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Microfluidic paper-based analytical devices for environmental analysis of soil, air, ecology and river water
Sensors & Actuators: B. Chemical 301 (2019) 126855
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Sensors and Actuators B: Chemical journal homepage: www.elsevier.com/locate/snb
Microfluidic paper-based analytical devices for environmental analysis of soil, air, ecology and river water Chia-Te Kunga, Chih-Yao Houb, Yao-Nan Wangc, Lung-Ming Fud,e,
T
⁎
a
Department of Emergency Medicine, Kaohsiung Chang Gung Memorial Hospital, Chang Gung University College of Medicine, Kaohsiung, 833, Taiwan Department of Seafood Science, National Kaohsiung University of Science and Technology, Kaohsiung 811, Taiwan c Department of Vehicle Engineering, National Pingtung University of Science and Technology, Pingtung 912, Taiwan d Department of Engineering Science, National Cheng Kung University, Tainan, 701, Taiwan e Graduate Institute of Materials Engineering, National Pingtung University of Science and Technology, Pingtung 912, Taiwan b
ARTICLE INFO
ABSTRACT
Keywords: Microfluidic Paper-based devices Water Soil Air Ecology Pesticide Environment
Microfluidic paper-based analytical devices (μPADs) have experienced rapid growth over the past decade due to their simple design, low cost, minimal sample requirement, and good sensitivity, selectivity and accuracy. While designed originally for point-of-care medical diagnostics, biological, and food safety applications, μPADs are now used increasingly for environmental monitoring purposes. This review provides a detailed overview of the μPADs developed over the past ten years for the environmental analysis of soil, air, ecology (pesticides) and river water. The review commences by introducing the fabrication techniques and detection methods used in μPAD technology. A detailed description of the main μPAD frameworks proposed in the past decade for environmental monitoring is then provided. The review concludes by examining the challenges facing μPADs for environmental monitoring and identifying probable avenues of future research.
1. Introduction As technology has advanced, the environment has become increasingly polluted with heavy metals, nutrients, microorganisms, organic pollutants, pesticides, and so on. Many of these pollutants are extremely harmful to human health, and hence the problem of developing instrumented techniques capable of detecting analyte concentrations in diverse sample matrices on the scale of parts per million (ppm), or even parts per trillion (ppt), has attracted great interest in recent decades. To meet the needs of the monitoring community for high sensitivity and low detection limits, most analytic methods rely on expensive equipment, which requires a high level of training to operate reliably. However, there is a growing need for low-cost technologies to detect and monitor environmental contaminant concentrations quickly, easily and in-field in order to provide more timely data regarding the extent and magnitude of pollution. Microfluidic paper-based analytical devices (μPADs) off ;er an opportunity to address this need by increasing the frequency and geographic coverage of environmental monitoring, while simultaneously reducing the analytic costs and complexity of the measurement process. μPAD platforms enable the realization of low-cost, flexible, simple and portable analytical instruments [1–3]. μPADs typically consist of a
⁎
small piece of patterned paper with a 2D or 3D structure capable of testing several tens of micro-liters of liquid sample within a relatively short period of time. During the past decade, numerous papers have been published in the μPAD field [4,5]. Typically, the devices proposed in these papers comprise an arrangement of microfluidic channels created by patterning hydrophobic materials on hydrophilic paper [6–8]. The testing process for biological substances (e.g., tears, urine, blood, sweat, saliva) [9–13], food (e.g., additives, bacteria, organic compounds) [14–17], and environmental reagents (e.g., heavy metal ions, nutrients, organic contaminants, microorganisms) [18–21] involves wicking the sample to the detection zone under the effects of capillary action without the need for an external pump [22–27]. Analytic detection is then facilitated by a chemical reaction process, which induces a change in color, electrochemical properties and / or light absorption or emission of the detection zone. Continuing industrialization and technological development has led to serious pollution of the air, soil and water in many regions of the world. Typically, these pollutants include nutrients, such as carbon, nitrogen and phosphorus, and many other contaminants, including heavy metals, organic contaminants, pharmaceuticals, herbicides, insecticides, disinfectants and industrial byproducts. Such pollution not only causes serious harm to the environment and surrounding
Corresponding author at: Department of Engineering Science, National Cheng Kung University, Tainan, 701, Taiwan. E-mail address: [email protected] (L.-M. Fu).
https://doi.org/10.1016/j.snb.2019.126855 Received 25 April 2019; Received in revised form 18 July 2019; Accepted 22 July 2019 Available online 08 August 2019 0925-4005/ © 2019 Elsevier B.V. All rights reserved.
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ecosystems, but also poses a major threat to human health and economic development. For a more detailed overview of the clinical presentations of some of the main environmental pollutants affecting humans nowadays, please refer to Supplementary Materials Table S1. Given the magnitude of the problem, the need for simple and cost-effective methods to enable the reliable monitoring of environmental pollution has emerged as a critical concern in recent years. This review provides a comprehensive overview of the main μPAD platforms developed over the past decade for environmental monitoring. The review commences by describing the various types of substrate material used in the fabrication of μPAD devices. Typical μPAD fabrication methods and detection techniques are then introduced. A detailed description of the main μPAD frameworks proposed over the past ten years for the analysis of soil, air, ecology (pesticides), and river water is then presented. Finally, the major challenges facing μPADs for environmental monitoring and analysis purposes are discussed, and likely directions of future research explored.
2.2. μPAD fabrication techniques Numerous approaches are available for fabricating μPADs using chemical modification or physical deposition techniques to alter the material characteristics of the cellulose matrix. In general, the treatment process changes the properties of specific areas of the cellulose paper from hydrophilic to hydrophobic; with parallel hydrophobic lines providing channels to guide the liquid flow as it permeates through the substrate under the effects of capillary action. The resulting μPADs can be broadly classified as either 2-dimensional (2D) [60–65] or 3-dimensional (3D) [66–70], depending on the direction (horizontal or horizontal / vertical) in which the fluid flows. Many methods have been proposed for fabricating μPADs, including lithography; 3D printing; wax printing; wax jetting; wax smearing; inkjet printing; screen printing; polydimethylsiloxane (PDMS) masking; laser cutting; hot embossing; printer cutting; sol-gel processing; scholar glue spraying; hydrophobic silanization; stamping; wet etching; and permanent marker pen, technical drawing pen, and eyeliner pencil writing. For a more detailed overview of the principles and comparisons of the main fabrication techniques, please refer to the review articles [71,72]. In recent years, a low-cost and efficient “origami” paperfolding method has also been proposed for the production of 3D μPADs based simply on the folding of the paper substrate [73–77]. For example, Xie et al. [78] developed a 3D μPAD, in which a paper mask coated with a thin layer of uncured PDMS mixture was folded with chromatographic paper to form a sandwich structure and was then heated to prompt the penetration of the PDMS into the chromatographic paper.
2. μPAD paper selection, fabrication and detection techniques 2.1. Paper selection Many different types of paper may be employed in μPADs depending on the fabrication method used and the particular analyte in question, including filter paper, chromatography paper, bioactive paper, glossy paper, nitrocellulose membrane paper, graphite paper, vegetal paper, and flexible paper [28–32]. Among these various types of paper, filter paper and chromatography paper (e.g., Whatman or Advantec) are among the most commonly used due to their relatively uniform thickness and superior pore size, which lead to enhanced adsorption and retention properties together with an improved wicking performance [33–38]. Furthermore, both papers undergo full bleaching following manufacturing, which removes virtually all of the impurities from the paper matrix. Glossy paper has also been proposed as a viable material for μPADs [39]. Glossy paper is composed of cellulose fibers and inorganic fillers blended into a paper matrix and has the advantage that its surface properties are more easily altered than those of traditional paper substrates. Bioactive paper has also been applied in μPADs [40,41]. In traditional paper substrates, only cationic molecules adsorb onto the wet cellulose fibers which make up the paper matrix. Furthermore, while proteins can be adsorbed on cellulose fibers, the rate and extent of this adsorption process is much lower than that of other hydrophilic surfaces. Consequently, the cellulose fibers must be modified in some way as to allow them to more readily absorb biomolecules. In bioactive paper, this is achieved by activating the surface of the paper using aldehyde or amide, for example, and then covalently conjugating biomolecules to the activated surface. Nitrocellulose membranes have also been used as μPAD substrates due to their chemical functional groups, which readily enable the covalent immobilization of biomolecules. Nitrocellulose additionally allows for charge-charge interactions, weak hydrogen bonds, and van der Waals interactions with protein-based substrates [42–44]. Due to their high protein-binding abilities, such membranes are commonly used in enzyme-linked immunosorbent assays (ELISA) and gold nanoparticle-based assays [45–50]. However, while nitrocellulose membranes can be easily patterned by wax printing, the penetration of the molten wax through the membrane thickness is slow compared to that in filter paper [51–53]. In graphite paper, the physically stripped graphene dispersion is further processed into layered graphene sheets by rapid filtration, high temperature annealing, and mechanical compression [54–59]. The resulting high-quality graphene and close contact between graphene sheets impart the graphene paper with ultrahigh conductive properties, which render the paper an ideal substrate material for electrical-based μPAD applications.
2.3. Detection techniques Many traditional techniques are available for the detection of toxic substances such as nutrients, heavy metals, microorganisms, organic contaminants and pesticides in environmental analyses. These methods include inductively coupled plasma mass spectrometry (ICP-MS), inductively coupled plasma-atomic/optical emission spectrometry (ICPAES/OES), energy dispersive X-ray fluorescence (EDXRF), electrochemical methods, electrothermal atomic adsorption spectrometry (ETAAS), flame atomic absorption spectrometry (FAAS), gas chromatography (GC), high-performance liquid chromatography (HPLC), gas chromatography-mass spectrometry (GC–MS), and atomic absorption spectrophotometry (AAS) [79]. Generally speaking, these methods have high sensitivity, good specificity, and excellent precision. However, all of them require complex equipment, professional personnel, and laborious operations. Thus, there is an urgent requirement for detection methods which are simpler, more cost-effective, and portable. This need is particularly pressing in developing countries and areas of the world with a lack of infrastructure, professional experts, and appropriate environmental treatment. Most previous research on μPADs has focused mainly on the design of the microfluidic chip itself rather than the overall detection system [1]. Thus, while modern μPADs are typically very small, the associated detection and correlation devices are still rather large. Moreover, they are generally available only in well-equipped laboratories and inspection centers. Consequently, the developed μPADs cannot be used for onsite detection and still require extensive inspector training. To address these problems, recent research has attempted to realize truly portable μPAD platforms, in which not only the sampling process, but also the detection and analysis procedures, can be performed on-site. Typically, these platforms involve the use of such detection techniques as colorimetric detection, fluorescence detection, electrochemical detection, chemiluminescence (CL) detection, electrochemiluminescence (ECL) detection, nanoparticle-based detection, mass spectrometry detection, and Raman spectroscopy detection. Colorimetric detection is one of the most widely used techniques in μPAD platforms nowadays and is defined by the passive movement of 2
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(As3+, Nd3+, Br−, Mn2+, Cr3+, F−, Cu2+, Pb2+ and Zn2+), neodymium (Nd), soil-transmitted helminth (STH), and tetrabromobisphenol A [88–113].
the analyte solution to test zones by capillary action followed by a reaction process with precisely loaded reagents to prompt a quantifiable color change [80]. The colorimetric images are generally acquired by a scanner, smartphone camera, or digital/CMOS camera, and are then transferred to a PC or cell phone for subsequent analysis. The detection limit for such methods is generally of the order of a few ppm (or the same level unit). Fluorescence/luminescent detection methods [81] exploit the interaction between the target molecules and a fluorescent dye, which results in a measurable electrical signal under illumination by a light source with a specific wavelength. Fluorescence/luminescence detection methods can easily meet these requirements, so fluorescence-based sensors appear to be one of the most promising candidates for chemical sensing. Due to its unique advantages in sensitivity and selectivity, this technology is widely used for the identification of cations and anions, response time and on-site monitoring. The detection limit for such methods is usually of the order of ppb (or the same level unit). Electrochemical techniques for μPAD platforms include cyclic voltammetry, amperometry, coulometry, and potentiometry. Electrochemical methods [82] involve the use of microelectrodes, convective mass transfer, surface-modified electrodes, flow injection, signal amplification, ion-selective electrodes, and ion-exchange membranes. The detection limit for such methods is typically around a few fM (or the same level unit). Chemiluminescence methods [83], which measure the light intensity generated from a chemical reaction, have gained significant attention as a detection technique for μPADs in recent years due to their inexpensive reagents and high signal-to-noise ratio, which makes possible detection limits of a few ppm (or the same level unit). Electrochemiluminescence is a derivative of the CL process [84], in which the signal is generated by an electrochemical reaction rather than a pure chemical reaction. Compared to CL-based detection, wherein signal emission is initiated upon application of the relevant reagents, ECL-based detection has the practical advantage that temporally-controlled signal capture can be more readily achieved through user-timed potential application. Moreover, the detection limit is generally of the order of a few ppb (or the same level unit). Mass spectrometry detection, magnetic resonance sensors, Raman spectroscopy, and capacitive sensors have also begun to be applied in μPAD platforms nowadays [85,86]. Accordingly, the quantitative analysis of μPAD kits had been addressed in many fields such as diagnostic tests, environmental monitoring and food safety, etc. The idea of combining multiple methods in one μPAD is promising, because these methods can potentially complement each other and minimize draw backs of a single method. For example, Wu et al. [87] reported a threedimensional multi-layer paper-based device that combines a thin adhesive film and paper folding to enable automated and multiple ELISA for colorimetric and electrochemical quantification of troponin I. Those detections of limit is approximately a few ppb (or the same level unit). For a more detailed overview of the detection methods and the range of LOD concentrations of each method, please refer to the review article [1].
3.1.1. Explosive residue pollution [88–95] Wang et al. [89] developed an inkjet-printed silver nanoparticle (Ag NP) paper-based sensor combined with a Raman spectroscopic method for the detection of crystalline trinitrotoluene (TNT) crystals and residues in the open environment (see Fig. 1(a)). The proposed sensor was modified with p-aminobenzenethiol (PABT) in order to more efficiently collect the airborne TNT via a charge-transfer reaction and to enhance the Raman scattering effect. It was shown that the device achieved a sensitivity limit of 1.6 × 10−17 g/cm2 TNT and was capable of detecting the odors emitted from 1.4 ppm TNT in soil and 7.2, 2.9 and 5.7 ng/cm2 TNT on clothing, leather and envelopes, respectively, within 2 s. Ryan et al. [90] presented a paper-based platform for the trace analysis of TNT in soil samples using an electrochemical probe consisting of graphite electrodes, filter paper, and ethylene glycol and choline chloride as the solvent/electrolyte. The sensitivity and detection limit of the probe were shown to be 0.75 nA/ng and 100 ng, respectively. Ueland et al. [91] used a wax-printing technique to realize a capillary-driven μPAD for the lab-on-chip (LoC) screening of explosive residues in soil. The experimental results showed that the device achieved a TNT detection limit of 1.4 ∼ 5.6 ng with a recovery rate ranging from 12 ∼ 40%. Shriver-Lake et al. [94] developed a paper-based probe for the electrochemical determination of chlorate using screen-printed carbon electrodes impregnated with vanadium-containing polyoxometalate anions (see Fig. 1(b)). In the proposed device, filter paper embedded with catalyst was cut into small strips and placed on the surface of commercial screen-printed electrodes. A small quantity of buffer solution was then added to render the electrode electrochemically active. The device showed a linear cyclic voltammetry current response over the chlorate concentration range of 0.156 ∼ 1.25 mg/mL and achieved a limit of detection (LOD) of 0.083 mg/mL. Table 1 briefly summarizes several other μPADs reported in the recent literature for explosive residue in soil pollution analysis. 3.1.2. Heavy metal pollution [96–101] Xiao et al [96] developed an enhanced 3D paper-based biosensing device for Ag+ detection, which uses a personal glucose meter with high sensitivity and portability. In the proposed device, the 3D origami μPADs integrated a piece of reagent-loaded nanoporous membrane. The membrane combined analyte-triggered self-growth of silver nanoparticles to block membrane pores in situ and perform signal amplification efficiently with a handheld personal glucose meter. This developed device can detect the Ag+ concentration of real water examples, i.e., tap water, drinking water, pond water and soil water. The LOD was found to be 58.1 pM. Nam and An [98] proposed a paper-disc device that includes the growth zone of soil algae Chlorococcum infusionum, chlorophyll fluorescence and photosynthetic activity, which exposure to copper treated soil. The study showed that the paper-disc device method is an effective, user-friendly method for assessing the metal toxicity of copper (Cu) and nickel (Ni) to soil algae. Chlorophyll fluorescence and photosynthetic activity decreased with increasing concentrations of Cu+2 or Ni+2 contaminated soil. The algal growth zone was visually analyzed and showed similar results to chlorophyll fluorescence. Sutariya et al. [99] developed a paper-based sensor device based on a single-step fluorescence consisting of a pyrene group connected to calix [4]arene as a fluorescent unit (TDPC) for the analysis of Nd3+ industrial soil sample and As3+ and Br- of industrial wastewater. In the proposed device, the paper-based sensor device comprises a luminescence sensing probe (CHEF-PET fluorescent probe) embedded in a cellulose matrix, wherein the resonance energy transfer appears to be a sensing mechanism, which is highly selective and sensitive for As3+,
3. Environmental pollution analysis and applications 3.1. Soil analysis Soil is the basic unit of the environment and is a valuable natural resource on which the entire world depends. However, large-scale industrialization and urbanization has resulted in significant soil pollution in many regions of the world. This pollution not only seriously degrades the soil fertility, but also impairs the capacity of the soil to retain nutrients and water. For the effects on these human bodies, please refer to Supplementary Material Table S1. Consequently, many μPAD platforms have been proposed for the analysis of common soil pollutants, including phosphate, chlorate, explosive residues, ammonia, copper (Cu), nickel (Ni), acid volatile sulfides (AVS), heavy metals 3
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Fig. 1. (a) Working principle of AgNP paper-based device to detect odor from TNT crystals using Raman spectra detection. (Reprinted from Ref. [89] with permission of American Chemical Society.) (b) Analysis method of paper-based electrochemical device for chlorate detection. (Reprinted from Ref. [94] with permission of MPDI (open access).) (c) Schematic illustration of paper-based spray ionization-MS device and calibration curve with isotopic internal standard for TBBPA analysis. (Reprinted from Ref. [108] with permission of Elsevier.).
Nd3+ and Br−. The results showed that the proposed system achieved detection limit of 11.53 nM, 0.65 nM and 11.25 nM for As3+, Nd3+ and Br−, respectively. The same group [100,101] also further performed a TAAC probe with a fluorescent paper-based device to enhance the analytical performance of fluorescent colorimetric detection. In soil, serum and industrial water samples, LOD can be enhanced to 0.88 nM for La3+, 0.19 nM for Cu2+, 0.15 nM for Br−, 11 nM for Mn2+, 4 nM for Cr3+ and 19 nM for F−. Table 1 briefly summarizes several other μPADs reported in the recent literature for heavy metal in soil pollution analysis.
with an isotopic internal standard method (see Fig. 1(c)). In the proposed device, soil and sediment extracts, spiked with 13C12 TBBPA (Ring-13C12), were loaded and separated on chromatographic paper and then sprayed and ionized by a high negative voltage. The paper substrate was then analyzed by mass spectrometry without purification and chromatography separation processes. The device showed a linear range of 0.1–100 μg/L, a LOD of 0.039 μg/L and a relative standard deviation of 5.3%. Naik et al. [110] preaented a loop-mediated isothermal DNA amplification (LAMP) paper-based device that combines one-step assay and thermal lysis to detect E. coli and M. smegmatis cells. The device combines thermal lysis and LAMP into a single reaction step on a paperbased device without any intermediate intervention and uses fluorescence from the DNA-binding dye PicoGreen to detect amplicons. The results showed that 100 CFU/mL of E. coli and M. smegmatis DNA amplification can be completed in 30 min. Similary, the authors in [111,112] used paper-based devices to detect E. coli in dust/soil or algae particle samples. Table 1 briefly summarizes several other μPADs reported in the recent literature for soil pollution analysis.
3.1.3. Other pollution [102–113] Wang et al. [105] presented a quantitative paper-based DNA reader (qPDR) for quantifying soil-transmitted helminth (STH) at the molecular level using “distance” as the readout. Since dsDNA depends on the concentration, the migration distance of SG-1 in the test region can be quantitatively determined by the concentration of dsDNA, so that dsDNA can be quantified by simply reading the migration distance of SG-1 in qPDR. The device exploited the unique interfacial interaction of SYBR Green I (a DNA intercalating dye) with the native cellulose matrix of chromatographic paper and performed polymerase chain reactions using a smartphone-controlled portable thermal cycler to detect minute amounts of genetic markers from adult worms expelled by STH-infected children. Liu et al. [108] developed a simple and rapid method for detecting tetrabromobisphenol A (TBBPA) in soils and sediments using a paper-based spray ionization mass spectrometry technique combined
3.2. Air analysis Air pollution has serious and wide-ranging effects on human health and the environment (See Supplementary Material Table S1). Air pollutants typically include solid particles, liquid droplets, or gases, and may be of either natural origin or manmade. Many μPADs have been 4
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Table 1 Summarizes of the μPADs developed for the determination of contamination in environmental analysis. Ref. and First author
years
Materials & structures
Fabrication methods
Detection methods
Target & (Sample matrices)
Detection limit
[91] Ueland
2016
Wax printing
Fluorescence
2015
Wax ink
Colorimetric
[95] Moram
2018
Soaking
SERS
Explosive residues (soil) Explosive residues (soil) Explosive residues
1.4 ng
[93] Peters
Filter paper, 2-D Chromatography paper, 2D Filter paper, 2-D Filter paper, 2-D Filter paper, 3-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Chromatography paper, 2D Chromatography paper, 2D Filter paper, 2-D Filter paper, 2-D Bare paper 2-D Photo paper 2-D Filter paper, 2-D N/R 2-D N/R
[99] Sutariya
2019
[103] Jayawardane
2014
[104] Jayawardane
2015
[106] Pellegrini
2018
[109] Basuri
2019
[113] Suaifan
2019
[115] Tang
2018
[118] Kuretake
2017
[119] Motooka
2018
[122] Alkasir
2015
[123] Colozz
2019
[127] Maity
2019
[129] Quddious
2016
[130] Petruci
2015
[131] Zhang
2015
[132] Kan
2019
[133] Sitanurak
2018
[138] Rattanarat
2014
[153] Yang
2016
[155] Nouanthavong
2016
[156] Ding
2016
[160] Wu
2017
[162] Ayazi
2018
[164] Mohammadi
2017
[166] Apilux
2015
[169] Evard
Wax printing Inkjet printing
Colorimetric (fluorescence) Colorimetric
Inkjet printing
Colorimetric
Cutting
Colorimetric
Cutting
SHPPSI MS
Wax printing
Colorimetric
N/R
Colorimetric
Cutting
Electrochemical
Screen- printing
Electrochemical
Inkjet printing
Colorimetric
Screen- printing
Electrochemical
Dip coating
Electrochemical
Inkjet printing
Electrochemical
Cutting
Fluorescence
Pencil-trace printing Spray-coated
Electrochemical
Filter paper, 2-D Filter paper, 2-D
N/R
Colorimetric
Wax printing
Colorimetric, Electrochemical
Filter 2-D Filter 2-D Filter 3-D Filter 2-D Filter 2-D
paper,
Inkjet printing
Electrochemical
paper,
Screen- printing
Colorimetric
paper,
Wax printing
Electrochemical
paper,
Inkjet printing
Colorimetric
paper,
Immersed
USA-TFME-GC-FID method
Filter paper, 2-D Filter paper, 3-D
Wax printing
Colorimetric
Punching
Colorimetric
2015
Filter paper, 2-D
Cutting
MS
[170] Lee
2018 2019
Cutting, calendering Dip-coating
SERS
[171] Zhang
Filter paper, 2-D Filter paper, 2-D
Electrochemical
3+
3+
As , Nd , Br (soil) Reactive phosphate (soil) Ammonia (sewage and soil water) Acid volatile sulfides (soil) Melamine (mike, soil) S. chartarum (soil) Methyl isothiocyanate (air) Ethanol (air) Ethanol (air) Bisphenol A (air) Sulfur mustard (air) NH3 (air) H2S gas (air) H2S gas (air) NO2 gas (air) NO2 gas (air) Hypochlorite (air) Cr, Cd and Pb (air) Trichlorfon (pesticide) Methyl- paraoxon, chlorpyrifos-oxon (pesticide) Methyl- parathion (pesticide) Paraoxon, trichlorfon (pesticide) Fenthion, chlorpyrifos, fenithrothion, phosalone, edifenphos, ethion (pesticide) -
Methiocarb (pesticide) Carbofuran, dichlorvos, carbaryl, paraoxon, pirimicarb (pesticide), Thiabendazole, aldicarb, imazalil, methomyl and methiocarb (pesticides) Thiram, ferbam (pesticide) Melamine, Thiram (pesticide)
SERS
0.39 μg 1.82 ng 11.53 nM, 0.65 nM, 11.25 nM 0.05 mg/L 0.8 mg N/L 0.1 μmoles/g 1.2 ppt (10 pM) 10 spores/mL 100 ppb 50 ppm 15 ppm 0.28 μg/g 0.019 g·min/m3 1 ppm 5 ppm 2 ppb 4.8 ppb 1 ppm 2 g Cl2/L 0.12 μg 0.25 ng 0. 89 μmol/L 8 ng/mL, 5.3 ng/mL 0.06 nM 0.01 ng/mL, 0.04 ng/mL 0.05 ng/mL, 0.05 ng/mL, 0.1 ng/mL, 0.3 ng/mL, 0.05 ng/mL, 0.3 ng/mL 5 ng/mL 0.003 ppm, 0.3 ppm, 0.5 ppm, 0.6 ppm, 0.6 ppm 5 mg/kg 0.46 nM, 0.49 nM 1 ppm
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Table 1 (continued) Ref. and First author
years
Materials & structures
Fabrication methods
Detection methods
Target & (Sample matrices)
Detection limit
[177] Jafry
2019
Filter paper, 2-D
Jet printing
Colorimetric
Methyl- paraoxon (pesticide)
10 μM
AChE: Acetylcholinesterase; MS: Mass spectrometry; N/R: No report; SERS: Surface-enhanced Raman scattering; SHPPSI MS: superhydrophobic preconcentration paper spray ionization mass spectrometry; USA-TFME-GC-FID method: ultrasound assisted thin film microextraction gas chromatography-flame ionization detection.
developed in recent years for the analysis of air pollution or air properties [114–148]. Typically, these devices are aimed at the detection of organic conpunds (volatile organic compounds (VOCs), ethylene (C2H4), bisphenol A (BPA), methyl isothiocyanate (MITC), ethanol vapor (C2H6O), sulfur mustard), inorginaic conpunds (ammonia gas (NH3), hydrogen sulfide (H2S), hypochlorite (ClO−), nitrogen dioxide (NO2),), and other substances (metal, oxygen (O2), humidity, pressure).
470 nm for the determination of hydrogen sulfide (H2S) in air (see Fig. 3(a)). The response time of the device was shown to be less than 60 s with a LOD of around 3 ppb. Kan et al. [132] developed a PbS nanowires paper-based sensor device for room-temperature NO2 gas detection. In the proposed device, PbS nanowires were spray coating onto apaper-based substrate at room temperature to enhance the sensitivity and flexibility of the gas sensor, because the PbS nanowires-on-paper sensor exhibits a porous network microstructure. The response of the paper-based sensor to 50 ppm of NO2 gas was 17.5 at room temperature, with the response and recovery time being 3 and 148 s, respectively. The device exhibited a linear response for NO2 concentrations in the range of 1–50 ppm with a detection limit of 1 ppm. Dhummakupt et al. [134] proposed a paper-based spray ionization device for the analysis of trimethyl phosphate, dimethyl methylphosphonate, and diisopropyl methylphosphonate collected on glass filter paper. In the detection process, a disposable cartridge containing a fiber filter is mounted on a specially designed 3D printing holder that effectively and reproducibly captures the aerosol onto the paper spray substrate. The device was capable of detecting aerosol concentrations as low as 1 × 10-6 mg/m3 and allowed for improved direct aerosol capture efficiency greater than 40%.
3.2.1. Organic compounds pollution [114–123] Soga et al. [114] developed a paper-based colorimetric sensor array for the detection of chemical compounds. The device was fabricated on standard copy paper using an inkjet printing technique and was patterned with dye encapsulated with polymer nanoparticles with different polarities to detect volatile primary amine (see Fig. 2(a)). It was shown that under the designed measurement conditions, the device achieved a high discrimination ability and good reproducibility for amine concentrations as low as 50 ppm. Tang and Sun [115] have developed a highly sensitive paper-based colorimetric sensor device for the detection of trace amounts of methyl isothiocyanate (MITC) in the air. The MITC paper-based sensor is based on detoxification reaction of glutathione (GSH) that binds to electrophilic toxicants during toxicantsduring under metabolic conditions and becomes unique when directly sensing the concentration of MITC. The LOD was found to be 100 ppb. Chen et al. [116] developed a paper-based sensor for the detection of volatile gases in air by means of an integrated optical and electronic sensor array patterned on the substrate surface through the direct handwriting of sensing materials (see Fig. 2(b)). The sensor was tested in ambient air for various volatile gases, including methanol, ammonia, toluene, acetone and ethanol. For each analyte, classification and detection were performed using a support-vector machine (SVM) technique. The results showed that the combined optical and electrical response provided a better discriminative power than that achieved using either sensing method alone. The authors in [117–120] used a paperbased cantilever array sensor and paper-based enzymatic biosensor, respectively, to detect volatile organic compounds (VOCs) and ethanol (breath analysis). Luo et al. [121] presented a paper-based plasma-assisted cataluminescence (PA-CTL) sensor for ethylene detection incorporating a substrate embedded with 0.320 wt% Mn-doped SiO2 nanomaterials (see Fig. 2(c)). The device showed a linear response in the range of 33∼6667 ppm and achieved a limit of detection of 10 ppm. Table 1 briefly summarizes several other μPADs reported in the recent literature for organic compounds in air pollution analysis.
3.2.3. Other substances analysis [135–148] Sun et al. [135] developed a paper-based microfluidic device for the on-site multiaxial quantification of airborne trace metals using an unmanned aerial vehicle (UAV) for sampling purposes and an integrated colorimetric detection method implemented on a smartphone (see Fig. 3(b)). The experimental results showed that the proposed system achieved limits of detection of 1.86 × 102, 45.84, 80.40, 8.16, 10.08 and1.52 × 102 ng for six metals commonly found in airborne PMs, namely Fe, Cu, Ni, Co, Mn, and Cr respectively. The same group [136] further integrated graphene oxide (GO) with a paper-based device to enhance the analytical performance of colorimetric detection. The LODs can be enhanced to 16.6, 5.1, and 9.9 ng for Fe, Cu, and Ni, respectively. The authors in [137,138] used μPAD-coated AgNPs aggregation and multilayer paper-based device for colorimetric and electrochemical quantification, respectively, to detect particulate matter (PM) pollution and six metals (Cd, Pb, Fe, Cu, Ni, and Cr) in air sample. A special paper-based device is used to detect ATP from airborne bacteria developed by Nguyen et al. [139]. The paper-based device can detect ATP extracted from purified E. coli as low as 1.17 × 103 CFU/mL. Gimenez et al. [140] developed a simple paper-based oxygen sensor consisting of a film of ZnO crystals dispersed over the paper surface. It was shown that when the device was illuminated by UV light, the current passing through the sensor underwent a small change under the effects of oxygen desorption. Moreover, the magnitude of this change was proportional to the concentration of oxygen adjacent to the sensor surface. The device was capable of detecting oxygen concentrations as low as 27.6 g/m3 even under low humidity conditions of 40% relative humidity (RH). Zhao et al. [142] presented a carbon-based humidity sensor in which the electrodes were written on the paper substrate by commercial pencils and the sensitive layer was drawn with oxidized multi-walled carbon nanotubes (o-MWCNTs) ink marker (see Fig. 3(c)). The response curve exhibited a high slope (0.41) and good linearity (R2 = 0.9976) in the 33∼95% RH range. The authors in [143,144]
3.2.2. Inorganic compounds pollution [124–134] Huang et al. [124] fabricated a paper-based sensor for the detection of ammonia gas (NH3) using silver and poly(m-aminobenzene sulphonic acid) functionalized single-walled carbon nanotubes (SWNT-PABS) deposited on photopaper using an inkjet printer. The sensor showed an excellent response, a short recovery time under NH3 concentrations at the ppm level, and good stability for at least several months. The authors in [125–127] used SWNTs and perovskite halide CH3NH3PbI3 (MAPI) deposited on paper to detect the presence of toxic NH3 gas. Petruci and Cardoso [128] developed a detection system incorporating a paper substrate infused with fluorescein mercury acetate (FMA), a light emitting diode (LED), and a spectrometer with a wavelength of 6
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Fig. 2. (a) Analysis principle of paper-based color sensor system and colorimetry results for principal component analysis. (Reprinted from Ref. [114] with permission of American Chemical Society.) (b) Schematic illustration of paper-based optoelectronic sensor (paper-nose) with colorimetric (optical) and chemiresistive (electronic) sensor array platform. (Reprinted from Ref. [116] with permission of Elsevier.) (c) Schematic illustration of paper-based PA-CTL system for ethylene detection. (Reprinted from Ref. [121] with permission of Elsevier.).
fabricated paper-based humidity sensors consisting of conductive molybdenum carbide–graphene (MCG) composites and polymers poly(3,4ethylenedioxythiophene)-poly(styrene sulfonate) (PEDOT:PSS) deposited on paper substrates, respectively. Zang et al. [147] developed a paper-based sensor for ambient pressure determination incorporating a conducting polymer (CP)-coated paper substrate. The experimental results showed that the sensor achieved a LOD as low as 0.3 Pa and a sensitivity of 2 kPa−1 (P ≤ 75 Pa). Table 1 briefly summarizes several other μPADs reported in the recent literature for air pollution analysis.
animal pests. However, runoff can carry pesticides into aquatic environments, while wind can carry them to other fields, grazing areas, human settlements and undeveloped areas. Moreover, pesticides easily enter the human body through the inhalation of aerosols, dust and vapor; oral exposure by consuming contaminated food or water; and skin exposure by direct contact. As such, pesticides have wide-ranging adverse effects on both the environment and human health (See Supplementary Material Table S1). Accordingly, many μPAD platforms have been proposed for the analysis of pesticides in recent years [149–176], including insecticides (dichlorvos (DDV), trichlorfon, methiocarb, methyl parathion, carbaryl, nitenpyram, chlorpyrifos, methomyl, profenofos, chlorpyrifos, aldicarb), fungicides (thiram, thiabendazole, ferbam, carbamate, imazalil), and others (melamine,
3.3. Ecology analysis ― pesticide Pesticides are widely used throughout agriculture to kill fungal or 7
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Fig. 3. (a) Schematic illustration of paper-based sensing platform for H2S detection and sample concentration measurement using LED excitation and microfiber USB spectrometer. (Reprinted from Ref. [128] with permission of American Chemical Society.) (b) Integrated paper-based colorimetric detection and UAV for quantification of metals in airborne particulate matter. (Reprinted from Ref. [135] with permission of Elsevier.) (c) Paper-based chip based on o-MWCNTs for electrochemical detection of humidity and dynamic response of sensor. (Reprinted from Ref. [142] with permission of American Chemical Society.).
dimethyl methylphosphonate, indole-3-acetic acid (IAA), salicylic acid (SA))
tetraphenylethylene (TPE) and the addition reaction capability of maleimide for the rapid naked-eye detection of AchE activity and Ops (see Fig. 4(b)). The LODs for AchE and Ops were found to be 2.5 mU/ mL and 0.5 ng/mL, respectively. The authors in [158,159] similarly used paper-based devices to detect AchE activity and cholinesterase activity in human blood. For the CMs type, Zhang et al. [163] presented a molecularly imprinted polymers (MIPs) paper-based biomimetic enzyme-linked immunosorbent assay (BELISA) device for the detection of carbaryl. In the proposed device, the surface of the paper substrate was first modified with γ-MAPS by hydrolytic action and the MIP layer was then anchored on the modified surface by copolymerization. The device showed a linear response (R2 = 0.99) over the concentration range of 0.001∼1 mg/L. Moreover, the LODs of the half-inhibitory concentration (IC50) and IC15 were 0.116 mg/L and 0.007 mg/L, respectively. Wang et al. [165] developed a highly-sensitive SERS platform incorporating a silver dendrites-decorated superhydrophobic paper-based device and a Raman measurement system for the detection of nitenpyram pesticide (see Fig. 5(a)). It was shown that the layered fernlike silver dendrites (F-AgNDs) not only enhanced the hydrophobicity of the surface, but also improved the SERS detection performance. The LOD and enhancement factor were found to be 1 nM and 3.4 × 107, respectively. Table 1 summarizes several other μPADs reported in the recent literature for insecticide analysis.
3.3.1. Insecticide pollution [149–157] In the insecticide pollution, the literature can be divided into two categories, using the μPAD platform for detection, namely organophosphorus (Ops) and carbamates (CMs). For the Ops type, Liu et al. [149,150] developed a paper-based CL analytical device combined with paper chromatography to determine the concentration of DDV in vegetables. The device used a mixed solution of luminol and H2O2 to produce CL and exhibited a linear response for DDV concentrations in the range of 3.0 ng/mL to 1.0 μg/mL with a detection limit of 0.8 ng/ mL. Apilux et al. [152] presented a thioglycolic acid (TGA)-capped CdTe QD paper-based device based on fluorescence conversion for the detection of DDV, pirimicarb and carbaryl. The detection zone was impregnated with acetylcholinesterase (AchE) and choline oxidase (ChOx) enzymes and was coated with TGA-capped CdTe quantum dots (QDs). It was shown that in the assay process, the bi-enzyme reaction induced by the presence of insecticide caused a reduction of H2O2 and led to a quantifiable change in the fluorescence intensity of the TGAcapped CdTe QDs under black light. The LOD was found to be 0.01, 0.05 and 0.01 ppm for DDV, pirimicarb and carbaryl, respectively. Several μPAD platforms have been proposed for the detection of complex organophosphorus (Ops) compounds in environmental samples and AchE activity and Ops in human serum samples [153–162]. For example, Kim et al. [154] presented a multilayered paper-based device for the detection of chlorpyrifos pesticide (OP-type) using a colorimetric method (see Fig. 4(a)). The device comprised three paper layers for sample injection, reagent storage, and reaction / color development, respectively. In the detection process, the sample solution was dripped onto the paper-based device and subsequently underwent mixing with two deposited reagents (AchE and indoxyl acetate (IDA)) to produce a blue image in the reaction zone. The LOD was found to be 8.60 ppm. Chang et al. [157] proposed a paper-based fluorescent sensor based on the aggregation-induced emission effect of
3.3.2. Fungicide pollution [168–173] Fungicides are biocidal compounds or biological organisms used to kill parasitic fungi or spores thereof. Fungicides can be used in both agricultural and fungal infections against animals. Ma et al. [168] proposed an on-site detection system for thiram, thiabendazole and methyl parathion pesticides comprising a surface-enhanced Raman scattering (SERS) paper substrate patterned with graphene oxide (GO) and Ag NPs. The device showed an excellent SERS activity and was capable of extracting thiram, thiabendazole and methyl parathion residues in fruits and vegetables with LODs of 0.26 ng/cm2, 28 ng/cm2 8
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Fig. 4. (a) Schematic illustration of colorimetric paper-based sensor device and procedure for pesticide analysis using competitive-inhibiting reaction. (Reprinted from Ref. [154] with permission of Springer.) (b) Analysis principle and observation results for fluorescent paper-based assay for AChE activity in presence of diazinon with different concentrations. (Reprinted from Ref. [157] with permission of Elsevier.).
and 7.4 ng/cm2, respectively. Lee et al. [170] also developed a paperbased SERS device that can detect pesticides of the fungicide type by hydrophobically modifying the filter paper with high sensitivity and repeatability. The filter paper is subjected to a hydrophobic treatment of the alkyl ketene dimer to prevent the paper from absorbing AgNP and the sample solution. Unlike conventional filter papers, hydrophobically modified filter paper produces more SERS hot spots composed of AgNP clusters on the paper surface for more sensitive detection of pesticides. Fungicides such as thiram and ferbam can be detected at the nanomolar level using the proposed device and found to have an LOD of 0.46 nM and 0.49 nM, respectively. Identically, Deng et al. [172] also presented a paper-based SERS device for detection of malachite green residues in fish. The surface-enhanced Raman scattering signal intensity has a good linear relationship with the malachite green concentration between 1 × 10−7 and 1 × 10-5 mol/L, and LOD was be founded to 5 × 10-10 mol / L. Table 1 summarizes several other μPADs reported in the recent literature for fungicide analysis.
butyrylcholinesterase (BchE) enzyme activity towards butyrylthiocholine with and without exposure to nerve agent, respectively, and enabled an entirely reagent-free analysis. The sensitivity of the device was enhanced through the use of carbon black/Prussian blue nanocomposites as working electrodes. In a series of tests performed using paraoxon as a nerve agent simulant, the device exhibited a linear detection performance down to 3 μg/L. Lee et al. [176] developed a foldable paper-based device for detecting dimethyl methylphosphonate (DMMP) in a semi-quantitative manner using a colorimetric technique (see Fig. 5(b)). In the proposed device, the color of the paper channel changed to yellow in the presence of DMMP as a result of the hydrogen peroxide produced from the enzymatic reactions and the DMMP concentration was then quantified using an angle-based readout. A linear angle response was observed for DMMP concentrations in the range of 1 ∼ 4 M. Table 1 summarizes several other μPADs reported in the recent literature for pesticide analysis. 3.4. River water analysis
3.3.3. Other pollution [174–177] Cinti et al. [174] developed an integrated paper-based screenprinted electrochemical biosensor for the detection of nerve agents. The device was based on the double electrochemical measurement of
Water pollution is a major global concern nowadays and is observed in many water bodies, including rivers, oceans, lakes and aquifers. Water contamination is usually the result of human activities, and 9
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Fig. 5. (a) Photograph of fabrication process for flexible SERS substrate based on silver dendrites-decorated filter paper for nitenpyram detection and SERS spectra result. (Reprinted from Ref. [165] with permission of Elsevier.) (b) Schematic illustration of fabrication process for paper-based SERS swabs and detection principle for pesticide residues. (Reprinted from Ref. [176] with permission of Elsevier.).
varied in direct proportion to the concentration of Cu2+ ions in the sample. The experimental results showed that the device achieved a LOD of 0.96 ppm (15 μM). Liu et al. [195] developed a paper-based analytical device for the image-based colorimetric detection of Cu2+, in which an on-line reaction between polyethyleneimine (PEI) and Cu2+ was induced within a T-type microfluidic channel under the application of an external electric driving field. The device achieved a linear response (R2 = 0.991) over a Cu2+ concentration range of 0.1∼1.0 mM with a LOD equal to 30 μM. Chen et al. [197] presented a colorimetric paper-based analytical platform based on AuNPs and a smartphone for water source Hg2+ detection (see Fig. 7(a)). The presence of Hg2+ ions induced the aggregation of the AuNPs via thymine–Hg2+–thymine (T–Hg2+–T) coordination chemistry. The resulting color change of the reaction zone was imaged and analyzed by the smartphone. The experimental results obtained for spiked pond and river water samples showed that the device was capable of performing Hg2+ detection down to 50 nM. Faham et al. [202] used AuNPs modified with 2,2′-thiodiacetic acid (TDA) to determine the concentrations of Cr3+ and Cr6+ ions using a paper-based device coupled with UV–vis spectrophotometry, dynamic light scattering, energy dispersive spectroscopy and transmission electron microscopy (see Fig. 7(b)). The device was used to determine the concentration of chromium ions in spiked water, urine and human plasma, and was found to have a good linear correlation (R2 = 0.98) over the concentration range of 1.0 nM to 0.1 mM and a LOD equal to 0.64 nM (0.033 ppb). Asano and Shiraishi [205] proposed a μPAD for the colorimetric detection of iron in water samples using phenanthroline indicator. Briefly, a hydrophobic surface was produced via immersion in octadecyltrichlorodecane (OTS)-n-hexane and the surface was then exposed to UV light through a photomask to produce a hydrophilic region. The visible color change induced in the reaction zone following the introduction of the sample solution was captured by a high-resolution camera and used to determine the corresponding iron concentration. The LOD and limit of quantitation (LOQ) were found to be 3.96 and 13.8 mM, respectively. Li et al. [208] developed a colorimetric paperbased membrane sensor for the determination of Ni2+ ions using zincon organometallic reagent combined with hollow ZnSiO3 nanospheres as a mixed ionophore (see Fig. 7(c)). In the presence of Ni2+, the
includes a wide range of chemicals and pathogens. Water pollution is the leading cause of death and disease worldwide (See Supplementary Material Table S1), and hence many μPAD platforms for detecting water contaminants have been proposed. These devices are generally intended for the analysis of river water [178–232] and typically target analytes such as heavy metals (mercury (Hg2+), lead (Pb2+), cobalt (Co2+), zinc (Zn2+), chromium (Cr6+, Cr3+), iron (Fe3+), copper (Cu2+), nickel (Ni2+), cadmium (Cd2+), silver (Ag+), manganum (Mn2+), calcium (Ca2+), magnesium (Mg2+)), non-metal ions (nitrite, arsenic (As), chloride (Cl−), bromide (Br−), iodide (I−), sulfide (S2−), and organic contaminants and microorganisms (pesticides, cyanide, ethinylestradiol, phosphate, dipicolinic acid, hydrogel, trinitrophenol, bacterial). 3.4.1. Heavy metal ion pollution [183–212] Vijitvarasan et al. [183] developed a paper-based scanometric colorimetric sensing assay that coupled enzyme probes (PE), magnetic beads (MB), substrate probes (PS) and gold nanoparticles (AuNPs) to perform the detection of Pb2+. As shown in Fig. 6(a), the AuNPs-PS were spotted on a paper substrate and the signal induced in the presence of a magnetic field was then amplified by a silver nitrate enhancer solution. The device exhibited a linear response over the range of 0.1∼1000 nM and a LOD of 0.3 nM. The literature contains several other DNAzyme-based methods for detecting metal ions using colorimetric or ELC techniques [184,185], label-free fluorescence assays [186,187], or aptamer-based assays [188], Zhang et al. [190] presented a label-free oligonucleotide sequences-AuNPs paper device for the colorimetric sensing of Ag+. Label-free oligonucleotide sequences (S1) were attached to unmodified AuNPs by cytosine–Ag+–cytosine (C–Ag+–C) coordination chemistry; giving rise to an OR function. A logic gate was then constructed using S1 and Ag+ as inputs to the S2attached AuNP mixture. The detection limit of the proposed device was shown to be as low as 10 nM. Sadollahkhani et al. [192] proposed a ZnO@ZnS core-shell nanoparticle paper-based sensor for the detection of Cu2+ ions in aqueous solutions (see Fig. 6(b)). The difference in solubility between ZnS and CuS resulted in a cation exchange between the ZnS nanoparticle surface and the Cu2+ ions. The cation exchange prompted a color transformation of the test paper from colorless to yellow, where the intensity 10
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Fig. 6. (a) Schematic illustration of detection procedure for lead ions using paper-based scanometric assay device. (Reprinted from Ref. [183] with permission of Elsevier.) (b) Functional mechanism and colorimetric detection results for Cu2+ analysis using PAD sensor platform. (Reprinted from Ref. [192] with permission of American Chemical Society.).
competition with the Zn2+ ions resulted in a quantifiable fading of the blue color in the reaction zone. It was shown that the selectivity of the proposed device could be enhanced by using masking agent Na2-EDTA as a co-ionophore. The device exhibited a linear response over the range of 32 nM to 9.2 mM Ni2+ and achieved a LOD of 35.6 nM. Table 2 summarizes several other μPADs reported in the recent literature for heavy metal ion pollution analysis.
mL, respectively. Devi et al. [216] presented a detailed overview of the progress made in sensor materials for the optical detection of arsenic in water samples between 2013 and 2018. Cuartero et al. [217] developed an electrochemical PAD for halide ion detection in food supplements and water samples via cyclic voltammetry. As shown in Fig. 8(a), the device consisted of a cellulose paper substrate, a cation exchange Donnan exclusion membrane, and a silver-foil working electrode. Cyclic voltammetry was used to perform the sequential oxidation and plating of the halide at the silver electrode, and was followed by regeneration with an inverted potential. The feasibility of the proposed device was demonstrated by detecting Cl−, Br− and I− ions in concentrations ranging from 10−4.5 M to 0.6 M for Cl− and 10−4.8 M to 0.1 M for Br− and I−. It was shown that the device achieved a LOD of 10−5 M. Vasimalai et al. [219] developed a paperbased testing kit for the detection of S2– ions in water samples based on the quenching effect of S2– on 6-mercapto-s-triazolo(4,3-b)-s-tetrazingold nanodots (MT-AuNDs) (see Fig. 8(b)). The device showed a linear response over the range of 870 nM to 16 μM S2– and achieved a LOD of 2 nM. Table 2 summarizes some of the other μPADs reported in the recent literature for non-metal ion pollution analysis.
3.4.2. Other ion pollutants [213–219] Liu et al. [213] developed an Ag-based μPAD chemiresistor for the electrochemical detection of nitrite ions in river water. In the proposed device, the introduction of nitrite prompted a Griess reaction, and the resulting azo and sulphonamide products reacted with the Ag metal and Ag+ ions to cause a change in resistance of the response region. The sensor was shown to provide a linear response over two nitride concentration ranges of 10 nM to 5.0 μM and 10 μM to 3.2 mM, respectively, Moreover, the LOD was found to be 8.5 × 10−2 nM. Cardoso et al. [214] developed a μPAD platform combined with colorimetric detection and a modified Griess reaction for the determination of nitrite in clinical, food and river water samples. The reaction images were captured by a scanner, converted to a color scale, and then analyzed in the magenta channel. The device achieved a LOD of 5.6 μM and a sensitivity of 0.56 AU/mM. Pena-Pereira et al. [215] proposed an AgNO3-based paper device for arsenic (As) detection involving in situ arsine generation followed by transfer of volatiles to the headspace and a subsequent reaction with silver nitrate in the detection zone. Under optimal conditions, the LOD and LOQ were found to be 1.1 and 3.6 ng/
3.4.3. Organic contaminants and microorganism pollution [220–232] Arduini et al. [221] proposed a 3D origami paper-based device combining different enzyme-inhibition biosensors and office paper screen-printed electrodes (SPE) for the electrochemical detection of several types of pesticide in river water (see Fig. 9(a)). In the proposed device, the presence of pesticide was detected by monitoring the 11
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Fig. 7. (a) Photographs, functional mechanism and detection results obtained by μPAD treated with AuNPs for on-site Hg2+ assay. (Reprinted from Ref. [197] with permission of American Chemical Society.) (b) Mechanism and colorimetric detection results obtained by PAD sensor platform based on TDA-AuNPs for Cr3+ assay. (Reprinted from Ref. [202] with permission of Springer.) (c) Schematic illustration of Ni2+ ion analysis using colorimetric paper-based membrane sensor based on indicator displacement mechanism and corresponding colorimetric sensing results. (Reprinted from Ref. [208] with permission of Elsevier.).
(R2 = 0.917) for the river water samples. The LOD of the biosensor was found to be 2 ppb. The same group [222] also used a paper-based screen-printed electrochemical sensor to detect phosphate. Saraji and Bagheri [224] developed a paper-based headspace extraction device coupled with digital image processing for the detection of cyanide in mineral, tap, well, river, sea and wastewater samples (see Fig. 9(b)). In
enzymatic activity degree chrono-amperometrically in the absence and presence of pesticide, respectively, using a portable potentiostat. The device was tested using paraoxon, 2,4-dichlorophenoxyacetic acid and atrazine at ppb concentration levels in both standard solutions and river water samples. Two linear response ranges were observed, namely 2∼100 ppb (R2 = 0.907) for the control solutions and 10∼100 ppb 12
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Table 2 Summarizes of the μPADs developed for the determination of contamination in river water analysis and maximum contaminant level in drinking water. Ref. and First author
years
[184] Xu [185] Sun
2018 2018
[186] Li
2018
[187] Lin
2016
[188] Fakhri
2018
[189] Almeida
2012
[191] Dhavamani
2018
[193] Liu
2012
[194] Cui
2019
Materials & structures
Fabrication methods
Detection methods
Target 2+
Detection limit
MCL(mg/L)EPA
Chromatography paper, 3-D Art-paper, 2-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Chromatography paper, 2-D
Wax printing Microcontact printing
ECL Colorimetric
Pb Pb2+
0.5 nM 10 nM
0.015 0.015
Wax printing
Fluorescence
Pb2+
10 nM
0.015
N/R
ICP-MS
CO2 laser cutting
Colorimetric
Pb2+, Cd2+ Pb2+
0.69 mg/L, 0.51 mg/L 0.7 nM
0.015 0.005 0.015
N/R
SR-TXRF
paper,
Hand drawn
Colorimetric
6.8 μg/L, 4.4 μg/L, 3.9 μg/L, 3.8 μg/L, 3.9 μg/L, 9.1 μg/L, 10 μM
0.05 1.0 5.0 0.015
Filter 2-D Filter 2-D Filter 2-D Filter 2-D
Mn, Co, Ni, Cu, Zn, Pb Ag+
0.10
paper,
Cutting and soaking
Fluorescence
Cu2+
5 μM
1.0
paper,
Inkjet printing
Colorimetric
Cu2+
0.08 μM
1.0
Wax printing
Colorimetric
2+
Cutting and immersing
Fluorescence
4.8 mg/L, 1.6 mg/L 0.18 mg/L 0.14 nM
1.0 0.1
Filter paper, 2-D Filter paper, 2-D
Ni , Cu2+, Cr2+ Hg2+
Laser printer
Fluorescence
Cutting
Fluorescence
Hg2+, Pb2+, Cd2+, Fe3+, Cu2+ Cr6+
10 μM, 20 μM, 20 μM, 10 μM, 20 μM 0.24 μM
0.002 0.015 0.005 0.3 1.0 0.1
Wax printing Photo-lithography Wax and screen printing
CL Colorimetric Colorimetric
Cr3+ Cr6+ Ni2+, Cr6+, Hg2+ Cu, Fe, Zn
0.02 ppm 30 ppm 0.24 ppm, 0.18 ppm, 0.19 ppm 0.1 ppm
0.1 0.1 0.1 0.002
0.2 mM, 0.4mM 0.5 mM
0.3
[196] Sun
2018
paper,
[198] Anh
2017
[199] Abbasi-Moayed
2018
[200] Bu
2016
[201] Alahmad [203] Asano [204] Devad-hasan
2016 2018 2018
Filter paper, 2-D Chromatography paper, 2-D Chromatography paper, 2-D Chromatography paper, 2-D
[206] Hofstetter
2018
Chromatography paper, 2-D
Wax printing
Colorimetric
[207] Xu
2018
paper,
Laser printer and coating
Colorimetric
[209] Karita
2016
paper,
Wax printing
Colorimetric
[210] Ostad
2017
paper,
Hand drawn
Colorimetric
[212] Liu
2018
paper,
Immersed
Colorimetric
Fe3+, Ni2+ Ca2+, Mg2+ Ca, Mg Co2+
[218] Yakoh
2018
paper,
Wax printing
Colorimetric
Cl-
1.3 mg/L
[223] Petruci
2018
paper,
Wax printing
Colorimetric
HCN
10 ppb
[229] Rengaraj
2018
Filter 2-D Filter 2-D Filter 2-D Filter 2-D Filter 2-D Filter 2-D Filter 2-D
paper,
Screen printing
Electrochemical
Bacte- rial
1.9 × 103 CFU/mL
0.002
1.0 0.3 5
8.3 mg/L, 1.0 mg/L 10 mg/L 4.0
0
ECL: Electrochemiluminescence; ICP-MS: Inductively coupled plasma mass spectrometry; SR-TXRF: Synchrotron radiation-excited total reflection X-ray fluorescence; CL: Chemiluminescence; MCL: Maximum Contaminant Level in drinking water (National Primary Drinking Water Regulations, EPA).
the detection process, the cyanide was converted to cyanogen chloride via a chloramine-T/pyridine-barbituric acid reaction, and the cyanide concentration was then determined via an inspection of the resulting color change in the reaction region. A linear response was observed for cyanide concentrations in the range of 3.0 ∼ 100 μg/L. Moreover, the LOD was equal to 0.7 μg/L and the analyte recovery rate was 69 ∼ 111%. Scala-Benuzzi et al. [226,227] proposed an electrochemical paperbased immunocapture assay (EPIA) method for determining the concentration of ethinyl estradiol (EE2) in river water (see Fig. 9(c)). The EPIA method used paper microzones modified with silica nanoparticles
(SNs) and anti-EE2 specific antibodies to capture and pre-concentrate the EE2. The EE2 was then electrochemically detected by Osteryoung square wave voltammetry (OSWV), wherein the oxidation current was proportional to the EE2 concentration. The device response was found to vary linearly over the concentration range of 0.5 ∼ 120 ng/L with a LOD of 0.1 ng/L. Alcaine et al. [228] developed a phage amplification paper-based fluidic device combined with a colorimetric detection method for bacteria detection in river water samples. The device utilized bioengineered T7 phage strains to enhance the sensitivity of phage amplification-based lateral flow assays (LFA) by over 100-fold. The enhanced sensitivity enabled a LOD of 103 cfu/ml for E. coli after 7 h. 13
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Fig. 8. (a) (I) Schematic illustration of electrochemical cell with closing system on μPAD and corresponding voltammetric readout. (Reprinted from Ref. [217] with permission of American Chemical Society.) (b) Mechanism and fluorescence detection results for S2– using MTT-AuND-modified PAD sensor platform. (Reprinted from Ref. [219] with permission of American Chemical Society.).
look set to provide an invaluable contribution toward protecting and improving human and environmental health throughout the world for years to come. This article has provided a comprehensive review of the latest developments in μPAD technology in the environmental analysis and monitoring field. The review has focused particularly on the use of μPADs for the analysis of soil, air, pesticides, and river water. In general, the surveyed literature has confirmed that μPADs provide a cheap and practical alternative to the large-scale equipment used in traditional environmental monitoring applications. Many of the concepts and techniques adopted in the literature show significant potential for further development in the future. For example, μPADs combined with UAVs provide a promising approach for the detection of PM2.5 in the environment [128,129], and future monitoring of environmental sources is quite helpful. In addition, μPADs incorporating coated nanoparticles and graphene oxide (GO) also appear to have significant potential for the high-sensitivity, high-selectivity detection of pesticides, heavy metal ions, bacterial cells, allergens and toxins [129,157,233–242]. As a result, nanoparticles and GO seem likely to play a key role in enabling the development of sophisticated μPAD platforms in the future. Although μPAD technology has advanced rapidly in recent years, several key challenges still remain to be overcome. For example, the World Health Organization (WHO) and United States Environmental Protection Agency (US-EPA) have set permissible limits for Hg2+ in water (tap or drinking) of 0.001 and 0.002 ppm, respectively. However, existing colorimetric-based μPAD methods [168,175,243–246] achieve
Rong et al. [230] presented a ratiometric fluorescence paper-based device for anthrax biomarker detection based on ethylenediamine tetraacetic acid (EDTA) and Eu(III) ion functionalized manganese-doped carbon dots (FMn-CDs) (see Fig. 9(d)). It was shown that 2, 6-dipicolinic acid (DPA), an important biomarker of Bacillus anthracisspore, sensitized the Eu(III) combined on the FMn-CDs to produce bright red fluorescence under UV irradiation. The device exhibited a linear response over the range of 0.1–750 nM DPA and achieved a LOD of 0.1. Tawfik et al. [232] developed a paper-based sensor with a thiophene copolymer quantum dot (TCPQD)-doped chitosan film for determining the concentration of trace quantities of 2,4,6-trinitrophenol (TNP) explosive in tap water and river water samples using a fluorescence quenching technique. The LOD was found to be 2.29 pg TNP, while the recovery was 98.02∼107.50%. Table 2 briefly summarizes several other μPADs reported in the recent literature for the detection of organic contaminants and other microorganism pollutants. 4. Conclusions and outlook μPADs have attracted immense interest in recent decades for a wide variety of monitoring and analysis applications, including disease diagnosis, food safety, environmental monitoring, and others. μPADs are inexpensive, portable, highly sensitive, and straightforward to use. Consequently, they provide an ideal analysis tool for resource-constrained environments lacking highly-trained technicians and wellequipped laboratories. Future advances in μPAD technology, combined with a more extensive distribution and availability of μPAD devices, 14
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Fig. 9. (a) Schematic illustration of origami paper-based electrochemical biosensor for pesticide detection. (Reprinted from Ref. [221] with permission of Elsevier.) (b) Procedure, mechanism and analysis results for cyanide detection using colorimetric paper-based headspace extraction system. (Reprinted from Ref. [224] with permission of Elsevier.) (c) Schematic illustration of detection procedure for EE2 using electrochemical paper-based immunocapture assay device. (Reprinted from Ref. [226] with permission of American Chemical Society.) (d) Schematic illustration of colorimetric FMn-CD paper-based device for DPA detection using ratiometric fluorescence method. (Reprinted from Ref. [230] with permission of Elsevier.).
LODs of Hg2+ only of 0.002–10 ppm. In other words, the sensitivity of these methods is lower than the prescribed regulatory limit for drinking water. Nonetheless, paper-based fluorescent devices have many advantages, including high sensitivity, fluorescent probes providing a wide range of wavelengths, qualitative/quantitative analysis, dynamic wide linear range, and good repeatability. For example, QD fluorescence quenching, with a LOD limit in the range of 0.01 ∼ 10 μg/L (ppb) [81,153,199,247], appears to provide a possible solution for overcoming this problem, and thus merits further attention in future studies. Another problem to be addressed in the future is that of the detection system integrated with the μPAD. At present, many μPAD platforms use mass spectrometry to quantify the target analyte [127,248–250]. However, while mass spectrometry has the advantages of simplicity and reliability, the detection system is too large and expensive for in-situ monitoring and analysis. Therefore, the development of more portable and inexpensive detection systems also represents an important avenue of future μPAD research. At present, there are already μPAD related products for environmental pollution analysis in the world. For example, in the water quality testing, the home water test kit (Lamotte Co. USA; Bioeasy Biotechnology Co. China, et al.) has been introduced. Most of these rapid testing products are qualitative tests that quickly detect malachite green, Al, Cr, Fe, Cu and Cd in water. In the rapid detection of pesticides, there are also related μPAD products, such as rapid pesticide residue detection kits have also been developed (Neogen Co. USA; MRight Biomedical Co. Taiwan; Apex Biotechnology Co. Taiwan, etc.), most of which are used for insecticide analysis. Such insecticid, only Ops and CMs types, are also qualitative tests. In the rapid detection of
air and soil pollution, there are no commercially available μPAD products. Therefore, the application of μPAD in the rapid detection of environmental pollution is still worth developing, such as the development of various contaminated μPAD and the quantitative detection of μPAD platform. In conclusion, this review has distilled out the key concepts from the huge body of information available in the literature relating to μPAD platforms for environmental analysis and monitoring applications. μPAD technology has advanced dramatically over the past ten years or so and, provided that the challenges described above are overcome, appears to represent the analytical tool of choice for reliable and inexpensive environmental analysis into the foreseeable future. Acknowledgement This study was supported by the Ministry of Science and Technology of Taiwan (107-2622-B-006-007-CC2, 106-2221-E-006-253-MY3, and 106-2314-B-006-085-MY3). Appendix A. Supplementary data Supplementary material related to this article can be found, in the online version, at doi:https://doi.org/10.1016/j.snb.2019.126855. References [1] L.M. Fu, Y.N. Wang, Detection methods and applications of microfluidic paperbased analytical devices, Trends Anal. Chem. 107 (2018) 196–211.
15
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C.-T. Kung, et al. [2] W. He, M. You, W. Wan, F. Xu, F. Li, A. Li, Point-of-care periodontitis testing: biomarkers, current technologies, and perspectives, Trends Biotechnol. 36 (2018) 1127–1144. [3] A.W. Martinez, S.T. Phillips, M.J. Butte, G.M. Whitesides, Patterned paper as a platform for inexpensive, low-volume, portable, bioassays, Angew. Chem. Int. Ed. 46 (2007) 1318–1320. [4] J.R. Choi, K.W. Yong, R. Tang, Y. Gong, T. Wen, F. Li, B. Pingguan-Murphy, D. Bai, F. Xu, Advances and challenges of fully integrated paper-based point-of-care nucleic acid testing, Trends Anal. Chem. 93 (2017) 37–50. [5] Z. Li, H. Liu, X. He, F. Xu, F. Li, Pen-on-paper strategies for point-of-care testing of human health, Trends Anal. Chem. 108 (2018) 50–64. [6] P. Teengam, W. Siangproh, A. Tuantranont, T. Vilaivan, O. Chailapakul, C.S. Henry, Electrochemical impedance-based DNA sensor using pyrrolidinyl peptide nucleic acids for tuberculosis detection, Anal. Chim. Acta 1044 (2018) 102–109. [7] G. Zhu, X. Yin, D. Jin, B. Zhang, Y. Gu, Y. An, Paper-based immunosensors: current trends in the types and applied detection techniques, Trends Anal. Chem. 111 (2019) 100–117. [8] Y. Yang, E. Noviana, M.P. Nguyen, J. Geiss, D.S. Dandy, C.S. Henry, Paper-based microfluidic devices: emerging themes and applications, Anal. Chem. 89 (2017) 71–91. [9] R.J. Yang, C.C. Tseng, W.J. Ju, H.L. Wang, L.M. Fu, A rapid paper-based detection system for determination of human serum albumin concentration, Chem. Eng. J. 352 (2018) 241–246. [10] E.L. Rossini, M.I. Milani, E. Carrilho, L. Pezza, H.R. Pezza, Simultaneous determination of renal function biomarkers in urineusing a validated paper-based microfluidic analytical device, Anal. Chim. Acta 997 (2018) 16–23. [11] R.J. Yang, C.C. Tseng, W.J. Ju, L.M. Fu, M.P. Syu, Integrated microfluidic paperbased system for determination of whole blood albumin, Sens. Actuators B Chem. 273 (2018) 1091–1097. [12] P. Kassal, M.D. Steinberg, E. Horak, I.M. Steinberg, Wireless fluorimeter for mobile and low cost chemical sensing: a paperbasedchloride assay, Sens. Actuators B Chem. 275 (2018) 230–236. [13] C.C. Tseng, R.J. Yang, W.J. Ju, L.M. Fu, Microfluidic paper-based platform for whole blood creatinine detection, Chem. Eng. J. 348 (2018) 117–124. [14] C.C. Liu, Y.N. Wang, L.M. Fu, D.Y. Yang, Rapid integrated microfluidic paperbased system for sulfur dioxide detection, Chem. Eng. J. 316 (2017) 790–796. [15] C.C. Liu, Y.N. Wang, L.M. Fu, Y.H. Huang, Microfluidic paper-based chip platform for formaldehyde concentration detection, Chem. Eng. J. 332 (2018) 695–701. [16] J.M.C.C. Guzmana, L.L. Tayoa, C.C. Liu, Y.N. Wang, L.M. Fu, Rapid microfluidic paper-based platform for low concentration formaldehyde detection, Sens. Actuators B Chem. 255 (2018) 3623–3629. [17] C.C. Liu, Y.N. Wang, L.M. Fu, K.L. Chen, Microfluidic paper-based chip platform for benzoic acid detection in food, Food Chem. 249 (2018) 162–167. [18] G.G. Morbioli, T. Mazzu-Nascimento, A.M. Stockton, E. Carrilho, Technical aspects and challenges of colorimetric detection with microfluidic paper-based analytical devices (μPADs) – a review, Anal. Chim. Acta 970 (2017) 1–22. [19] J. Mettakoonpitak, C.S. Henry, Electrophoretic separations on Parafilm-paperbased analytical devices, Sens. Actuators B Chem. 273 (2018) 1022–1028. [20] Q. Kong, Y. Wang, L. Zhang, S. Ge, J. Yu, A novel microfluidic paper-based colorimetric sensor based on molecularly imprinted polymer membranes for highly selective and sensitive detection of bisphenol A, Sens. Actuators B Chem. 243 (2017) 130–136. [21] L. Ma, A. Nilghaz, J.R. Choi, X. Liu, X. Lu, Rapid detection of clenbuterol in milk using microfluidic paper-based ELISA, Food Chem. 246 (2018) 437–441. [22] L.M. Fu, C.C. Tseng, W.J. Ju, R.J. Yang, Rapid paper-based system for human serum creatinine detection, Inventions 3 (2018) 34. [23] T.M.G. Cardoso, F.R. de Souza, P.T. Garcia, D. Rabelo, C.S. Henry, W.K.T. Coltro, Versatile fabrication of paper-based microfluidic devices with high chemical resistance using scholar glue and magnetic masks, Anal. Chim. Acta 974 (2017) 63–68. [24] G.P. dos Santos, C.C. Corrêa, L.T. Kubota, A simple, sensitive and reduced cost paper-based device with low quantity of chemicals for the early diagnosis of Plasmodium falciparum malaria using an enzyme-based colorimetric assay, Sens. Actuators B Chem. 255 (2018) 2113–2120. [25] M.P. Nguyen, N.A. Meredith, S.P. Kelly, C.S. Henry, Design considerations for reducing sample loss in microfluidic paper-based analytical devices, Anal. Chim. Acta 1017 (2018) 20–25. [26] J. Lee, Y.J. Lee, Y.J. Ahn, S. Choi, G.J. Lee, A simple and facile paper-based colorimetric assay for detection of free hydrogen sulfide in prostate cancer cells, Sens. Actuators B Chem. 256 (2018) 828–834. [27] L.M. Fu, C.C. Liu, C.E. Yang, Y.N. Wang, C.H. Ko, A PET/paper chip platform for high resolution sulphur dioxide detection in foods, Food Chem. 286 (2019) 316–321. [28] T. Akyazi, L. Basabe-Desmonts, F. Benito-Lopez, Review on microfluidic paperbased analytical devices towards commercialization, Anal. Chim. Acta 1001 (2018) 1–17. [29] A. Nilghaz, L. Guan, W. Tan, W. Shen, Advances of paper-based microfluidics for diagnostics–The original motivation and current status, ACS Sens. 1 (2016) 1382–1393. [30] Y.S. Kim, Y. Yang, C.S. Henry, Laminated and infused Parafilm@-paper for paperbased analytical devices, Sens. Actuators B Chem. 255 (2018) 3654–3661. [31] L. Sun, Y. Jiang, R. Pan, M. Li, R. Wang, S. Chen, S. Fu, C. Man, A novel, simple and low-cost paper-based analytical device for colorimetric detection of Cronobacter spp, Anal. Chim. Acta 1036 (2018) 80–88. [32] J. Wang, W. Li, L. Ban, W. Du, X. Feng, B. Liu, A paper-based device with an
[33] [34] [35]
[36]
[37] [38] [39] [40] [41] [42] [43] [44] [45] [46] [47]
[48]
[49] [50] [51] [52] [53] [54] [55] [56] [57]
[58] [59] [60]
16
adjustable time controller for the rapid determination of tumor biomarkers, Sens. Actuators B Chem. 254 (2018) 855–862. C.H. Wang, J.J. Wu, G.B. Lee, Screening of highly-specific aptamers and their applications in paper-based microfluidic chips for rapid diagnosis of multiple bacteria, Sens. Actuators B Chem. 284 (2019) 395–402. A.W. Martinez, S.T. Phillips, G.M. Whitesides, E. Carrilho, Diagnostics for the developing world: microfluidic paper-based analytical devices, Anal. Chem. 82 (2010) 3–10. L. Guadarrama-Fernández, M. Novell, P. Blondeau, F.J. Andrade, A disposable, simple, fast and low-cost paper-based biosensor and its application to the determination of glucose in commercial orange juices, Food Chem. 265 (2018) 64–69. P.T. Garcia, E.F.M. Gabriel, G.S. Pessôa, J.C.S. Júnior, P.C.M. Filho, R.B.F. Guidugli, N.F. Höehr, M.A.Z. Arruda, W.K.T. Coltro, Paper-based microfluidic devices on the crime scene: a simple tool for rapid estimation of postmortem interval using vitreous humour, Anal. Chim. Acta 974 (2017) 69–74. A. Rayaprolu, S.K. Srivastava, K. Anand, L. Bhati, A. Asthana, C.M. Rao, Fabrication of cost-effective and efficient paper-based device for viscosity A. Measurement, Anal. Chim. Acta 1044 (2018) 86–92. F.A. Kappi, G.Z. Tsogas, A. Routs, D.C. Christodouleas, D.L. Giokas, Paper-based devices for biothiols sensing using the photochemical reduction of silver halides, Anal. Chim. Acta 1036 (2018) 89–96. L. Huang, P. Jiang, D. Wang, Y. Luo, M. Li, H. Lee, R.A. Gerhardt, A novel paperbased flexible ammonia gas sensor via silver and SWNT-PABS inkjet printing, Sens. Actuators B Chem. 197 (2014) 308–313. S. Liu, R. Cao, J. Wu, L. Guan, M. Li, J. Liu, J. Tian, Directly writing barrier-free patterned biosensors and bioassays on paper for low-cost diagnostics, Sens. Actuators B Chem. 285 (2019) 529–535. T. Tiana, H. Liua, L. Li, J. Yu, S. Ge, X. Song, M. Yan, Paper-based biosensor for noninvasive detection of epidermal growth factor receptor mutations in non-small cell lung cancer patients, Sens. Actuators B Chem. 251 (2017) 440–445. M. Rahbar, P.N. Nesterenko, B. Paull, M. Macka, High-throughput deposition of chemical reagents via pen-plotting technique for microfluidic paper-based analytical devices, Anal. Chim. Acta 1047 (2019) 115–123. L. Xiao, Z. Zhang, C. Wu, L. Han, H. Zhang, Molecularly imprinted polymer grafted paper-based method for the detection of 17β-estradiol, Food Chem. 221 (2017) 82–86. G.G. Morbioli, T. Mazzu-Nascimento, A.M. Stockton, E. Carrilho, Technical aspects and challenges of colorimetric detection with microfluidic paper-basedanalytical devices (μPADs) – a review, Anal. Chim. Acta 970 (2017) 1–22. Y.J. Lee, K.S. Eom, K. Shin, J.Y. Kang, S.H. Lee, Enzyme-loaded paper combined impedimetric sensor for the determination of the low-level of cholesterol in saliva, Sens. Actuators B Chem. 271 (2018) 73–81. Y. Fu, X. Zhou, D. Xing, Integrated paper-based detection chip with nucleic acid extraction and amplification for automatic and sensitive pathogen detection, Sens. Actuators B Chem. 261 (2018) 288–296. S. Doughan, U. Uddayasankar, A. Peri, U.J. Krull, Apaper-based multiplexed resonance energy transfer nucleic acid hybridization assay using a single form of upconversion nanoparticleas donor and three quantum dots as acceptors, Anal. Chim. Acta 962 (2017) 88–96. M. Pavithra, S. Muruganand, C. Parthiban, Development of novel paper based electrochemical immunosensor with self-made goldnanoparticle ink and quinone derivate for highly sensitive carcinoembryonic antigen, Sens. Actuators B Chem. 257 (2018) 496–503. S.M. Russell, R. de la Rica, Papertransducers to detect plasmon variations in colorimetric nanoparticle biosensors, Sens. Actuators B Chem. 270 (2018) 327–332. Z. Wang, J. Zhang, L. Liu, X. Wu, H. Kuang, C. Xu, L. Xu, A colorimetric paperbased sensor for toltrazuril and its metabolites in feed, chicken, and egg samples, Food Chem. 276 (2019) 707–713. M.M. Ali, C.L. Brown, S. Jahanshahi-Anbuhi, B. Kannan, Y. Li, C.D.M. Filipe, J.D. Brennan, A printed multicomponent paper sensor for bacterial detection, Sci. Rep. 7 (2017) 12335. X. Li, D.R. Ballerini, W. Shen, A perspective on paper-based microfluidics: current status and future trends, Biomicrofluid. 6 (2012) 011301. C. Teng, D. Xie, J. Wang, Z. Yang, G. Ren, Y. Zhu, Ultrahigh conductive graphene paper based on ball‐milling exfoliated graphene, Adv. Funct. Mater. 27 (2017) 1700240. D.R. Ballerini, X. Li, W. Shen, Patterned paper and alternative materials as substrates for low-cost microfluidic diagnostics, Microfluid. Nanofluid. 13 (2012) 769–787. P. Wang, Z. Cheng, Q. Chen, L. Qu, X. Miao, Q. Feng, Construction of a paperbased electrochemical biosensing platform for rapid and accurate detection of adenosine triphosphate (ATP), Sens. Actuators B Chem. 256 (2018) 931–937. D.M. Cate, J.A. Adkins, J. Mettakoonpitak, C.S. Henry, Recent developments in paper-based microfluidic devices, Anal. Chem. 87 (2015) 19–41. H. Wang, Y. Jian, Q. Kong, H. Liu, F. Lan, L. Liang, S. Ge, J. Yu, Ultrasensitive electrochemical paper-based biosensor for microRNA via strand displacement reaction and metal-organic frameworks, Sens. Actuators B Chem. 257 (2018) 561–569. A.A.S. Samson, J. Lee, J.M. Song, Inkjet printing-based photo-induced electron transfer reaction on parchment paper using riboflavin as a photosensitizer, Anal. Chim. Acta 1012 (2018) 49–59. N. Ruecha, K. Shin, O. Chailapakul, N. Rodthongkum, Label-free paper-based electrochemical impedance immunosensor for human interferon gamma detection, Sens. Actuators B Chem. 279 (2019) 298–304. L. Guadarrama-Fernández, M. Novell, P. Blondeau, F.J. Andrade, A disposable,
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al.
[61] [62] [63] [64]
[65] [66]
[67] [68] [69] [70] [71]
[72] [73] [74] [75] [76] [77]
[78] [79] [80] [81]
[82]
[83] [84]
[85]
[86]
simple, fast and low-cost paper-based biosensor and its application to the determination of glucose in commercial orange juices, Food Chem. 265 (2018) 64–69. N. Dossi, R. Toniolo, F. Terzi, N. Sdrigotti, F. Tubaro, G. Bontempelli, A cotton thread fluidic device with a wall-jet pencil-drawn paper based dual electrode detector, Anal. Chim. Acta 1040 (2018) 74–80. S. Bharadwaj, A. Pandey, B. Yagci, V. Ozguz, A. Qureshi, Graphene nano-mesh-AgZnO hybrid paper for sensitive SERS sensing and self-cleaning of organic pollutants, Chem. Eng. J. 336 (2018) 445–455. Y. Chen, W. Chu, W. Liu, X. Guo, Distance-based carcinoembryonic antigen assay on microfluidic paper immunodevice, Sens. Actuators B Chem. 260 (2018) 452–459. E. Jaworsk, G. Pomarico, B.B. Bern, K. Maksymiuk, R. Paolesse, A. Michalska, Allsolid-state paper based potentiometric potassium sensors containing cobalt(II) porphyrin/cobalt(III) corrole in the transducer layer, Sens. Actuators B Chem. 277 (2018) 306–311. Q. Huang, K. Zhang, Y. Yang, J. Ren, R. Sun, F. Huang, X. Wang, Highly smooth, stable and reflective Ag-paper electrode enabled by silver mirror reaction for organic optoelectronics, Chem. Eng. J. 370 (2019) 1048–1056. J. Park, J.K. Park, Pressed region integrated 3Dpaper-based microfluidic device that enables vertical flow multistep assays for the detection of C-reactive protein basedon programmed reagent loading, Sens. Actuators B Chem. 246 (2017) 1049–1055. R.A.G. de Oliveira, F. Camargo, N.C. Pesquero, R.C. Faria, A simple method to produce 2D and 3D microfluidic paper-based analytical devices for clinical analysis, Anal. Chim. Acta 957 (2017) 40–46. X. Weng, S.R. Ahmed, S. Neethirajan, A nanocomposite-based biosensor for bovine haptoglobin on a 3Dpaper-based analytical device, Sens. Actuators B Chem. 265 (2018) 242–248. L. Fan, Q. Hao, X. Kan, Three-dimensional graphite paper based imprinted electrochemical sensor for tertiary butylhydroquinone selective recognition and sensitive detection, Sens. Actuators B Chem. 256 (2018) 520–527. X. Sun, B. Li, C. Tian, F. Yu, N. Zhou, Y. Zhan, L. Chen, Rotational paper-based electrochemiluminescence immunodevices for sensitive and multiplexed detection of cancer biomarkers, Anal. Chim. Acta 1007 (2018) 33–39. G. Sriram, M.P. Bhat, P. Patil, U.T. Uthappa, H.Y. Jung, T. Altalhi, T. Kumeria, T.M. Aminabhavi, R.K. Pai, M.D.K. Madhuprasad, Paper-based microfluidic analytical devices for colorimetric detection of toxic ions: a review, Trends Anal, Chem. 93 (2017) 212–227. A.T. Singh, D. Lantigua, A. Meka, S. Taing, M. Pandher, G. Camci-Unal, Paperbased sensors: emerging themes and applications, Sensors 18 (2018) 2838. J.P. Rojas, D. Conchouso, A. Arevalo, D. Singh, I.G. Foulds, M.M. Hussain, Based origami flexible and foldable thermoelectric nanogenerator, Nano Energy 31 (2017) 296–301. W. Chu, Y. Chen, W. Liu, M. Zhao, H. Li, Paper-based chemiluminescence immunodevice with temporal controls of reagent transport technique, Sens. Actuators B Chem. 250 (2017) 324–332. A. Alba-Patiño, S.M. Russell, R. de la Rica, Origami-enabled signal amplification for paper-based colorimetric biosensors, Sens. Actuators B Chem. 273 (2018) 951–954. K.H. Chou, S.H. Yeh, R.J. Yang, Enhanced sample concentration on a three-dimensional origami paper-based analytical device with non-uniform assay channel, Microfluid. Nanofluid. 21 (2017) 112. S.A. Nogueira, A.D. Lemes, A.C. Chagas, M.L. Vieira, M. Talhavini, P.A.O. Morais, W.K.T. Coltro, Redox titration on foldable paper-based analytical devices for the visual determination of alcohol content in whiskey samples, Talanta 194 (2019) 363–369. L. Xie, X. Zi, H. Zeng, J. Sun, L. Xu, S. Chen, Low-cost fabrication of a paper-based microfluidic using a folded pattern paper, Anal. Chim. Acta 1053 (2019) 131–138. Y. Lin, D. Gritsenko, F. S, Y.C.I.X. Lu, J. Xu, Detection of heavy metal by paperbased microfluidics, Biosens. Bioelectron. 83 (2016) 256–266. R.S. Aparna, J.S.A. Devi, P. Sachidanandan, S. George, Polyethylene imine capped copper nanoclusters- fluorescent and colorimetric onsite sensor for the trace level detection of TNT, Sens. Actuators B Chem. 254 (2018) 811–819. J. Qi, B. Li, X. Wang, Z. Zhang, Z. Wang, J. Han, L. Chen, Three-dimensional paperbased microfluidic chip device for multiplexed fluorescence detection of Cu2+ and Hg2+ ions based on ion imprinting technology, Sens. Actuators B Chem. 251 (2017) 224–233. J. Bhardwaj, S. Devarakonda, S. Kumar, J. Jang, Development of a paper-based electrochemical immunosensor using an antibody-single walled carbon nanotubes bio-conjugate modified electrode for label-free detection of foodborne pathogens, Sens. Actuators B Chem. 253 (2017) 115–123. M.I.G.S. Almeida, B.M. Jayawardane, S.D. Kolev, I.D. McKelvie, Developments of microfluidic paper-based analytical devices (μPADs) for water analysis: a review, Talanta 177 (2018) 176–190. S. Ge, J. Zhao, S. Wang, F. Lan, M. Yan, J. Yu, Ultrasensitive electrochemiluminescence assay of tumor cells and evaluation of H2O2 on apaper-based closed-bipolar electrode by in-situ hybridization chain reaction amplification, Biosens. Bioelectron. 102 (2018) 411–417. K. Chu, P. Chen, Y. You, H. Chang, W. Kao, Y. Chu, C. Wu, J. Shyue, Integration of paper-based microarray and time-of-flight secondary ion mass spectrometry (ToFSIMS) for parallel detection and quantification of molecules in multiple samples automatically, Anal. Chim. Acta 1005 (2018) 61–69. Y. Xu, P. Man, Y. Huo, T. Ning, C. Li, B. Man, C. Yang, Synthesis of the 3D AgNF/ AgNP arrays for the paper-based surface enhancement Raman scattering application, Sens. Actuators B Chem. 265 (2018) 302–309.
[87] Y. Wu, Y. Ren, L. Han, Y. Yan, H. Jiang, Three-dimensional paper based platform for automatically running multiple assays in a single step, Talanta 200 (2019) 177–185. [88] E. Erçağ, A. Üzer, Ş. Eren, Ş. Sağlam, H. Filik, R. Apak, Rapid detection of nitroaromatic and nitramine explosives on chromatographic paper and their reflectometric sensing on PVC tablets, Talanta 85 (2011) 2226–2232. [89] J. Wang, L. Yang, B. Liu, H. Jiang, R. Liu, J. Yang, G. Han, Q. Mei, Z. Zhang, Inkjetprinted silver nanoparticle paper detects airborne species from crystalline explosives and their ultratrace residues in open environment, Anal. Chem. 86 (2014) 3338–3345. [90] P. Ryan, D. Zabetakis, D. Stenger, S. Trammell, Integrating paper chromatography with electrochemical detection for the trace analysis of TNT in soil, Sensors 15 (2015) 17048–17056. [91] M. Ueland, L. Blanes, R.V. Taudte, B.H. Stuart, N. Cole, P. Willis, P. Doble, Capillary-driven microfluidic paper-based analytical devices for lab on a chip screening of explosive residues in soil, J. Chromatograp. A 1436 (2016) 28–33. [92] S.T. Krauss, V.C. Holt, J.P. Landers, Simple reagent storage in polyester-paper hybrid microdevices for colorimetric detection, Sens. Actuators B Chem. 246 (2017) 740–747. [93] K.L. Peters, I. Corbin, L.M. Kaufman, K. Zreibe, L. Blanes, B.R. McCord, Simultaneous colorimetric detection of improvised explosive compounds using microfluidic paper based analytical devices (μPADs), Anal. Methods 7 (2015) 63–70. [94] L. Shriver-Lake, D. Zabetakis, W. Dressick, D. Stenger, S. Trammell, Paper-based electrochemical detection of chlorate, Sensors 18 (2018) 328. [95] S.S.B. Moram, C. Byram, S.N. Shibu, B.M. Chilukamarri, V.R. Soma, Ag/Au nanoparticle-loaded paper-based versatile surface-enhanced Raman spectroscopy substrates for multiple explosives detection, ACS Omega 3 (2018) 8190–8201. [96] W. Xiao, Y. Gao, Y. Zhang, J. Li, Z. Liu, J. Nie, J. Li, Enhanced 3D paper-based devices with a personal glucose meter for highly sensitive and portable biosensing of silver ion, Biosens. Bioelectron. 137 (2019) 154–160. [97] H. Arabyarmohammadi, A.K. Darban, M. Abdollahy, B. Ayati, Simultaneous immobilization of heavy metals in soil environment by pulp and paper derived nanoporous biochars, J. Environ. Health Sci. Eng. 16 (2018) 109–119. [98] S.H. Nam, Y.J. An, Disc method: an efficient assay for evaluating metal toxicity to soil algae, Environ. Pollut. 216 (2016) 1–8. [99] P.G. Sutariya, H. Soni, S.A. Gandhi, A. Pandya, Single-step fluorescence recognition of As3+, Nd3+ and Br− using pyrene-linked calix[4]arene: application to real samples, computational modelling and paper-based device, New J. Chem. 43 (2019) 737–747. [100] P.G. Sutariya, H. Soni, S.A. Gandhi, A. Pandya, Novel tritopic calix[4]arene CHEFPET fluorescence paper based probe for La3+, Cu2+, and Br−: its computational investigation and application to real samples, J. Lumin. 212 (2019) 171–179. [101] P.G. Sutariya, H. Soni, S.A. Gandhi, A. Pandya, Novel luminescent paper based calix[4]arene chelation enhanced fluorescence- photoinduced electron transfer probe for Mn2+, Cr3+ and F−, J. Lumin. 208 (2019) 6–17. [102] B.M. Jayawardane, I.D. McKelvie, S.D. Kolev, A paper-based device for measurement of reactive phosphate in water, Talanta 100 (2012) 454–460. [103] B.M. Jayawardane, W. Wongwilai, K. Grudpan, S.D. Kolev, M.W. Heaven, D.M. Nash, I.D. McKelvie, Evaluation and application of a paper-based device for the determination of reactive phosphate in soil solution, J. Environ. Qual. 43 (2014) 1081–1085. [104] B.M. Jayawardane, I.D. McKelvie, S.D. Kolev, Development of a gas-diffusion microfluidic paper-based analytical device (μPAD) for the determination of ammonia in wastewater samples, Anal. Chem. 87 (2015) 4621–4626. [105] A.G. Wang, T. Dong, H. Mansour, G. Matamoros, A.L. Sanchez, F. Li, Paper-based DNA reader for visualized quantification of soil-transmitted helminth Infections, ACS Sens. 3 (2018) 205–210. [106] E. Pellegrini, M. Contin, L. Vittori Antisari, G. Vianello, C. Ferronato, M. De Nobili, A new paper sensor method for field analysis of acid volatile sulfides in soils, Environ. Toxicol. Chem. 37 (2018) 3025–3031. [107] S.H. Nam, J.I. Kwak, Y.J. An, Assessing applicability of the paper-disc method used in combination with flow cytometry to evaluate algal toxicity, Environ. Pollut. 234 (2018) 979–987. [108] H. Liu, W. Gao, Y. Tian, A. Liu, Z. Wang, Y. Cai, Z. Zhao, Rapidly detecting tetrabromobisphenol A in soils and sediments by paper spray ionization mass spectrometry combined with isotopic internal standard, Talanta 191 (2019) 272–276. [109] P. Basuri, A. Baidya, T. Pradeep, Sub-parts-per-trillion level detection of analytes by superhydrophobic preconcentration paper spray ionization mass spectrometry (SHPPSI MS), Anal. Chem. 91 (2019) 7118–7124. [110] P. Naik, S. Jaitpal, P. Shetty, D. Paul, An integrated one-step assay combining thermal lysis and loop-mediated isothermal DNA amplification (LAMP) in 30 min from E. Coli and M. Smegmatis cells on a paper substrate, Sens. Actuators B Chem. 291 (2019) 74–80. [111] T.S. Park, J.Y. Yoon, Smartphone detection of Escherichia coli from field water samples on paper microfluidics, IEEE Sens. J. 15 (2015) 1902–1907. [112] J. Zhang, Z. Yang, Q. Liu, H. Liang, Electrochemical biotoxicity detection on a microfluidic paper-based analytical device via cellular respiratory inhibition, Talanta 202 (2019) 384–391. [113] G.A.R.Y. Suaifan, M. Zourob, Portable paper-based colorimetric nanoprobe for the detection of Stachybotrys chartarum using peptide labeled magnetic nanoparticles, Microchim. Acta 186 (2019) 230. [114] T. Soga, Y. Jimbo, K. Suzuki, D. Citterio, Inkjet-printed paper-based colorimetric sensor array for the discrimination of volatile primary amines, Anal. Chem. 85 (2013) 8973–8978. [115] P. Tang, G. Sun, Highly sensitive colorimetric paper sensor for methyl
17
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al.
[116] [117] [118] [119] [120] [121] [122] [123] [124] [125] [126] [127] [128] [129] [130] [131] [132] [133]
[134]
[135] [136] [137] [138] [139] [140] [141] [142] [143] [144] [145]
isothiocyanate (MITC): using its toxicological reaction, Sens. Actuators B Chem. 261 (2018) 178–187. Y. Chen, R.E. Owyeung, S.R. Sonkusale, Combined optical and electronic papernose for detection of volatile gases, Anal. Chim. Acta 1034 (2018) 128–136. A. Fraiwan, H. Lee, S. Choi, A paper-based cantilever array sensor: monitoring volatile organic compounds with naked eye, Talanta 158 (2016) 57–62. T. Kuretake, S. Kawahara, M. Motooka, S. Uno, An electrochemical gas biosensor based on enzymes immobilized on chromatography paper for ethanol vapor detection, Sensors 17 (2017) 281. M. Motooka, S. Uno, Improvement in limit of detection of enzymatic biogas sensor utilizing chromatography paper for breath analysis, Sensors 18 (2018) 440. Z. Wen, S. Song, C. Wang, F. Qu, T. Thomas, T. Hu, P. Wang, M. Yang, Large-scale synthesis of dual-emitting-based visualization sensing paper for humidity and ethanol detection, Sens. Actuators B Chem. 282 (2019) 9–15. M. Luo, K. Shao, Z. Long, L. Wang, C. Peng, J. Ouyang, N. Na, A paper-based plasma-assisted cataluminescence sensor for ethylene detection, Sens. Actuators B Chem. 240 (2017) 132–141. R.S. Alkasir, A. Rossner, S. Andreescu, Portable colorimetric paper-based biosensing device for the assessment of bisphenol A in indoor dust, Environ. Sci. Technol. 49 (2015) 9889–9897. N. Colozz, K. Kehe, G. Dionisi, T. Popp, A. Tsoutsoulopoulos, D. Steinritz, D. Moscone, F. Arduini, A wearable origami-like paper-based electrochemical biosensor for sulfur mustard detection, Biosens. Bioelectron. 129 (2019) 15–23. L. Huang, P. Jiang, D. Wang, Y. Luo, M. Li, H. Lee, R.A. Gerhardt, A novel paperbased flexible ammonia gas sensor via silver and SWNT-PABS inkjet printing, Sens. Actuators B Chem. 197 (2014) 308–313. L.R. Shobin, S. Manivannan, Carbon nanotubes on paper: flexible and disposable chemiresistors, Sens. Actuators B Chem. 220 (2015) 1178–1185. A. Maity, B. Ghosh, Fast response paper based visual color change gas sensor for efficient ammonia detection at room temperature, Sci. Reports 8 (2018) 16851. A. Maity, A.K. Raychaudhuri, B. Ghosh, High sensitivity NH3 gas sensor with electrical readout made on paper with perovskite halide as sensor material, Sci. Rep. 9 (2019) 7777. J.F.D.S. Petruci, A.A. Cardoso, Portable and disposable paper-based fluorescent sensor for in situ gaseous hydrogen sulfide determination in near real-time, Anal. Chem. 88 (2016) 11714–11719. A. Quddious, S. Yang, M. Khan, F. Tahir, A. Shamim, K. Salama, H. Cheema, Disposable, paper-based, inkjet-printed humidity and H2S gas sensor for passive sensing applications, Sensors 16 (2016) 2073. J.F. da Silveira Petruci, A.A. Cardoso, Sensitive luminescent paper-based sensor for the determination of gaseous hydrogen sulfide, Anal. Methods 7 (2015) 2687–2692. J. Zhang, L. Huang, Y. Lin, L. Chen, Z. Zeng, L. Shen, Q. Chen, W. Shi, Pencil-trace on printed silver interdigitated electrodes for paper-based NO2 gas sensors, Appl. Phys. Lett. 106 (2015) 143101. H. Kan, M. Li, J. Luo, B. Zhang, J. Liu, Z. Hu, G. Zhang, S. Jaing, H. Liu, PbS nanowires-on-paper sensors for room-temperature gas detection, IEEE Sens. J. 19 (2019) 846–851. J. Sitanurak, N. Wangdi, T. Sonsa-ard, S. Teerasong, T. Amornsakchai, D. Nacapricha, Simple and green method for direct quantification of hypochlorite in household bleach with membraneless gas-separation microfluidic paper-based analytical device, Talanta 187 (2018) 91–98. E.S. Dhummakupt, P.M. Mach, D. Carmany, P.S. Demond, T.S. Moran, T. Connell, H.S. Wylie, N.E. Manicke, J.M. Nilles, T. Glaros, Direct analysis of aerosolized chemical warfare simulants captured on a modified glass-based substrate by “paper-spray” ionization, Anal. Chem. 89 (2017) 10866–10872. H. Sun, Y. Jia, H. Dong, L. Fan, J. Zheng, Multiplex quantification of metals in airborne particulate matter via smartphone and paper-based microfluidics, Anal. Chim. Acta 1044 (2018) 110–118. H. Sun, Y. Jia, H. Dong, L. Fan, Graphene oxide nanosheets coupled with paper microfluidics for enhanced on-site airborne trace metal detection, Microsyst. Nanoeng. 5 (2019) 4. W. Dungchai, Y. Sameenoi, O. Chailapakul, J. Volckens, C.S. Henry, Determination of aerosol oxidative activity using silver nanoparticle aggregation on paper-based analytical devices, Analyst 138 (2013) 6766–6773. P. Rattanarat, W. Dungchai, D. Cate, J. Volckens, O. Chailapakul, C.S. Henry, Multilayer paper-based device for colorimetric and electrochemical quantification of metals, Anal. Chem. 86 (2014) 3555–3562. D.T. Nguyen, H.R. Kim, J.H. Jung, K.B. Lee, B.C. Kim, The development of paper discs immobilized withluciferase/D-luciferin for the detection of ATP from airborne bacteria, Sens. Actuators B Chem. 260 (2018) 274–281. A.J. Gimenez, G. Luna-Barcenas, I.C. Sanchez, J.M. Yanez-Limon, Paper-based ZnO oxygen sensor, IEEE Sens. J. 15 (2015) 1246–1251. H. Zhao, L. Zang, H. Zhao, Y. Zhang, Y. Zheng, Z. Zhang, W. Cao, Oxygen sensing properties of gadolinium labeled hematoporphyrin monomethyl ether based on filter paper, Sens. Actuators B Chem. 206 (2015) 351–356. H. Zhao, T. Zhang, R. Qi, J. Dai, S. Liu, T. Fei, Drawn on paper: a reproducible humidity sensitive device by handwriting, ACS Appl, Mater. Interfaces 9 (2017) 28002–28009. X. Zang, C. Shen, Y. Chu, B. Li, M. Wei, J. Zhong, M. Sanghadasa, L. Lin, Laser‐induced molybdenum carbide–graphene composites for 3D foldable paper electronics, Adv. Mater. 30 (2018) 1800062. R.M. Morais, M. dos Santos Klem, G.L. Nogueira, T.C. Gomes, N. Alves, Low cost humidity sensor based on PANI/PEDOT: PSS printed on paper, IEEE Sens. J. 18 (2018) 2647–182651. J. Zhang, A.B. Dichiara, I. Novosselov, D. Gao, J. Chung, Polyacrylic acid coated
[146] [147] [148] [149] [150] [151] [152] [153] [154] [155] [156] [157] [158] [159] [160] [161] [162]
[163] [164] [165] [166] [167] [168] [169] [170] [171] [172]
[173]
[174]
18
carbon nanotube–paper composites for humidity and moisture sensing, J. Mater. Chem. C Mater. Opt. Electron. Devices 7 (2019) 5374–5380. P. Tian, X. Gao, G. Wen, L. Zhong, Z. Wang, Z. Guo, Novel fabrication of polymer/ carbon nanotube composite coated Janus paper for humidity stress sensor, J. Colloid Interface Sci. 532 (2018) 517–526. X. Zang, Y. Jiang, X. Wang, X. Wang, J. Ji, M. Xue, Highly sensitive pressure sensors based on conducting polymer-coated paper, Sens. Actuators B Chem. 273 (2018) 1195–1201. S. Chen, Y. Song, F. Xu, Flexible and highly sensitive resistive pressure sensor based on carbonized crepe paper with corrugated structure, ACS Appl. Mater. Interfaces 10 (2018) 34646–34654. W. Liu, J. Kou, H. Xing, B. Li, Based chromatographic chemiluminescence chip for the detection of dichlorvos in vegetables, Biosens. Bioelectron. 52 (2014) 76–81. W. Liu, Y. Guo, J. Luo, J. Kou, H. Zheng, B. Li, Z. Zhang, A molecularly imprinted polymer based a lab-on-paper chemiluminescence device for the detection of dichlorvos, Spectrochim. Acta A. Mol. Biomol. Spectrosc. 141 (2015) 51–57. Z. Ayazi, F. Shekari Esfahlan, P. Matin, Graphene oxide reinforced polyamide nanocomposite coated on paper as a novel layered sorbent for microextraction by packed sorbent, Int. J. Environ. Anal. Chem. 98 (2018) 1118–1134. A. Apilux, W. Siangproh, N. Insin, O. Chailapakul, V. Prachayasittikul, Paperbased thioglycolic acid (TGA)-capped CdTe QD device for rapid screening of organophosphorus and carbamate insecticides, Anal. Methods 9 (2017) 519–527. W. Yang, L. Zhang, H. Liu, Z. Gu, Smartphone-based paper microfluidic device for potentiometric detection of pesticide, Chinese J. Anal. Chem. 44 (2016) 586–590. H.J. Kim, Y. Kim, S.J. Park, C. Kwon, H. Noh, Development of colorimetric paper sensor for pesticide detection using competitive-inhibiting reaction, Biochip J. 12 (2018) 326–331. S. Nouanthavong, D. Nacapricha, C.S. Henry, Y. Sameenoi, Pesticide analysis using nanoceria-coated paper-based devices as a detection platform, Analyst 141 (2016) 1837–1846. J. Ding, B. Li, L. Chen, W. Qin, A three‐dimensional origami paper‐based device for potentiometric biosensing, Angew. Chem. Int. Ed. 55 (2016) 13033–13037. J. Chang, H. Li, T. Hou, F. Li, Based fluorescent sensor for rapid naked-eye detection of acetylcholinesterase activity and organophosphorus pesticides with high sensitivity and selectivity, Biosens. Bioelectronics 86 (2016) 971–977. C. Liu, F.A. Gomez, A microfluidic paper‐based device to assess acetylcholinesterase activity, Electrophoresis 38 (2017) 1002–1006. G. Scordo, D. Moscone, G. Palleschi, F. Arduini, A reagent-free paper-based sensor embedded in a 3D printing device for cholinesterase activity measurement in serum, Sens. Actuators B Chem. 258 (2018) 1015–1021. Y. Wu, Y. Sun, F. Xiao, Z. Wu, R. Yu, Sensitive inkjet printing paper-based colormetric strips for acetylcholinesterase inhibitors with indoxyl acetate substrate, Talanta 162 (2017) 174–179. M. Kavruk, V.C. Özalp, H.A. Öktem, Portable bioactive paper-based sensor for quantification of pesticides, J. Anal. Methods Chem. (2013) 932946. Z. Ayazi, F.S. Esfahlan, Z.M. Khoshhesab, ZnO nanoparticles doped polyamide nanocomposite coated on cellulose paper as a novel sorbent for ultrasound-assisted thin film microextraction of organophosphorous pesticides in aqueous samples, Anal. Methods 10 (2018) 3043–3051. C. Zhang, H. Cui, Y. Han, F. Yu, X. Shi, Development of a biomimetic enzymelinked immunosorbent assay based on molecularly imprinted polymers on paper for the detection of carbaryl, Food Chem. 240 (2018) 893–897. A. Mohammadi, F. Ghasemi, M.R. Hormozi-Nezhad, Development of a paperbased plasmonic test strip for visual detection of methiocarb insecticide, IEEE Sens. J. 17 (2017) 6044–6049. Q. Wang, Y. Liu, Y. Bai, S. Yao, Z. Wei, M. Zhang, L. Wang, L. Wang, Superhydrophobic SERS substrates based on silver dendrite-decorated filter paper for trace detection of nitenpyram, Anal. Chim. Acta 1049 (2019) 170–178. A. Apilux, C. Isarankura-Na-Ayudhya, T. Tantimongcolwat, V. Prachayasittikul, Based acetylcholinesterase inhibition assay combining a wet system for organophosphate and carbamate pesticides detection, EXCLI J. 14 (2013) 307–319. M.E. Badawy, A.F. El-Aswad, Bioactive paper sensor based on the acetylcholinesterase for the rapid detection of organophosphate and carbamate pesticides, Int. J. Anal. Chem. (2014) 536823. Y. Ma, Y. Wang, Y. Luo, H. Duan, D. Li, H. Xu, E.K. Fodjo, Rapid and sensitive onsite detection of pesticide residues in fruits and vegetables using screen-printed paper-based SERS swabs, Anal. Methods 10 (2018) 4655–4664. H. Evard, A. Kruve, R. Lõhmus, I. Leito, Paper spray ionization mass spectrometry: study of a method for fast-screening analysis of pesticides in fruits and vegetables, J. Food Anal. 41 (2015) 221–225. M. Lee, K. Oh, H.K. Choi, S.G. Lee, H.J. Youn, H.L. Lee, D.H. Jeong, Subnanomolar sensitivity of filter paper-based SERS sensor for pesticide detection by hydrophobicity change of paper surface, ACS Sens. 3 (2018) 151–159. C. Zhang, T. You, N. Yang, Y. Gao, L. Jiang, P. Yin, Hydrophobic paper-based SERS platform for direct-droplet quantitative determination of melamine, Food Chem. 287 (2019) 363–368. D. Deng, Q. Lin, H. Li, Z. Huang, Y. Kuang, H. Chen, J. Kong, Rapid detection of malachite green residues in fish using a surface-enhanced Raman scattering-active glass fiber paper prepared by in situ reduction method, Talanta 200 (2019) 272–278. P.A. Atanasov, N.N. Nedyalkov, N. Fukata, W. Jevasuwan, T. Subramani, M. Terakawa, Ya Nakajima, Surface-enhanced Raman spectroscopy (SERS) of mancozeb and thiamethoxam assisted by gold and silver nanostructures produced by laser techniques on paper, Appl. Spectrosc. 73 (2019) 313–319. S. Cinti, C. Minotti, D. Moscone, G. Palleschi, F. Arduini, Fully integrated ready-touse paper-based electrochemical biosensor to detect nerve agents, Biosens.
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al. Bioelectronics 93 (2017) 46–51. [175] L.J. Sun, Y. Xie, Y.F. Yan, H. Yang, H.Y. Gu, N. Bao, Based analytical devices for direct electrochemical detection of free IAA and SA in plant samples with the weight of several milligrams, Sens. Actuators B Chem. 247 (2017) 336–342. [176] S. Lee, J. Park, J.K. Park, Foldable paper-based analytical device for the detection of an acetylcholinesterase inhibitor using an angle-based readout, Sens. Actuators B Chem. 273 (2018) 322–327. [177] A.T. Jafry, H. Lee, A.P. Tenggara, H. Lim, Y. Moon, S.H. Kim, Y. Lee, S.M. Kim, S. Park, D. Byun, J. Lee, Double-sided electrohydrodynamic jet printing of twodimensional electrode array in paper-based digital microfluidics, Sens. Actuators B Chem. 282 (2019) 831–837. [178] A. İncel, O. Akın, A. Cagır, Ü. Yıldızc, M.M. Demir, Smart phone assisted detection and quantification of cyanide in drinking water by paper based sensing platform, Sens. Actuators B Chem. 252 (2017) 886–893. [179] Y. Li, Y. Chen, H. Yu, L. Tian, Z. Wang, Portable and smart devices for monitoring heavy metal ions integrated with nanomaterials, Trends Anal, Chem. 98 (2018) 190–200. [180] N.N. Hamidon, Y. Hong, G.I. Salentijn, E. Verpoorte, Water-based alkyl ketene dimer ink for user-friendly patterning in paper microfluidics, Anal. Chim. Acta 1000 (2018) 180–190. [181] M. Rahbar, B. Paull, M. Macka, Instrument-free argentometric determination of chloride via trapezoidal distance-based microfluidic paper devices, Anal. Chim. Acta 1063 (2019) 1–8. [182] A. Sánchez-Calvo, M.T. Fernández-Abedul, M.C. Blanco-López, A. Costa-García, Paper-based electrochemical transducer modified with nanomaterials for mercury determination in environmental waters, Sens. Actuators B Chem. 290 (2019) 87–92. [183] P. Vijitvarasan, S. Oaew, W. Surareungchai, Based scanometric assay for lead ion detection using DNAzyme, Anal. Chim. Acta 896 (2015) 152–159. [184] J. Xu, Y. Zhang, L. Li, Q. Kong, L. Zhang, S. Ge, J. Yu, Colorimetric and electrochemiluminescence dual-mode sensing of lead Ion based on integrated Lab-onpaper device, ACS Appl. Mater. Interfaces 10 (2018) 3431–3440. [185] H. Sun, W. Li, Z.Z. Dong, C. Hu, C.H. Leung, D.L. Ma, K. Ren, A suspending-droplet mode paper-based microfluidic platform for low-cost, rapid, and convenient detection of lead (II) ions in liquid solution, Biosens. Bioelectronics 99 (2018) 361–367. [186] P. Li, J. Li, M. Bian, D. Huo, C. Hou, P. Yang, M. Yang, A redox route for the fluorescence detection of lead ions in sorghum, river water ad tap water and a desk study of a paper-based probe, Anal. Methods 10 (2018) 3256–3262. [187] X. Lin, S.X. Li, F.Y. Zheng, An integrated system for field analysis of Cd (ii) and Pb (ii) via preconcentration using nano-TiO2/cellulose paper composite and subsequent detection with a portable X-ray fluorescence spectrometer, RSC Adv. 6 (2016) 9002–9006. [188] N. Fakhri, M. Hosseini, O. Tavakoli, Aptamer-based colorimetric determination of Pb2+ using a paper-based microfluidic platform, Anal. Methods 10 (2018) 4438–4444. [189] E. de Almeida, V.F. do Nascimento Filho, A.A. Menegário, Based diffusive gradients in thin films technique coupled to energy dispersive X-ray fluorescence spectrometry for the determination of labile Mn, Co, Ni, Cu, Zn and Pb in river water, Spectrochim. Acta Part B At. Spectrosc. 71 (2018) 70–74. [190] Y. Zhang, M. Li, H. Liu, S. Ge, J. Yu, Label-free colorimetric logic gates based on free gold nanoparticles and the coordination strategy between cytosine and silver ions, New J. Chem. 40 (2016) 5516–5522. [191] J. Dhavamani, L.H. Mujawar, M.S. El-Shahawi, Hand drawn paper-based optical assay plate for rapid and trace level determination of Ag+ in water, Sens. Actuators B Chem. 258 (2018) 321–330. [192] A. Sadollahkhani, A. Hatamie, O. Nur, M. Willander, B. Zargar, I. Kazeminezhad, Colorimetric disposable paper coated with ZnO@ ZnS core–shell nanoparticles for detection of copper ions in aqueous solutions, ACS Appl. Mater. Interfaces 6 (2014) 17694–17701. [193] X. Liu, C. Zong, L. Lu, Fluorescent silver nanoclusters for user-friendly detection of Cu2+ on a paper platform, Analyst 137 (2012) 2406–2414. [194] Y. Cui, X. Wang, Q. Zhang, H. Zhang, H. Li, M. Meyerhoff, Colorimetric copper ion sensing in solution phase and on paper substrate based on catalytic decomposition of S-nitrosothiol, Anal. Chim. Acta 1053 (2019) 155–161. [195] L. Liu, M.R. Xie, F. Fang, Z.Y. Wu, Sensitive colorimetric detection of Cu2+ by simultaneous reaction and electrokinetic stacking on a paper-based analytical device, Microchem. J. 139 (2018) 357–362. [196] X. Sun, B. Li, A. Qi, C. Tian, J. Han, Y. Shi, B. Lin, L. Chen, Improved assessment of accuracy and performance using a rotational paper-based device for multiplexed detection of heavy metals, Talanta 178 (2018) 426–431. [197] G.H. Chen, W.Y. Chen, Y.C. Yen, C.W. Wang, H.T. Chang, C.F. Chen, Detection of mercury (II) ions using colorimetric gold nanoparticles on paper-based analytical devices, Anal. Chem. 86 (2014) 6843–6849. [198] N.T.N. Anh, A.D. Chowdhury, R.A. Doong, Highly sensitive and selective detection of mercury ions using N, S-codoped graphene quantum dots and its paper strip based sensing application in wastewater, Sens. Actuators B Chem. 252 (2017) 1169–1178. [199] S. Abbasi-Moayed, H. Golmohammadi, M.R. Hormozi-Nezhad, A nanopaper-based artificial tongue: a ratiometric fluorescent sensor array on bacterial nanocellulose for chemical discrimination applications, Nanoscale 10 (2018) 2492–2502. [200] L. Bu, J. Peng, H. Peng, S. Liu, H. Xiao, D. Liu, Z. Pan, Y. Chen, F. Chen, Y. He, Fluorescent carbon dots for the sensitive detection of Cr (VI) in aqueous media and their application in test papers, RSC Adv. 6 (2016) 95469–95475. [201] W. Alahmad, K. Uraisin, D. Nacapricha, T. Kaneta, A miniaturized chemiluminescence detection system for a microfluidic paper-based analytical device and its
[202] [203] [204] [205]
[206]
[207] [208] [209] [210]
[211] [212]
[213] [214] [215] [216] [217] [218] [219]
[220] [221] [222] [223] [224] [225]
[226] [227]
[228]
19
application to the determination of chromium (III), Anal. Methods 8 (2016) 5414–5420. S. Faham, G. Khayatian, H. Golmohammadi, R. Ghavami, A paper-based optical probe for chromium by using gold nanoparticles modified with 2, 2′-thiodiacetic acid and smartphone camera readout, Microchim. Acta 185 (2018) 374. H. Asano, Y. Shiraishi, Microfluidic paper-based analytical device for the determination of hexavalent chromium by photolithographic fabrication using a photomask printed with 3D printer, Anal. Sci. 34 (2018) 71–74. J.P. Devadhasan, J. Kim, A chemically functionalized paper-based microfluidic platform for multiplex heavy metal detection, Sens. Actuators B Chem. 273 (2018) 18–24. H. Asano, Y. Shiraishi, Development of paper-based microfluidic analytical device for iron assay using photomask printed with 3D printer for fabrication of hydrophilic and hydrophobic zones on paper by photolithography, Anal. Chim. Acta 883 (2015) 55–60. J.C. Hofstetter, J.B. Wydallis, G. Neymark, T.H. Reilly III, J. Harrington, C.S. Henry, Quantitative colorimetric paper analytical devices based on radial distance measurements for aqueous metal determination, Analyst 143 (2018) 3085–3090. W. Xu, X. Chen, S. Cai, J. Chen, Z. Xu, H. Jia, J. Chen, Superhydrophobic titania nanoparticles for fabrication of paper-based analytical devices: an example of heavy metals assays, Talanta 181 (2018) 333–339. J.J. Li, C.J. Hou, D.Q. Huo, C.H. Shen, X.G. Luo, H.B. Fa, M. Yang, J. Zhou, Detection of trace nickel ions with a colorimetric sensor based on indicator displacement mechanism, Sens. Actuators B Chem. 241 (2017) 1294–1302. S. Karita, T. Kaneta, Chelate titrations of Ca2+ and Mg2+ using microfluidic paperbased analytical devices, Anal. Chim. Acta 924 (2016) 60–67. M.A. Ostad, A. Hajinia, T. Heidari, A novel direct and cost effective method for fabricating paper-based microfluidic device by commercial eye pencil and its application for determining simultaneous calcium and magnesium, Microchem. J. 133 (2017) 545–550. H. Kudo, K. Yamada, D. Watanabe, K. Suzuki, D. Citterio, Based analytical device for zinc ion quantification in water samples with power-free analyte concentration, Micromachines 8 (2017) 127. X. Liu, Y. Yang, Q. Li, Z. Wang, X. Xing, Y. Wang, Portably colorimetric paper sensor based on ZnS quantum dots for semi-quantitative detection of Co2+ through the measurement of grey level, Sens. Actuators B Chem. 260 (2018) 1068–1075. Y.C. Liu, C.H. Hsu, B.J. Lu, P.Y. Lin, M.L. Ho, Determination of nitrite ions in environment analysis with a paper-based microfluidic device, Dalton Trans. 47 (2018) 14799–14807. T.M. Cardoso, P.T. Garcia, W.K. Coltro, Colorimetric determination of nitrite in clinical, food and environmental samples using microfluidic devices stamped in paper platforms, Anal. Methods 7 (2015) 7311–7317. F. Pena-Pereira, L. Villar-Blanco, I. Lavilla, C. Bendicho, Test for arsenic speciation in waters based on a paper-based analytical device with scanometric detection, Anal. Chim. Acta 1011 (2018) 1–10. P. Devi, A. Thakur, R.Y. Lai, S. Saini, R. Jain, P. Kumar, Progress in the materials for optical detection of arsenic in water, Trend Anal, Chem. 110 (2019) 97–115. M. Cuartero, G.A. Crespo, E. Bakker, Based thin-layer coulometric sensor for halide determination, Anal. Chem. 87 (2015) 1981–1990. A. Yakoh, P. Rattanarat, W. Siangproh, O. Chailapakul, Simple and selective paper-based colorimetric sensor for determination of chloride ion in environmental samples using label-free silver nanoprisms, Talanta 178 (2018) 134–140. N. Vasimalai, M.T. Fernández-Argüelles, B. Espiña, Detection of sulfide using mercapto tetrazine-protected fluorescent gold nanodots: preparation of paperbased testing kit for on-site monitoring, ACS Appl, Mater. Interfaces 10 (2018) 1634–1645. M.C. Díaz-Liñán, A.I. López-Lorente, S. Cárdenas, R. Lucena, Molecularly imprinted paper-based analytical device obtained by a polymerization-free synthesis, Sens. Actuators B Chem. 287 (2019) 138–146. F. Arduini, S. Cinti, V. Caratelli, L. Amendola, G. Palleschi, D. Moscone, Origami multiple paper-based electrochemical biosensors for pesticide detection, Biosens.Bioelectronics 126 (2019) 346–354. S. Cinti, D. Talarico, G. Palleschi, D. Moscone, F. Arduini, Novel reagentless paperbased screen-printed electrochemical sensor to detect phosphate, Anal. Chim. Acta 919 (2016) 78–84. J.F. da Silveira Petruci, P.C. Hauser, A.A. Cardoso, Colorimetric paper-based device for gaseous hydrogen cyanide quantification based on absorbance measurements, Sens. Actuators B Chem. 268 (2018) 392–397. M. Saraji, N. Bagheri, Based headspace extraction combined with digital image analysis for trace determination of cyanide in water samples, Sens. Actuators B Chem. 270 (2018) 28–34. M. Zarejousheghani, S. Schrader, M. Möder, T. Mayer, H. Borsdorf, Negative electrospray ionization ion mobility spectrometry combined with paper-based molecular imprinted polymer disks: a novel approach for rapid target screening of trace organic compounds in water samples, Talanta 190 (2018) 47–54. M.L. Scala-Benuzzi, J. Raba, G.J. Soler-Illia, R.J. Schneider, G.A. Messina, Novel electrochemical paper-based immunocapture assay for the quantitative determination of ethinylestradiol in water samples, Anal. Chem. 90 (2018) 4104–4111. M.L. Scala-Benuzzi, E.A. Takara, M. Alderete, G.J. Soler-Illia, R.J. Schneider, J. Raba, G.A. Messina, Ethinylestradiol quantification in drinking water sources using a fluorescent paper based immunosensor, Microchem. J. 141 (2018) 287–293. S.D. Alcaine, K. Law, S. Ho, A.J. Kinchla, D.A. Sela, S.R. Nugen, Bioengineering bacteriophages to enhance the sensitivity of phage amplification-based paper
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al. fluidic detection of bacteria, Biosens. Bioelectronics 82 (2016) 14–19. [229] S. Rengaraj, A. Cruz-Izquierdo, J.L. Scott, M. Di Lorenzo, Impedimetric paperbased biosensor for the detection of bacterial contamination in water, Sens. Actuators B Chem. 265 (2018) 50–58. [230] M. Rong, Y. Liang, D. Zhao, B. Chen, C. Pan, X. Deng, Y. Chen, J. He, A ratiometric fluorescence visual test paper for an anthrax biomarker based on functionalized manganese-doped carbon dots, Sens. Actuators B Chem. 265 (2018) 498–505. [231] T. Akyazi, A. Tudor, D. Diamond, L. Basabe-Desmonts, L. Florea, F. Benito-Lopez, Driving flows in microfluidic paper-based analytical devices with a cholinium based poly (ionic liquid) hydrogel, Sens. Actuators B Chem. 261 (2018) 372–378. [232] S.M. Tawfik, M. Sharipov, S. Kakhkhorov, M.R. Elmasry, Y.I. Lee, Multiple emitting amphiphilic conjugated polythiophenes‐coated CdTe QDs for picogram detection of trinitrophenol explosive and application using chitosan film and paper‐based sensor coupled with smartphone, Adv. Science (2019) 1801467. [233] L. Baptista‐Pires, J. Orozco, P. Guardia, A. Merkoçi, Architecting graphene oxide rolled‐up micromotors: a simple paper‐based manufacturing technology, Small 14 (2018) 1702746. [234] X. Weng, S. Neethirajan, Paper‐based microfluidic aptasensor for food safety, J. Food Saf. 38 (2018) e12412. [235] Y. Yao, C. Jiang, J. Ping, Flexible freestanding graphene paper-based potentiometric enzymatic aptasensor for ultrasensitive wireless detection of kanamycin, Biosens. Bioelectronics 123 (2019) 178–184. [236] Y. Yao, C. Jiang, J. Ping, Flexible freestanding graphene paper-based potentiometric enzymatic aptasensor for ultrasensitive wireless detection of kanamycin, Biosens. Bioelectronics 123 (2019) 178–184. [237] K.V. Ragavan, P. Egan, S. Neethirajan, Multi mimetic Graphene Palladium nanocomposite based colorimetric paper sensor for the detection of neurotransmitters, Sens. Actuators B Chem. 273 (2018) 1385–1394. [238] N.T.N. Anh, A.D. Chowdhury, R.A. Doong, Highly sensitive and selective detection of mercury ions using N, S-codoped graphene quantum dots and its paper strip based sensing application in wastewater, Sens. Actuators B Chem. 252 (2017) 1169–1178. [239] P. Teengam, W. Siangproh, A. Tuantranont, C.S. Henry, T. Vilaivan, O. Chailapakul, Electrochemical paper-based peptide nucleic acid biosensor for detecting human papillomavirus, Anal. Chim. Acta 952 (2017) 32–40. [240] L. Cao, C. Fang, R. Zeng, X. Zhao, F. Zhao, Y. Jiang, Z. Chen, A disposable paperbased microfluidic immunosensor based on reduced graphene oxide-tetraethylene pentamine/Au nanocomposite decorated carbon screen-printed electrodes, Sens. Actuators B Chem. 252 (2017) 44–54. [241] M.S. Khan, S.K. Misra, K. Dighe, Z. Wang, A.S. Schwartz-Duval, D. Sar, D. Pan, Electrically-receptive and thermally-responsive paper-based sensor chip for rapid detection of bacterial cells, Biosens. Bioelectronics 110 (2018) 132–140. [242] N. Ruecha, K. Shin, O. Chailapakul, N. Rodthongkum, Label-free paper-based electrochemical impedance immunosensor for human interferon gamma detection, Sens. Actuators B Chem. 279 (2019) 298–304. [243] R. Meelapsom, P. Jarujamrus, M. Amatatongchai, S. Chairam, C. Kulsing, W. Shen, Chromatic analysis by monitoring unmodified silver nanoparticles reduction ondouble layer microfluidic paper-based analytical devices for selective and sensitivedetermination of mercury(II), Talanta 155 (2016) 193–201. [244] N. Pourreza, H. Golmohammadi, S. Rastegarzadeh, Highly selective and portable chemosensor for mercury determination in water samples using curcumin
nanoparticles in a paper based analytical device, RSC Adv. 6 (2016) 69060–69066. [245] W.W. Chen, X.E. Fang, H. Li, H.M. Cao, J.L. Kong, A simple paper-based colorimetric device for rapid mercury(II) assay, Sci. Rep. 6 (2016) 7. [246] S.K. Patil, D. Das, A nanomolar detection of mercury (II) ion by a chemodosimetric rhodamine-based sensor in an aqueous medium: potential applications in real water samples and as paper strips Spectrochim, Acta A Mol. Biomol. Spectrosc. 210 (2019) 44–51. [247] M. Zhao, H. Li, W. Liu, W. Chu, Y. Chen, Paper-based laser induced fluorescence immunodevice combining with CdTe embedded silica nanoparticles signal enhancement strategy, Sens. Actuators B Chem. 242 (2017) 87–94. [248] Y. Yang, J. Wu, J. Deng, K. Yuan, X. Chen, N. Liu, T. Luan, Rapid and on-site analysis of amphetamine-type illicit drugs in whole blood and raw urine by slugflow microextraction coupled with paper spray mass spectrometry, Anal. Chim. Acta 1032 (2018) 75–82. [249] M. Yu, R. Wen, L. Jiang, S. Huang, Z. Fang, B. Chen, L. Wang, Rapid analysis of benzoic acid and vitamin C in beverages by paper spray mass spectrometry, Food Chem. 268 (2018) 411–415. [250] D. Kim, J. Lee, B. Kim, Optimization and application of paper-based spray ionization mass spectrometry for analysis of natural organic matter, Anal. Chem. 90 (2018) 12027–12034. Chia-Te Kung received the B.S. and M.S. degrees from the Department of Medicine and Public Health Institute, Kaohsiung Medical University, Kaohsiung, Taiwan, in 1991 and 2011, respectively. He has been with the Emergency Department, Kaohsiung Chang Gung Memorial Hospital, since 1991. He is currently an Associate Professor with the Department of Medicine, Chang Gung University. His specialties include emergency medicine, critical care medicine, microfluidics paper-based devices and their biomedical applications, and disaster medicine. Chih-Yao Hou received M.S. and Ph.D. degrees from the Department of Food Science from National Pingtung University of Science and Technology, Taiwan, in 2004 and 2008, respectively. He is currently an Assistant Professor in the Department of Seafood Science at National Kaohsiung University of Science and Technology. His current research involves food engineering, food protein chemistry, food inspection and analysis, and microfluidic paper-based devices and applications. Yao-Nan Wang received M.S. and Ph.D. degrees from the Department of Mechanical Engineering from National Cheng Kung University (NCKU), Taiwan, in 2003 and 2008, respectively. He is currently an Associate Professor in the Department of Vehicle Engineering at National Pingtung University of Science and Technology. His current research involves thermo-fluid engineering and integration of microdevices. Lung-Ming Fu received M.S. and Ph.D. degrees in Engineering Science from National Cheng Kung University (NCKU), Taiwan, in 1997 and 2001. He had his postdoc training in Department of Engineering Science at NCKU during 2002-2003. He is currently a Distinguished Professor of Engineering Science Department at National Cheng Kung University, Tainan, Taiwan. His research interests are in microfluidic systems, microfluidic paper-based devices and applications, MEMS fabrication technologies, microsensor and computational fluid dynamics.
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Contents lists available at ScienceDirect
Sensors and Actuators B: Chemical journal homepage: www.elsevier.com/locate/snb
Microfluidic paper-based analytical devices for environmental analysis of soil, air, ecology and river water Chia-Te Kunga, Chih-Yao Houb, Yao-Nan Wangc, Lung-Ming Fud,e,
T
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a
Department of Emergency Medicine, Kaohsiung Chang Gung Memorial Hospital, Chang Gung University College of Medicine, Kaohsiung, 833, Taiwan Department of Seafood Science, National Kaohsiung University of Science and Technology, Kaohsiung 811, Taiwan c Department of Vehicle Engineering, National Pingtung University of Science and Technology, Pingtung 912, Taiwan d Department of Engineering Science, National Cheng Kung University, Tainan, 701, Taiwan e Graduate Institute of Materials Engineering, National Pingtung University of Science and Technology, Pingtung 912, Taiwan b
ARTICLE INFO
ABSTRACT
Keywords: Microfluidic Paper-based devices Water Soil Air Ecology Pesticide Environment
Microfluidic paper-based analytical devices (μPADs) have experienced rapid growth over the past decade due to their simple design, low cost, minimal sample requirement, and good sensitivity, selectivity and accuracy. While designed originally for point-of-care medical diagnostics, biological, and food safety applications, μPADs are now used increasingly for environmental monitoring purposes. This review provides a detailed overview of the μPADs developed over the past ten years for the environmental analysis of soil, air, ecology (pesticides) and river water. The review commences by introducing the fabrication techniques and detection methods used in μPAD technology. A detailed description of the main μPAD frameworks proposed in the past decade for environmental monitoring is then provided. The review concludes by examining the challenges facing μPADs for environmental monitoring and identifying probable avenues of future research.
1. Introduction As technology has advanced, the environment has become increasingly polluted with heavy metals, nutrients, microorganisms, organic pollutants, pesticides, and so on. Many of these pollutants are extremely harmful to human health, and hence the problem of developing instrumented techniques capable of detecting analyte concentrations in diverse sample matrices on the scale of parts per million (ppm), or even parts per trillion (ppt), has attracted great interest in recent decades. To meet the needs of the monitoring community for high sensitivity and low detection limits, most analytic methods rely on expensive equipment, which requires a high level of training to operate reliably. However, there is a growing need for low-cost technologies to detect and monitor environmental contaminant concentrations quickly, easily and in-field in order to provide more timely data regarding the extent and magnitude of pollution. Microfluidic paper-based analytical devices (μPADs) off ;er an opportunity to address this need by increasing the frequency and geographic coverage of environmental monitoring, while simultaneously reducing the analytic costs and complexity of the measurement process. μPAD platforms enable the realization of low-cost, flexible, simple and portable analytical instruments [1–3]. μPADs typically consist of a
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small piece of patterned paper with a 2D or 3D structure capable of testing several tens of micro-liters of liquid sample within a relatively short period of time. During the past decade, numerous papers have been published in the μPAD field [4,5]. Typically, the devices proposed in these papers comprise an arrangement of microfluidic channels created by patterning hydrophobic materials on hydrophilic paper [6–8]. The testing process for biological substances (e.g., tears, urine, blood, sweat, saliva) [9–13], food (e.g., additives, bacteria, organic compounds) [14–17], and environmental reagents (e.g., heavy metal ions, nutrients, organic contaminants, microorganisms) [18–21] involves wicking the sample to the detection zone under the effects of capillary action without the need for an external pump [22–27]. Analytic detection is then facilitated by a chemical reaction process, which induces a change in color, electrochemical properties and / or light absorption or emission of the detection zone. Continuing industrialization and technological development has led to serious pollution of the air, soil and water in many regions of the world. Typically, these pollutants include nutrients, such as carbon, nitrogen and phosphorus, and many other contaminants, including heavy metals, organic contaminants, pharmaceuticals, herbicides, insecticides, disinfectants and industrial byproducts. Such pollution not only causes serious harm to the environment and surrounding
Corresponding author at: Department of Engineering Science, National Cheng Kung University, Tainan, 701, Taiwan. E-mail address: [email protected] (L.-M. Fu).
https://doi.org/10.1016/j.snb.2019.126855 Received 25 April 2019; Received in revised form 18 July 2019; Accepted 22 July 2019 Available online 08 August 2019 0925-4005/ © 2019 Elsevier B.V. All rights reserved.
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ecosystems, but also poses a major threat to human health and economic development. For a more detailed overview of the clinical presentations of some of the main environmental pollutants affecting humans nowadays, please refer to Supplementary Materials Table S1. Given the magnitude of the problem, the need for simple and cost-effective methods to enable the reliable monitoring of environmental pollution has emerged as a critical concern in recent years. This review provides a comprehensive overview of the main μPAD platforms developed over the past decade for environmental monitoring. The review commences by describing the various types of substrate material used in the fabrication of μPAD devices. Typical μPAD fabrication methods and detection techniques are then introduced. A detailed description of the main μPAD frameworks proposed over the past ten years for the analysis of soil, air, ecology (pesticides), and river water is then presented. Finally, the major challenges facing μPADs for environmental monitoring and analysis purposes are discussed, and likely directions of future research explored.
2.2. μPAD fabrication techniques Numerous approaches are available for fabricating μPADs using chemical modification or physical deposition techniques to alter the material characteristics of the cellulose matrix. In general, the treatment process changes the properties of specific areas of the cellulose paper from hydrophilic to hydrophobic; with parallel hydrophobic lines providing channels to guide the liquid flow as it permeates through the substrate under the effects of capillary action. The resulting μPADs can be broadly classified as either 2-dimensional (2D) [60–65] or 3-dimensional (3D) [66–70], depending on the direction (horizontal or horizontal / vertical) in which the fluid flows. Many methods have been proposed for fabricating μPADs, including lithography; 3D printing; wax printing; wax jetting; wax smearing; inkjet printing; screen printing; polydimethylsiloxane (PDMS) masking; laser cutting; hot embossing; printer cutting; sol-gel processing; scholar glue spraying; hydrophobic silanization; stamping; wet etching; and permanent marker pen, technical drawing pen, and eyeliner pencil writing. For a more detailed overview of the principles and comparisons of the main fabrication techniques, please refer to the review articles [71,72]. In recent years, a low-cost and efficient “origami” paperfolding method has also been proposed for the production of 3D μPADs based simply on the folding of the paper substrate [73–77]. For example, Xie et al. [78] developed a 3D μPAD, in which a paper mask coated with a thin layer of uncured PDMS mixture was folded with chromatographic paper to form a sandwich structure and was then heated to prompt the penetration of the PDMS into the chromatographic paper.
2. μPAD paper selection, fabrication and detection techniques 2.1. Paper selection Many different types of paper may be employed in μPADs depending on the fabrication method used and the particular analyte in question, including filter paper, chromatography paper, bioactive paper, glossy paper, nitrocellulose membrane paper, graphite paper, vegetal paper, and flexible paper [28–32]. Among these various types of paper, filter paper and chromatography paper (e.g., Whatman or Advantec) are among the most commonly used due to their relatively uniform thickness and superior pore size, which lead to enhanced adsorption and retention properties together with an improved wicking performance [33–38]. Furthermore, both papers undergo full bleaching following manufacturing, which removes virtually all of the impurities from the paper matrix. Glossy paper has also been proposed as a viable material for μPADs [39]. Glossy paper is composed of cellulose fibers and inorganic fillers blended into a paper matrix and has the advantage that its surface properties are more easily altered than those of traditional paper substrates. Bioactive paper has also been applied in μPADs [40,41]. In traditional paper substrates, only cationic molecules adsorb onto the wet cellulose fibers which make up the paper matrix. Furthermore, while proteins can be adsorbed on cellulose fibers, the rate and extent of this adsorption process is much lower than that of other hydrophilic surfaces. Consequently, the cellulose fibers must be modified in some way as to allow them to more readily absorb biomolecules. In bioactive paper, this is achieved by activating the surface of the paper using aldehyde or amide, for example, and then covalently conjugating biomolecules to the activated surface. Nitrocellulose membranes have also been used as μPAD substrates due to their chemical functional groups, which readily enable the covalent immobilization of biomolecules. Nitrocellulose additionally allows for charge-charge interactions, weak hydrogen bonds, and van der Waals interactions with protein-based substrates [42–44]. Due to their high protein-binding abilities, such membranes are commonly used in enzyme-linked immunosorbent assays (ELISA) and gold nanoparticle-based assays [45–50]. However, while nitrocellulose membranes can be easily patterned by wax printing, the penetration of the molten wax through the membrane thickness is slow compared to that in filter paper [51–53]. In graphite paper, the physically stripped graphene dispersion is further processed into layered graphene sheets by rapid filtration, high temperature annealing, and mechanical compression [54–59]. The resulting high-quality graphene and close contact between graphene sheets impart the graphene paper with ultrahigh conductive properties, which render the paper an ideal substrate material for electrical-based μPAD applications.
2.3. Detection techniques Many traditional techniques are available for the detection of toxic substances such as nutrients, heavy metals, microorganisms, organic contaminants and pesticides in environmental analyses. These methods include inductively coupled plasma mass spectrometry (ICP-MS), inductively coupled plasma-atomic/optical emission spectrometry (ICPAES/OES), energy dispersive X-ray fluorescence (EDXRF), electrochemical methods, electrothermal atomic adsorption spectrometry (ETAAS), flame atomic absorption spectrometry (FAAS), gas chromatography (GC), high-performance liquid chromatography (HPLC), gas chromatography-mass spectrometry (GC–MS), and atomic absorption spectrophotometry (AAS) [79]. Generally speaking, these methods have high sensitivity, good specificity, and excellent precision. However, all of them require complex equipment, professional personnel, and laborious operations. Thus, there is an urgent requirement for detection methods which are simpler, more cost-effective, and portable. This need is particularly pressing in developing countries and areas of the world with a lack of infrastructure, professional experts, and appropriate environmental treatment. Most previous research on μPADs has focused mainly on the design of the microfluidic chip itself rather than the overall detection system [1]. Thus, while modern μPADs are typically very small, the associated detection and correlation devices are still rather large. Moreover, they are generally available only in well-equipped laboratories and inspection centers. Consequently, the developed μPADs cannot be used for onsite detection and still require extensive inspector training. To address these problems, recent research has attempted to realize truly portable μPAD platforms, in which not only the sampling process, but also the detection and analysis procedures, can be performed on-site. Typically, these platforms involve the use of such detection techniques as colorimetric detection, fluorescence detection, electrochemical detection, chemiluminescence (CL) detection, electrochemiluminescence (ECL) detection, nanoparticle-based detection, mass spectrometry detection, and Raman spectroscopy detection. Colorimetric detection is one of the most widely used techniques in μPAD platforms nowadays and is defined by the passive movement of 2
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(As3+, Nd3+, Br−, Mn2+, Cr3+, F−, Cu2+, Pb2+ and Zn2+), neodymium (Nd), soil-transmitted helminth (STH), and tetrabromobisphenol A [88–113].
the analyte solution to test zones by capillary action followed by a reaction process with precisely loaded reagents to prompt a quantifiable color change [80]. The colorimetric images are generally acquired by a scanner, smartphone camera, or digital/CMOS camera, and are then transferred to a PC or cell phone for subsequent analysis. The detection limit for such methods is generally of the order of a few ppm (or the same level unit). Fluorescence/luminescent detection methods [81] exploit the interaction between the target molecules and a fluorescent dye, which results in a measurable electrical signal under illumination by a light source with a specific wavelength. Fluorescence/luminescence detection methods can easily meet these requirements, so fluorescence-based sensors appear to be one of the most promising candidates for chemical sensing. Due to its unique advantages in sensitivity and selectivity, this technology is widely used for the identification of cations and anions, response time and on-site monitoring. The detection limit for such methods is usually of the order of ppb (or the same level unit). Electrochemical techniques for μPAD platforms include cyclic voltammetry, amperometry, coulometry, and potentiometry. Electrochemical methods [82] involve the use of microelectrodes, convective mass transfer, surface-modified electrodes, flow injection, signal amplification, ion-selective electrodes, and ion-exchange membranes. The detection limit for such methods is typically around a few fM (or the same level unit). Chemiluminescence methods [83], which measure the light intensity generated from a chemical reaction, have gained significant attention as a detection technique for μPADs in recent years due to their inexpensive reagents and high signal-to-noise ratio, which makes possible detection limits of a few ppm (or the same level unit). Electrochemiluminescence is a derivative of the CL process [84], in which the signal is generated by an electrochemical reaction rather than a pure chemical reaction. Compared to CL-based detection, wherein signal emission is initiated upon application of the relevant reagents, ECL-based detection has the practical advantage that temporally-controlled signal capture can be more readily achieved through user-timed potential application. Moreover, the detection limit is generally of the order of a few ppb (or the same level unit). Mass spectrometry detection, magnetic resonance sensors, Raman spectroscopy, and capacitive sensors have also begun to be applied in μPAD platforms nowadays [85,86]. Accordingly, the quantitative analysis of μPAD kits had been addressed in many fields such as diagnostic tests, environmental monitoring and food safety, etc. The idea of combining multiple methods in one μPAD is promising, because these methods can potentially complement each other and minimize draw backs of a single method. For example, Wu et al. [87] reported a threedimensional multi-layer paper-based device that combines a thin adhesive film and paper folding to enable automated and multiple ELISA for colorimetric and electrochemical quantification of troponin I. Those detections of limit is approximately a few ppb (or the same level unit). For a more detailed overview of the detection methods and the range of LOD concentrations of each method, please refer to the review article [1].
3.1.1. Explosive residue pollution [88–95] Wang et al. [89] developed an inkjet-printed silver nanoparticle (Ag NP) paper-based sensor combined with a Raman spectroscopic method for the detection of crystalline trinitrotoluene (TNT) crystals and residues in the open environment (see Fig. 1(a)). The proposed sensor was modified with p-aminobenzenethiol (PABT) in order to more efficiently collect the airborne TNT via a charge-transfer reaction and to enhance the Raman scattering effect. It was shown that the device achieved a sensitivity limit of 1.6 × 10−17 g/cm2 TNT and was capable of detecting the odors emitted from 1.4 ppm TNT in soil and 7.2, 2.9 and 5.7 ng/cm2 TNT on clothing, leather and envelopes, respectively, within 2 s. Ryan et al. [90] presented a paper-based platform for the trace analysis of TNT in soil samples using an electrochemical probe consisting of graphite electrodes, filter paper, and ethylene glycol and choline chloride as the solvent/electrolyte. The sensitivity and detection limit of the probe were shown to be 0.75 nA/ng and 100 ng, respectively. Ueland et al. [91] used a wax-printing technique to realize a capillary-driven μPAD for the lab-on-chip (LoC) screening of explosive residues in soil. The experimental results showed that the device achieved a TNT detection limit of 1.4 ∼ 5.6 ng with a recovery rate ranging from 12 ∼ 40%. Shriver-Lake et al. [94] developed a paper-based probe for the electrochemical determination of chlorate using screen-printed carbon electrodes impregnated with vanadium-containing polyoxometalate anions (see Fig. 1(b)). In the proposed device, filter paper embedded with catalyst was cut into small strips and placed on the surface of commercial screen-printed electrodes. A small quantity of buffer solution was then added to render the electrode electrochemically active. The device showed a linear cyclic voltammetry current response over the chlorate concentration range of 0.156 ∼ 1.25 mg/mL and achieved a limit of detection (LOD) of 0.083 mg/mL. Table 1 briefly summarizes several other μPADs reported in the recent literature for explosive residue in soil pollution analysis. 3.1.2. Heavy metal pollution [96–101] Xiao et al [96] developed an enhanced 3D paper-based biosensing device for Ag+ detection, which uses a personal glucose meter with high sensitivity and portability. In the proposed device, the 3D origami μPADs integrated a piece of reagent-loaded nanoporous membrane. The membrane combined analyte-triggered self-growth of silver nanoparticles to block membrane pores in situ and perform signal amplification efficiently with a handheld personal glucose meter. This developed device can detect the Ag+ concentration of real water examples, i.e., tap water, drinking water, pond water and soil water. The LOD was found to be 58.1 pM. Nam and An [98] proposed a paper-disc device that includes the growth zone of soil algae Chlorococcum infusionum, chlorophyll fluorescence and photosynthetic activity, which exposure to copper treated soil. The study showed that the paper-disc device method is an effective, user-friendly method for assessing the metal toxicity of copper (Cu) and nickel (Ni) to soil algae. Chlorophyll fluorescence and photosynthetic activity decreased with increasing concentrations of Cu+2 or Ni+2 contaminated soil. The algal growth zone was visually analyzed and showed similar results to chlorophyll fluorescence. Sutariya et al. [99] developed a paper-based sensor device based on a single-step fluorescence consisting of a pyrene group connected to calix [4]arene as a fluorescent unit (TDPC) for the analysis of Nd3+ industrial soil sample and As3+ and Br- of industrial wastewater. In the proposed device, the paper-based sensor device comprises a luminescence sensing probe (CHEF-PET fluorescent probe) embedded in a cellulose matrix, wherein the resonance energy transfer appears to be a sensing mechanism, which is highly selective and sensitive for As3+,
3. Environmental pollution analysis and applications 3.1. Soil analysis Soil is the basic unit of the environment and is a valuable natural resource on which the entire world depends. However, large-scale industrialization and urbanization has resulted in significant soil pollution in many regions of the world. This pollution not only seriously degrades the soil fertility, but also impairs the capacity of the soil to retain nutrients and water. For the effects on these human bodies, please refer to Supplementary Material Table S1. Consequently, many μPAD platforms have been proposed for the analysis of common soil pollutants, including phosphate, chlorate, explosive residues, ammonia, copper (Cu), nickel (Ni), acid volatile sulfides (AVS), heavy metals 3
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Fig. 1. (a) Working principle of AgNP paper-based device to detect odor from TNT crystals using Raman spectra detection. (Reprinted from Ref. [89] with permission of American Chemical Society.) (b) Analysis method of paper-based electrochemical device for chlorate detection. (Reprinted from Ref. [94] with permission of MPDI (open access).) (c) Schematic illustration of paper-based spray ionization-MS device and calibration curve with isotopic internal standard for TBBPA analysis. (Reprinted from Ref. [108] with permission of Elsevier.).
Nd3+ and Br−. The results showed that the proposed system achieved detection limit of 11.53 nM, 0.65 nM and 11.25 nM for As3+, Nd3+ and Br−, respectively. The same group [100,101] also further performed a TAAC probe with a fluorescent paper-based device to enhance the analytical performance of fluorescent colorimetric detection. In soil, serum and industrial water samples, LOD can be enhanced to 0.88 nM for La3+, 0.19 nM for Cu2+, 0.15 nM for Br−, 11 nM for Mn2+, 4 nM for Cr3+ and 19 nM for F−. Table 1 briefly summarizes several other μPADs reported in the recent literature for heavy metal in soil pollution analysis.
with an isotopic internal standard method (see Fig. 1(c)). In the proposed device, soil and sediment extracts, spiked with 13C12 TBBPA (Ring-13C12), were loaded and separated on chromatographic paper and then sprayed and ionized by a high negative voltage. The paper substrate was then analyzed by mass spectrometry without purification and chromatography separation processes. The device showed a linear range of 0.1–100 μg/L, a LOD of 0.039 μg/L and a relative standard deviation of 5.3%. Naik et al. [110] preaented a loop-mediated isothermal DNA amplification (LAMP) paper-based device that combines one-step assay and thermal lysis to detect E. coli and M. smegmatis cells. The device combines thermal lysis and LAMP into a single reaction step on a paperbased device without any intermediate intervention and uses fluorescence from the DNA-binding dye PicoGreen to detect amplicons. The results showed that 100 CFU/mL of E. coli and M. smegmatis DNA amplification can be completed in 30 min. Similary, the authors in [111,112] used paper-based devices to detect E. coli in dust/soil or algae particle samples. Table 1 briefly summarizes several other μPADs reported in the recent literature for soil pollution analysis.
3.1.3. Other pollution [102–113] Wang et al. [105] presented a quantitative paper-based DNA reader (qPDR) for quantifying soil-transmitted helminth (STH) at the molecular level using “distance” as the readout. Since dsDNA depends on the concentration, the migration distance of SG-1 in the test region can be quantitatively determined by the concentration of dsDNA, so that dsDNA can be quantified by simply reading the migration distance of SG-1 in qPDR. The device exploited the unique interfacial interaction of SYBR Green I (a DNA intercalating dye) with the native cellulose matrix of chromatographic paper and performed polymerase chain reactions using a smartphone-controlled portable thermal cycler to detect minute amounts of genetic markers from adult worms expelled by STH-infected children. Liu et al. [108] developed a simple and rapid method for detecting tetrabromobisphenol A (TBBPA) in soils and sediments using a paper-based spray ionization mass spectrometry technique combined
3.2. Air analysis Air pollution has serious and wide-ranging effects on human health and the environment (See Supplementary Material Table S1). Air pollutants typically include solid particles, liquid droplets, or gases, and may be of either natural origin or manmade. Many μPADs have been 4
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Table 1 Summarizes of the μPADs developed for the determination of contamination in environmental analysis. Ref. and First author
years
Materials & structures
Fabrication methods
Detection methods
Target & (Sample matrices)
Detection limit
[91] Ueland
2016
Wax printing
Fluorescence
2015
Wax ink
Colorimetric
[95] Moram
2018
Soaking
SERS
Explosive residues (soil) Explosive residues (soil) Explosive residues
1.4 ng
[93] Peters
Filter paper, 2-D Chromatography paper, 2D Filter paper, 2-D Filter paper, 2-D Filter paper, 3-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Chromatography paper, 2D Chromatography paper, 2D Filter paper, 2-D Filter paper, 2-D Bare paper 2-D Photo paper 2-D Filter paper, 2-D N/R 2-D N/R
[99] Sutariya
2019
[103] Jayawardane
2014
[104] Jayawardane
2015
[106] Pellegrini
2018
[109] Basuri
2019
[113] Suaifan
2019
[115] Tang
2018
[118] Kuretake
2017
[119] Motooka
2018
[122] Alkasir
2015
[123] Colozz
2019
[127] Maity
2019
[129] Quddious
2016
[130] Petruci
2015
[131] Zhang
2015
[132] Kan
2019
[133] Sitanurak
2018
[138] Rattanarat
2014
[153] Yang
2016
[155] Nouanthavong
2016
[156] Ding
2016
[160] Wu
2017
[162] Ayazi
2018
[164] Mohammadi
2017
[166] Apilux
2015
[169] Evard
Wax printing Inkjet printing
Colorimetric (fluorescence) Colorimetric
Inkjet printing
Colorimetric
Cutting
Colorimetric
Cutting
SHPPSI MS
Wax printing
Colorimetric
N/R
Colorimetric
Cutting
Electrochemical
Screen- printing
Electrochemical
Inkjet printing
Colorimetric
Screen- printing
Electrochemical
Dip coating
Electrochemical
Inkjet printing
Electrochemical
Cutting
Fluorescence
Pencil-trace printing Spray-coated
Electrochemical
Filter paper, 2-D Filter paper, 2-D
N/R
Colorimetric
Wax printing
Colorimetric, Electrochemical
Filter 2-D Filter 2-D Filter 3-D Filter 2-D Filter 2-D
paper,
Inkjet printing
Electrochemical
paper,
Screen- printing
Colorimetric
paper,
Wax printing
Electrochemical
paper,
Inkjet printing
Colorimetric
paper,
Immersed
USA-TFME-GC-FID method
Filter paper, 2-D Filter paper, 3-D
Wax printing
Colorimetric
Punching
Colorimetric
2015
Filter paper, 2-D
Cutting
MS
[170] Lee
2018 2019
Cutting, calendering Dip-coating
SERS
[171] Zhang
Filter paper, 2-D Filter paper, 2-D
Electrochemical
3+
3+
As , Nd , Br (soil) Reactive phosphate (soil) Ammonia (sewage and soil water) Acid volatile sulfides (soil) Melamine (mike, soil) S. chartarum (soil) Methyl isothiocyanate (air) Ethanol (air) Ethanol (air) Bisphenol A (air) Sulfur mustard (air) NH3 (air) H2S gas (air) H2S gas (air) NO2 gas (air) NO2 gas (air) Hypochlorite (air) Cr, Cd and Pb (air) Trichlorfon (pesticide) Methyl- paraoxon, chlorpyrifos-oxon (pesticide) Methyl- parathion (pesticide) Paraoxon, trichlorfon (pesticide) Fenthion, chlorpyrifos, fenithrothion, phosalone, edifenphos, ethion (pesticide) -
Methiocarb (pesticide) Carbofuran, dichlorvos, carbaryl, paraoxon, pirimicarb (pesticide), Thiabendazole, aldicarb, imazalil, methomyl and methiocarb (pesticides) Thiram, ferbam (pesticide) Melamine, Thiram (pesticide)
SERS
0.39 μg 1.82 ng 11.53 nM, 0.65 nM, 11.25 nM 0.05 mg/L 0.8 mg N/L 0.1 μmoles/g 1.2 ppt (10 pM) 10 spores/mL 100 ppb 50 ppm 15 ppm 0.28 μg/g 0.019 g·min/m3 1 ppm 5 ppm 2 ppb 4.8 ppb 1 ppm 2 g Cl2/L 0.12 μg 0.25 ng 0. 89 μmol/L 8 ng/mL, 5.3 ng/mL 0.06 nM 0.01 ng/mL, 0.04 ng/mL 0.05 ng/mL, 0.05 ng/mL, 0.1 ng/mL, 0.3 ng/mL, 0.05 ng/mL, 0.3 ng/mL 5 ng/mL 0.003 ppm, 0.3 ppm, 0.5 ppm, 0.6 ppm, 0.6 ppm 5 mg/kg 0.46 nM, 0.49 nM 1 ppm
(continued on next page)
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Table 1 (continued) Ref. and First author
years
Materials & structures
Fabrication methods
Detection methods
Target & (Sample matrices)
Detection limit
[177] Jafry
2019
Filter paper, 2-D
Jet printing
Colorimetric
Methyl- paraoxon (pesticide)
10 μM
AChE: Acetylcholinesterase; MS: Mass spectrometry; N/R: No report; SERS: Surface-enhanced Raman scattering; SHPPSI MS: superhydrophobic preconcentration paper spray ionization mass spectrometry; USA-TFME-GC-FID method: ultrasound assisted thin film microextraction gas chromatography-flame ionization detection.
developed in recent years for the analysis of air pollution or air properties [114–148]. Typically, these devices are aimed at the detection of organic conpunds (volatile organic compounds (VOCs), ethylene (C2H4), bisphenol A (BPA), methyl isothiocyanate (MITC), ethanol vapor (C2H6O), sulfur mustard), inorginaic conpunds (ammonia gas (NH3), hydrogen sulfide (H2S), hypochlorite (ClO−), nitrogen dioxide (NO2),), and other substances (metal, oxygen (O2), humidity, pressure).
470 nm for the determination of hydrogen sulfide (H2S) in air (see Fig. 3(a)). The response time of the device was shown to be less than 60 s with a LOD of around 3 ppb. Kan et al. [132] developed a PbS nanowires paper-based sensor device for room-temperature NO2 gas detection. In the proposed device, PbS nanowires were spray coating onto apaper-based substrate at room temperature to enhance the sensitivity and flexibility of the gas sensor, because the PbS nanowires-on-paper sensor exhibits a porous network microstructure. The response of the paper-based sensor to 50 ppm of NO2 gas was 17.5 at room temperature, with the response and recovery time being 3 and 148 s, respectively. The device exhibited a linear response for NO2 concentrations in the range of 1–50 ppm with a detection limit of 1 ppm. Dhummakupt et al. [134] proposed a paper-based spray ionization device for the analysis of trimethyl phosphate, dimethyl methylphosphonate, and diisopropyl methylphosphonate collected on glass filter paper. In the detection process, a disposable cartridge containing a fiber filter is mounted on a specially designed 3D printing holder that effectively and reproducibly captures the aerosol onto the paper spray substrate. The device was capable of detecting aerosol concentrations as low as 1 × 10-6 mg/m3 and allowed for improved direct aerosol capture efficiency greater than 40%.
3.2.1. Organic compounds pollution [114–123] Soga et al. [114] developed a paper-based colorimetric sensor array for the detection of chemical compounds. The device was fabricated on standard copy paper using an inkjet printing technique and was patterned with dye encapsulated with polymer nanoparticles with different polarities to detect volatile primary amine (see Fig. 2(a)). It was shown that under the designed measurement conditions, the device achieved a high discrimination ability and good reproducibility for amine concentrations as low as 50 ppm. Tang and Sun [115] have developed a highly sensitive paper-based colorimetric sensor device for the detection of trace amounts of methyl isothiocyanate (MITC) in the air. The MITC paper-based sensor is based on detoxification reaction of glutathione (GSH) that binds to electrophilic toxicants during toxicantsduring under metabolic conditions and becomes unique when directly sensing the concentration of MITC. The LOD was found to be 100 ppb. Chen et al. [116] developed a paper-based sensor for the detection of volatile gases in air by means of an integrated optical and electronic sensor array patterned on the substrate surface through the direct handwriting of sensing materials (see Fig. 2(b)). The sensor was tested in ambient air for various volatile gases, including methanol, ammonia, toluene, acetone and ethanol. For each analyte, classification and detection were performed using a support-vector machine (SVM) technique. The results showed that the combined optical and electrical response provided a better discriminative power than that achieved using either sensing method alone. The authors in [117–120] used a paperbased cantilever array sensor and paper-based enzymatic biosensor, respectively, to detect volatile organic compounds (VOCs) and ethanol (breath analysis). Luo et al. [121] presented a paper-based plasma-assisted cataluminescence (PA-CTL) sensor for ethylene detection incorporating a substrate embedded with 0.320 wt% Mn-doped SiO2 nanomaterials (see Fig. 2(c)). The device showed a linear response in the range of 33∼6667 ppm and achieved a limit of detection of 10 ppm. Table 1 briefly summarizes several other μPADs reported in the recent literature for organic compounds in air pollution analysis.
3.2.3. Other substances analysis [135–148] Sun et al. [135] developed a paper-based microfluidic device for the on-site multiaxial quantification of airborne trace metals using an unmanned aerial vehicle (UAV) for sampling purposes and an integrated colorimetric detection method implemented on a smartphone (see Fig. 3(b)). The experimental results showed that the proposed system achieved limits of detection of 1.86 × 102, 45.84, 80.40, 8.16, 10.08 and1.52 × 102 ng for six metals commonly found in airborne PMs, namely Fe, Cu, Ni, Co, Mn, and Cr respectively. The same group [136] further integrated graphene oxide (GO) with a paper-based device to enhance the analytical performance of colorimetric detection. The LODs can be enhanced to 16.6, 5.1, and 9.9 ng for Fe, Cu, and Ni, respectively. The authors in [137,138] used μPAD-coated AgNPs aggregation and multilayer paper-based device for colorimetric and electrochemical quantification, respectively, to detect particulate matter (PM) pollution and six metals (Cd, Pb, Fe, Cu, Ni, and Cr) in air sample. A special paper-based device is used to detect ATP from airborne bacteria developed by Nguyen et al. [139]. The paper-based device can detect ATP extracted from purified E. coli as low as 1.17 × 103 CFU/mL. Gimenez et al. [140] developed a simple paper-based oxygen sensor consisting of a film of ZnO crystals dispersed over the paper surface. It was shown that when the device was illuminated by UV light, the current passing through the sensor underwent a small change under the effects of oxygen desorption. Moreover, the magnitude of this change was proportional to the concentration of oxygen adjacent to the sensor surface. The device was capable of detecting oxygen concentrations as low as 27.6 g/m3 even under low humidity conditions of 40% relative humidity (RH). Zhao et al. [142] presented a carbon-based humidity sensor in which the electrodes were written on the paper substrate by commercial pencils and the sensitive layer was drawn with oxidized multi-walled carbon nanotubes (o-MWCNTs) ink marker (see Fig. 3(c)). The response curve exhibited a high slope (0.41) and good linearity (R2 = 0.9976) in the 33∼95% RH range. The authors in [143,144]
3.2.2. Inorganic compounds pollution [124–134] Huang et al. [124] fabricated a paper-based sensor for the detection of ammonia gas (NH3) using silver and poly(m-aminobenzene sulphonic acid) functionalized single-walled carbon nanotubes (SWNT-PABS) deposited on photopaper using an inkjet printer. The sensor showed an excellent response, a short recovery time under NH3 concentrations at the ppm level, and good stability for at least several months. The authors in [125–127] used SWNTs and perovskite halide CH3NH3PbI3 (MAPI) deposited on paper to detect the presence of toxic NH3 gas. Petruci and Cardoso [128] developed a detection system incorporating a paper substrate infused with fluorescein mercury acetate (FMA), a light emitting diode (LED), and a spectrometer with a wavelength of 6
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Fig. 2. (a) Analysis principle of paper-based color sensor system and colorimetry results for principal component analysis. (Reprinted from Ref. [114] with permission of American Chemical Society.) (b) Schematic illustration of paper-based optoelectronic sensor (paper-nose) with colorimetric (optical) and chemiresistive (electronic) sensor array platform. (Reprinted from Ref. [116] with permission of Elsevier.) (c) Schematic illustration of paper-based PA-CTL system for ethylene detection. (Reprinted from Ref. [121] with permission of Elsevier.).
fabricated paper-based humidity sensors consisting of conductive molybdenum carbide–graphene (MCG) composites and polymers poly(3,4ethylenedioxythiophene)-poly(styrene sulfonate) (PEDOT:PSS) deposited on paper substrates, respectively. Zang et al. [147] developed a paper-based sensor for ambient pressure determination incorporating a conducting polymer (CP)-coated paper substrate. The experimental results showed that the sensor achieved a LOD as low as 0.3 Pa and a sensitivity of 2 kPa−1 (P ≤ 75 Pa). Table 1 briefly summarizes several other μPADs reported in the recent literature for air pollution analysis.
animal pests. However, runoff can carry pesticides into aquatic environments, while wind can carry them to other fields, grazing areas, human settlements and undeveloped areas. Moreover, pesticides easily enter the human body through the inhalation of aerosols, dust and vapor; oral exposure by consuming contaminated food or water; and skin exposure by direct contact. As such, pesticides have wide-ranging adverse effects on both the environment and human health (See Supplementary Material Table S1). Accordingly, many μPAD platforms have been proposed for the analysis of pesticides in recent years [149–176], including insecticides (dichlorvos (DDV), trichlorfon, methiocarb, methyl parathion, carbaryl, nitenpyram, chlorpyrifos, methomyl, profenofos, chlorpyrifos, aldicarb), fungicides (thiram, thiabendazole, ferbam, carbamate, imazalil), and others (melamine,
3.3. Ecology analysis ― pesticide Pesticides are widely used throughout agriculture to kill fungal or 7
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Fig. 3. (a) Schematic illustration of paper-based sensing platform for H2S detection and sample concentration measurement using LED excitation and microfiber USB spectrometer. (Reprinted from Ref. [128] with permission of American Chemical Society.) (b) Integrated paper-based colorimetric detection and UAV for quantification of metals in airborne particulate matter. (Reprinted from Ref. [135] with permission of Elsevier.) (c) Paper-based chip based on o-MWCNTs for electrochemical detection of humidity and dynamic response of sensor. (Reprinted from Ref. [142] with permission of American Chemical Society.).
dimethyl methylphosphonate, indole-3-acetic acid (IAA), salicylic acid (SA))
tetraphenylethylene (TPE) and the addition reaction capability of maleimide for the rapid naked-eye detection of AchE activity and Ops (see Fig. 4(b)). The LODs for AchE and Ops were found to be 2.5 mU/ mL and 0.5 ng/mL, respectively. The authors in [158,159] similarly used paper-based devices to detect AchE activity and cholinesterase activity in human blood. For the CMs type, Zhang et al. [163] presented a molecularly imprinted polymers (MIPs) paper-based biomimetic enzyme-linked immunosorbent assay (BELISA) device for the detection of carbaryl. In the proposed device, the surface of the paper substrate was first modified with γ-MAPS by hydrolytic action and the MIP layer was then anchored on the modified surface by copolymerization. The device showed a linear response (R2 = 0.99) over the concentration range of 0.001∼1 mg/L. Moreover, the LODs of the half-inhibitory concentration (IC50) and IC15 were 0.116 mg/L and 0.007 mg/L, respectively. Wang et al. [165] developed a highly-sensitive SERS platform incorporating a silver dendrites-decorated superhydrophobic paper-based device and a Raman measurement system for the detection of nitenpyram pesticide (see Fig. 5(a)). It was shown that the layered fernlike silver dendrites (F-AgNDs) not only enhanced the hydrophobicity of the surface, but also improved the SERS detection performance. The LOD and enhancement factor were found to be 1 nM and 3.4 × 107, respectively. Table 1 summarizes several other μPADs reported in the recent literature for insecticide analysis.
3.3.1. Insecticide pollution [149–157] In the insecticide pollution, the literature can be divided into two categories, using the μPAD platform for detection, namely organophosphorus (Ops) and carbamates (CMs). For the Ops type, Liu et al. [149,150] developed a paper-based CL analytical device combined with paper chromatography to determine the concentration of DDV in vegetables. The device used a mixed solution of luminol and H2O2 to produce CL and exhibited a linear response for DDV concentrations in the range of 3.0 ng/mL to 1.0 μg/mL with a detection limit of 0.8 ng/ mL. Apilux et al. [152] presented a thioglycolic acid (TGA)-capped CdTe QD paper-based device based on fluorescence conversion for the detection of DDV, pirimicarb and carbaryl. The detection zone was impregnated with acetylcholinesterase (AchE) and choline oxidase (ChOx) enzymes and was coated with TGA-capped CdTe quantum dots (QDs). It was shown that in the assay process, the bi-enzyme reaction induced by the presence of insecticide caused a reduction of H2O2 and led to a quantifiable change in the fluorescence intensity of the TGAcapped CdTe QDs under black light. The LOD was found to be 0.01, 0.05 and 0.01 ppm for DDV, pirimicarb and carbaryl, respectively. Several μPAD platforms have been proposed for the detection of complex organophosphorus (Ops) compounds in environmental samples and AchE activity and Ops in human serum samples [153–162]. For example, Kim et al. [154] presented a multilayered paper-based device for the detection of chlorpyrifos pesticide (OP-type) using a colorimetric method (see Fig. 4(a)). The device comprised three paper layers for sample injection, reagent storage, and reaction / color development, respectively. In the detection process, the sample solution was dripped onto the paper-based device and subsequently underwent mixing with two deposited reagents (AchE and indoxyl acetate (IDA)) to produce a blue image in the reaction zone. The LOD was found to be 8.60 ppm. Chang et al. [157] proposed a paper-based fluorescent sensor based on the aggregation-induced emission effect of
3.3.2. Fungicide pollution [168–173] Fungicides are biocidal compounds or biological organisms used to kill parasitic fungi or spores thereof. Fungicides can be used in both agricultural and fungal infections against animals. Ma et al. [168] proposed an on-site detection system for thiram, thiabendazole and methyl parathion pesticides comprising a surface-enhanced Raman scattering (SERS) paper substrate patterned with graphene oxide (GO) and Ag NPs. The device showed an excellent SERS activity and was capable of extracting thiram, thiabendazole and methyl parathion residues in fruits and vegetables with LODs of 0.26 ng/cm2, 28 ng/cm2 8
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Fig. 4. (a) Schematic illustration of colorimetric paper-based sensor device and procedure for pesticide analysis using competitive-inhibiting reaction. (Reprinted from Ref. [154] with permission of Springer.) (b) Analysis principle and observation results for fluorescent paper-based assay for AChE activity in presence of diazinon with different concentrations. (Reprinted from Ref. [157] with permission of Elsevier.).
and 7.4 ng/cm2, respectively. Lee et al. [170] also developed a paperbased SERS device that can detect pesticides of the fungicide type by hydrophobically modifying the filter paper with high sensitivity and repeatability. The filter paper is subjected to a hydrophobic treatment of the alkyl ketene dimer to prevent the paper from absorbing AgNP and the sample solution. Unlike conventional filter papers, hydrophobically modified filter paper produces more SERS hot spots composed of AgNP clusters on the paper surface for more sensitive detection of pesticides. Fungicides such as thiram and ferbam can be detected at the nanomolar level using the proposed device and found to have an LOD of 0.46 nM and 0.49 nM, respectively. Identically, Deng et al. [172] also presented a paper-based SERS device for detection of malachite green residues in fish. The surface-enhanced Raman scattering signal intensity has a good linear relationship with the malachite green concentration between 1 × 10−7 and 1 × 10-5 mol/L, and LOD was be founded to 5 × 10-10 mol / L. Table 1 summarizes several other μPADs reported in the recent literature for fungicide analysis.
butyrylcholinesterase (BchE) enzyme activity towards butyrylthiocholine with and without exposure to nerve agent, respectively, and enabled an entirely reagent-free analysis. The sensitivity of the device was enhanced through the use of carbon black/Prussian blue nanocomposites as working electrodes. In a series of tests performed using paraoxon as a nerve agent simulant, the device exhibited a linear detection performance down to 3 μg/L. Lee et al. [176] developed a foldable paper-based device for detecting dimethyl methylphosphonate (DMMP) in a semi-quantitative manner using a colorimetric technique (see Fig. 5(b)). In the proposed device, the color of the paper channel changed to yellow in the presence of DMMP as a result of the hydrogen peroxide produced from the enzymatic reactions and the DMMP concentration was then quantified using an angle-based readout. A linear angle response was observed for DMMP concentrations in the range of 1 ∼ 4 M. Table 1 summarizes several other μPADs reported in the recent literature for pesticide analysis. 3.4. River water analysis
3.3.3. Other pollution [174–177] Cinti et al. [174] developed an integrated paper-based screenprinted electrochemical biosensor for the detection of nerve agents. The device was based on the double electrochemical measurement of
Water pollution is a major global concern nowadays and is observed in many water bodies, including rivers, oceans, lakes and aquifers. Water contamination is usually the result of human activities, and 9
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Fig. 5. (a) Photograph of fabrication process for flexible SERS substrate based on silver dendrites-decorated filter paper for nitenpyram detection and SERS spectra result. (Reprinted from Ref. [165] with permission of Elsevier.) (b) Schematic illustration of fabrication process for paper-based SERS swabs and detection principle for pesticide residues. (Reprinted from Ref. [176] with permission of Elsevier.).
varied in direct proportion to the concentration of Cu2+ ions in the sample. The experimental results showed that the device achieved a LOD of 0.96 ppm (15 μM). Liu et al. [195] developed a paper-based analytical device for the image-based colorimetric detection of Cu2+, in which an on-line reaction between polyethyleneimine (PEI) and Cu2+ was induced within a T-type microfluidic channel under the application of an external electric driving field. The device achieved a linear response (R2 = 0.991) over a Cu2+ concentration range of 0.1∼1.0 mM with a LOD equal to 30 μM. Chen et al. [197] presented a colorimetric paper-based analytical platform based on AuNPs and a smartphone for water source Hg2+ detection (see Fig. 7(a)). The presence of Hg2+ ions induced the aggregation of the AuNPs via thymine–Hg2+–thymine (T–Hg2+–T) coordination chemistry. The resulting color change of the reaction zone was imaged and analyzed by the smartphone. The experimental results obtained for spiked pond and river water samples showed that the device was capable of performing Hg2+ detection down to 50 nM. Faham et al. [202] used AuNPs modified with 2,2′-thiodiacetic acid (TDA) to determine the concentrations of Cr3+ and Cr6+ ions using a paper-based device coupled with UV–vis spectrophotometry, dynamic light scattering, energy dispersive spectroscopy and transmission electron microscopy (see Fig. 7(b)). The device was used to determine the concentration of chromium ions in spiked water, urine and human plasma, and was found to have a good linear correlation (R2 = 0.98) over the concentration range of 1.0 nM to 0.1 mM and a LOD equal to 0.64 nM (0.033 ppb). Asano and Shiraishi [205] proposed a μPAD for the colorimetric detection of iron in water samples using phenanthroline indicator. Briefly, a hydrophobic surface was produced via immersion in octadecyltrichlorodecane (OTS)-n-hexane and the surface was then exposed to UV light through a photomask to produce a hydrophilic region. The visible color change induced in the reaction zone following the introduction of the sample solution was captured by a high-resolution camera and used to determine the corresponding iron concentration. The LOD and limit of quantitation (LOQ) were found to be 3.96 and 13.8 mM, respectively. Li et al. [208] developed a colorimetric paperbased membrane sensor for the determination of Ni2+ ions using zincon organometallic reagent combined with hollow ZnSiO3 nanospheres as a mixed ionophore (see Fig. 7(c)). In the presence of Ni2+, the
includes a wide range of chemicals and pathogens. Water pollution is the leading cause of death and disease worldwide (See Supplementary Material Table S1), and hence many μPAD platforms for detecting water contaminants have been proposed. These devices are generally intended for the analysis of river water [178–232] and typically target analytes such as heavy metals (mercury (Hg2+), lead (Pb2+), cobalt (Co2+), zinc (Zn2+), chromium (Cr6+, Cr3+), iron (Fe3+), copper (Cu2+), nickel (Ni2+), cadmium (Cd2+), silver (Ag+), manganum (Mn2+), calcium (Ca2+), magnesium (Mg2+)), non-metal ions (nitrite, arsenic (As), chloride (Cl−), bromide (Br−), iodide (I−), sulfide (S2−), and organic contaminants and microorganisms (pesticides, cyanide, ethinylestradiol, phosphate, dipicolinic acid, hydrogel, trinitrophenol, bacterial). 3.4.1. Heavy metal ion pollution [183–212] Vijitvarasan et al. [183] developed a paper-based scanometric colorimetric sensing assay that coupled enzyme probes (PE), magnetic beads (MB), substrate probes (PS) and gold nanoparticles (AuNPs) to perform the detection of Pb2+. As shown in Fig. 6(a), the AuNPs-PS were spotted on a paper substrate and the signal induced in the presence of a magnetic field was then amplified by a silver nitrate enhancer solution. The device exhibited a linear response over the range of 0.1∼1000 nM and a LOD of 0.3 nM. The literature contains several other DNAzyme-based methods for detecting metal ions using colorimetric or ELC techniques [184,185], label-free fluorescence assays [186,187], or aptamer-based assays [188], Zhang et al. [190] presented a label-free oligonucleotide sequences-AuNPs paper device for the colorimetric sensing of Ag+. Label-free oligonucleotide sequences (S1) were attached to unmodified AuNPs by cytosine–Ag+–cytosine (C–Ag+–C) coordination chemistry; giving rise to an OR function. A logic gate was then constructed using S1 and Ag+ as inputs to the S2attached AuNP mixture. The detection limit of the proposed device was shown to be as low as 10 nM. Sadollahkhani et al. [192] proposed a ZnO@ZnS core-shell nanoparticle paper-based sensor for the detection of Cu2+ ions in aqueous solutions (see Fig. 6(b)). The difference in solubility between ZnS and CuS resulted in a cation exchange between the ZnS nanoparticle surface and the Cu2+ ions. The cation exchange prompted a color transformation of the test paper from colorless to yellow, where the intensity 10
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Fig. 6. (a) Schematic illustration of detection procedure for lead ions using paper-based scanometric assay device. (Reprinted from Ref. [183] with permission of Elsevier.) (b) Functional mechanism and colorimetric detection results for Cu2+ analysis using PAD sensor platform. (Reprinted from Ref. [192] with permission of American Chemical Society.).
competition with the Zn2+ ions resulted in a quantifiable fading of the blue color in the reaction zone. It was shown that the selectivity of the proposed device could be enhanced by using masking agent Na2-EDTA as a co-ionophore. The device exhibited a linear response over the range of 32 nM to 9.2 mM Ni2+ and achieved a LOD of 35.6 nM. Table 2 summarizes several other μPADs reported in the recent literature for heavy metal ion pollution analysis.
mL, respectively. Devi et al. [216] presented a detailed overview of the progress made in sensor materials for the optical detection of arsenic in water samples between 2013 and 2018. Cuartero et al. [217] developed an electrochemical PAD for halide ion detection in food supplements and water samples via cyclic voltammetry. As shown in Fig. 8(a), the device consisted of a cellulose paper substrate, a cation exchange Donnan exclusion membrane, and a silver-foil working electrode. Cyclic voltammetry was used to perform the sequential oxidation and plating of the halide at the silver electrode, and was followed by regeneration with an inverted potential. The feasibility of the proposed device was demonstrated by detecting Cl−, Br− and I− ions in concentrations ranging from 10−4.5 M to 0.6 M for Cl− and 10−4.8 M to 0.1 M for Br− and I−. It was shown that the device achieved a LOD of 10−5 M. Vasimalai et al. [219] developed a paperbased testing kit for the detection of S2– ions in water samples based on the quenching effect of S2– on 6-mercapto-s-triazolo(4,3-b)-s-tetrazingold nanodots (MT-AuNDs) (see Fig. 8(b)). The device showed a linear response over the range of 870 nM to 16 μM S2– and achieved a LOD of 2 nM. Table 2 summarizes some of the other μPADs reported in the recent literature for non-metal ion pollution analysis.
3.4.2. Other ion pollutants [213–219] Liu et al. [213] developed an Ag-based μPAD chemiresistor for the electrochemical detection of nitrite ions in river water. In the proposed device, the introduction of nitrite prompted a Griess reaction, and the resulting azo and sulphonamide products reacted with the Ag metal and Ag+ ions to cause a change in resistance of the response region. The sensor was shown to provide a linear response over two nitride concentration ranges of 10 nM to 5.0 μM and 10 μM to 3.2 mM, respectively, Moreover, the LOD was found to be 8.5 × 10−2 nM. Cardoso et al. [214] developed a μPAD platform combined with colorimetric detection and a modified Griess reaction for the determination of nitrite in clinical, food and river water samples. The reaction images were captured by a scanner, converted to a color scale, and then analyzed in the magenta channel. The device achieved a LOD of 5.6 μM and a sensitivity of 0.56 AU/mM. Pena-Pereira et al. [215] proposed an AgNO3-based paper device for arsenic (As) detection involving in situ arsine generation followed by transfer of volatiles to the headspace and a subsequent reaction with silver nitrate in the detection zone. Under optimal conditions, the LOD and LOQ were found to be 1.1 and 3.6 ng/
3.4.3. Organic contaminants and microorganism pollution [220–232] Arduini et al. [221] proposed a 3D origami paper-based device combining different enzyme-inhibition biosensors and office paper screen-printed electrodes (SPE) for the electrochemical detection of several types of pesticide in river water (see Fig. 9(a)). In the proposed device, the presence of pesticide was detected by monitoring the 11
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Fig. 7. (a) Photographs, functional mechanism and detection results obtained by μPAD treated with AuNPs for on-site Hg2+ assay. (Reprinted from Ref. [197] with permission of American Chemical Society.) (b) Mechanism and colorimetric detection results obtained by PAD sensor platform based on TDA-AuNPs for Cr3+ assay. (Reprinted from Ref. [202] with permission of Springer.) (c) Schematic illustration of Ni2+ ion analysis using colorimetric paper-based membrane sensor based on indicator displacement mechanism and corresponding colorimetric sensing results. (Reprinted from Ref. [208] with permission of Elsevier.).
(R2 = 0.917) for the river water samples. The LOD of the biosensor was found to be 2 ppb. The same group [222] also used a paper-based screen-printed electrochemical sensor to detect phosphate. Saraji and Bagheri [224] developed a paper-based headspace extraction device coupled with digital image processing for the detection of cyanide in mineral, tap, well, river, sea and wastewater samples (see Fig. 9(b)). In
enzymatic activity degree chrono-amperometrically in the absence and presence of pesticide, respectively, using a portable potentiostat. The device was tested using paraoxon, 2,4-dichlorophenoxyacetic acid and atrazine at ppb concentration levels in both standard solutions and river water samples. Two linear response ranges were observed, namely 2∼100 ppb (R2 = 0.907) for the control solutions and 10∼100 ppb 12
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Table 2 Summarizes of the μPADs developed for the determination of contamination in river water analysis and maximum contaminant level in drinking water. Ref. and First author
years
[184] Xu [185] Sun
2018 2018
[186] Li
2018
[187] Lin
2016
[188] Fakhri
2018
[189] Almeida
2012
[191] Dhavamani
2018
[193] Liu
2012
[194] Cui
2019
Materials & structures
Fabrication methods
Detection methods
Target 2+
Detection limit
MCL(mg/L)EPA
Chromatography paper, 3-D Art-paper, 2-D Filter paper, 2-D Filter paper, 2-D Filter paper, 2-D Chromatography paper, 2-D
Wax printing Microcontact printing
ECL Colorimetric
Pb Pb2+
0.5 nM 10 nM
0.015 0.015
Wax printing
Fluorescence
Pb2+
10 nM
0.015
N/R
ICP-MS
CO2 laser cutting
Colorimetric
Pb2+, Cd2+ Pb2+
0.69 mg/L, 0.51 mg/L 0.7 nM
0.015 0.005 0.015
N/R
SR-TXRF
paper,
Hand drawn
Colorimetric
6.8 μg/L, 4.4 μg/L, 3.9 μg/L, 3.8 μg/L, 3.9 μg/L, 9.1 μg/L, 10 μM
0.05 1.0 5.0 0.015
Filter 2-D Filter 2-D Filter 2-D Filter 2-D
Mn, Co, Ni, Cu, Zn, Pb Ag+
0.10
paper,
Cutting and soaking
Fluorescence
Cu2+
5 μM
1.0
paper,
Inkjet printing
Colorimetric
Cu2+
0.08 μM
1.0
Wax printing
Colorimetric
2+
Cutting and immersing
Fluorescence
4.8 mg/L, 1.6 mg/L 0.18 mg/L 0.14 nM
1.0 0.1
Filter paper, 2-D Filter paper, 2-D
Ni , Cu2+, Cr2+ Hg2+
Laser printer
Fluorescence
Cutting
Fluorescence
Hg2+, Pb2+, Cd2+, Fe3+, Cu2+ Cr6+
10 μM, 20 μM, 20 μM, 10 μM, 20 μM 0.24 μM
0.002 0.015 0.005 0.3 1.0 0.1
Wax printing Photo-lithography Wax and screen printing
CL Colorimetric Colorimetric
Cr3+ Cr6+ Ni2+, Cr6+, Hg2+ Cu, Fe, Zn
0.02 ppm 30 ppm 0.24 ppm, 0.18 ppm, 0.19 ppm 0.1 ppm
0.1 0.1 0.1 0.002
0.2 mM, 0.4mM 0.5 mM
0.3
[196] Sun
2018
paper,
[198] Anh
2017
[199] Abbasi-Moayed
2018
[200] Bu
2016
[201] Alahmad [203] Asano [204] Devad-hasan
2016 2018 2018
Filter paper, 2-D Chromatography paper, 2-D Chromatography paper, 2-D Chromatography paper, 2-D
[206] Hofstetter
2018
Chromatography paper, 2-D
Wax printing
Colorimetric
[207] Xu
2018
paper,
Laser printer and coating
Colorimetric
[209] Karita
2016
paper,
Wax printing
Colorimetric
[210] Ostad
2017
paper,
Hand drawn
Colorimetric
[212] Liu
2018
paper,
Immersed
Colorimetric
Fe3+, Ni2+ Ca2+, Mg2+ Ca, Mg Co2+
[218] Yakoh
2018
paper,
Wax printing
Colorimetric
Cl-
1.3 mg/L
[223] Petruci
2018
paper,
Wax printing
Colorimetric
HCN
10 ppb
[229] Rengaraj
2018
Filter 2-D Filter 2-D Filter 2-D Filter 2-D Filter 2-D Filter 2-D Filter 2-D
paper,
Screen printing
Electrochemical
Bacte- rial
1.9 × 103 CFU/mL
0.002
1.0 0.3 5
8.3 mg/L, 1.0 mg/L 10 mg/L 4.0
0
ECL: Electrochemiluminescence; ICP-MS: Inductively coupled plasma mass spectrometry; SR-TXRF: Synchrotron radiation-excited total reflection X-ray fluorescence; CL: Chemiluminescence; MCL: Maximum Contaminant Level in drinking water (National Primary Drinking Water Regulations, EPA).
the detection process, the cyanide was converted to cyanogen chloride via a chloramine-T/pyridine-barbituric acid reaction, and the cyanide concentration was then determined via an inspection of the resulting color change in the reaction region. A linear response was observed for cyanide concentrations in the range of 3.0 ∼ 100 μg/L. Moreover, the LOD was equal to 0.7 μg/L and the analyte recovery rate was 69 ∼ 111%. Scala-Benuzzi et al. [226,227] proposed an electrochemical paperbased immunocapture assay (EPIA) method for determining the concentration of ethinyl estradiol (EE2) in river water (see Fig. 9(c)). The EPIA method used paper microzones modified with silica nanoparticles
(SNs) and anti-EE2 specific antibodies to capture and pre-concentrate the EE2. The EE2 was then electrochemically detected by Osteryoung square wave voltammetry (OSWV), wherein the oxidation current was proportional to the EE2 concentration. The device response was found to vary linearly over the concentration range of 0.5 ∼ 120 ng/L with a LOD of 0.1 ng/L. Alcaine et al. [228] developed a phage amplification paper-based fluidic device combined with a colorimetric detection method for bacteria detection in river water samples. The device utilized bioengineered T7 phage strains to enhance the sensitivity of phage amplification-based lateral flow assays (LFA) by over 100-fold. The enhanced sensitivity enabled a LOD of 103 cfu/ml for E. coli after 7 h. 13
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Fig. 8. (a) (I) Schematic illustration of electrochemical cell with closing system on μPAD and corresponding voltammetric readout. (Reprinted from Ref. [217] with permission of American Chemical Society.) (b) Mechanism and fluorescence detection results for S2– using MTT-AuND-modified PAD sensor platform. (Reprinted from Ref. [219] with permission of American Chemical Society.).
look set to provide an invaluable contribution toward protecting and improving human and environmental health throughout the world for years to come. This article has provided a comprehensive review of the latest developments in μPAD technology in the environmental analysis and monitoring field. The review has focused particularly on the use of μPADs for the analysis of soil, air, pesticides, and river water. In general, the surveyed literature has confirmed that μPADs provide a cheap and practical alternative to the large-scale equipment used in traditional environmental monitoring applications. Many of the concepts and techniques adopted in the literature show significant potential for further development in the future. For example, μPADs combined with UAVs provide a promising approach for the detection of PM2.5 in the environment [128,129], and future monitoring of environmental sources is quite helpful. In addition, μPADs incorporating coated nanoparticles and graphene oxide (GO) also appear to have significant potential for the high-sensitivity, high-selectivity detection of pesticides, heavy metal ions, bacterial cells, allergens and toxins [129,157,233–242]. As a result, nanoparticles and GO seem likely to play a key role in enabling the development of sophisticated μPAD platforms in the future. Although μPAD technology has advanced rapidly in recent years, several key challenges still remain to be overcome. For example, the World Health Organization (WHO) and United States Environmental Protection Agency (US-EPA) have set permissible limits for Hg2+ in water (tap or drinking) of 0.001 and 0.002 ppm, respectively. However, existing colorimetric-based μPAD methods [168,175,243–246] achieve
Rong et al. [230] presented a ratiometric fluorescence paper-based device for anthrax biomarker detection based on ethylenediamine tetraacetic acid (EDTA) and Eu(III) ion functionalized manganese-doped carbon dots (FMn-CDs) (see Fig. 9(d)). It was shown that 2, 6-dipicolinic acid (DPA), an important biomarker of Bacillus anthracisspore, sensitized the Eu(III) combined on the FMn-CDs to produce bright red fluorescence under UV irradiation. The device exhibited a linear response over the range of 0.1–750 nM DPA and achieved a LOD of 0.1. Tawfik et al. [232] developed a paper-based sensor with a thiophene copolymer quantum dot (TCPQD)-doped chitosan film for determining the concentration of trace quantities of 2,4,6-trinitrophenol (TNP) explosive in tap water and river water samples using a fluorescence quenching technique. The LOD was found to be 2.29 pg TNP, while the recovery was 98.02∼107.50%. Table 2 briefly summarizes several other μPADs reported in the recent literature for the detection of organic contaminants and other microorganism pollutants. 4. Conclusions and outlook μPADs have attracted immense interest in recent decades for a wide variety of monitoring and analysis applications, including disease diagnosis, food safety, environmental monitoring, and others. μPADs are inexpensive, portable, highly sensitive, and straightforward to use. Consequently, they provide an ideal analysis tool for resource-constrained environments lacking highly-trained technicians and wellequipped laboratories. Future advances in μPAD technology, combined with a more extensive distribution and availability of μPAD devices, 14
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Fig. 9. (a) Schematic illustration of origami paper-based electrochemical biosensor for pesticide detection. (Reprinted from Ref. [221] with permission of Elsevier.) (b) Procedure, mechanism and analysis results for cyanide detection using colorimetric paper-based headspace extraction system. (Reprinted from Ref. [224] with permission of Elsevier.) (c) Schematic illustration of detection procedure for EE2 using electrochemical paper-based immunocapture assay device. (Reprinted from Ref. [226] with permission of American Chemical Society.) (d) Schematic illustration of colorimetric FMn-CD paper-based device for DPA detection using ratiometric fluorescence method. (Reprinted from Ref. [230] with permission of Elsevier.).
LODs of Hg2+ only of 0.002–10 ppm. In other words, the sensitivity of these methods is lower than the prescribed regulatory limit for drinking water. Nonetheless, paper-based fluorescent devices have many advantages, including high sensitivity, fluorescent probes providing a wide range of wavelengths, qualitative/quantitative analysis, dynamic wide linear range, and good repeatability. For example, QD fluorescence quenching, with a LOD limit in the range of 0.01 ∼ 10 μg/L (ppb) [81,153,199,247], appears to provide a possible solution for overcoming this problem, and thus merits further attention in future studies. Another problem to be addressed in the future is that of the detection system integrated with the μPAD. At present, many μPAD platforms use mass spectrometry to quantify the target analyte [127,248–250]. However, while mass spectrometry has the advantages of simplicity and reliability, the detection system is too large and expensive for in-situ monitoring and analysis. Therefore, the development of more portable and inexpensive detection systems also represents an important avenue of future μPAD research. At present, there are already μPAD related products for environmental pollution analysis in the world. For example, in the water quality testing, the home water test kit (Lamotte Co. USA; Bioeasy Biotechnology Co. China, et al.) has been introduced. Most of these rapid testing products are qualitative tests that quickly detect malachite green, Al, Cr, Fe, Cu and Cd in water. In the rapid detection of pesticides, there are also related μPAD products, such as rapid pesticide residue detection kits have also been developed (Neogen Co. USA; MRight Biomedical Co. Taiwan; Apex Biotechnology Co. Taiwan, etc.), most of which are used for insecticide analysis. Such insecticid, only Ops and CMs types, are also qualitative tests. In the rapid detection of
air and soil pollution, there are no commercially available μPAD products. Therefore, the application of μPAD in the rapid detection of environmental pollution is still worth developing, such as the development of various contaminated μPAD and the quantitative detection of μPAD platform. In conclusion, this review has distilled out the key concepts from the huge body of information available in the literature relating to μPAD platforms for environmental analysis and monitoring applications. μPAD technology has advanced dramatically over the past ten years or so and, provided that the challenges described above are overcome, appears to represent the analytical tool of choice for reliable and inexpensive environmental analysis into the foreseeable future. Acknowledgement This study was supported by the Ministry of Science and Technology of Taiwan (107-2622-B-006-007-CC2, 106-2221-E-006-253-MY3, and 106-2314-B-006-085-MY3). Appendix A. Supplementary data Supplementary material related to this article can be found, in the online version, at doi:https://doi.org/10.1016/j.snb.2019.126855. References [1] L.M. Fu, Y.N. Wang, Detection methods and applications of microfluidic paperbased analytical devices, Trends Anal. Chem. 107 (2018) 196–211.
15
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C.-T. Kung, et al. [2] W. He, M. You, W. Wan, F. Xu, F. Li, A. Li, Point-of-care periodontitis testing: biomarkers, current technologies, and perspectives, Trends Biotechnol. 36 (2018) 1127–1144. [3] A.W. Martinez, S.T. Phillips, M.J. Butte, G.M. Whitesides, Patterned paper as a platform for inexpensive, low-volume, portable, bioassays, Angew. Chem. Int. Ed. 46 (2007) 1318–1320. [4] J.R. Choi, K.W. Yong, R. Tang, Y. Gong, T. Wen, F. Li, B. Pingguan-Murphy, D. Bai, F. Xu, Advances and challenges of fully integrated paper-based point-of-care nucleic acid testing, Trends Anal. Chem. 93 (2017) 37–50. [5] Z. Li, H. Liu, X. He, F. Xu, F. Li, Pen-on-paper strategies for point-of-care testing of human health, Trends Anal. Chem. 108 (2018) 50–64. [6] P. Teengam, W. Siangproh, A. Tuantranont, T. Vilaivan, O. Chailapakul, C.S. Henry, Electrochemical impedance-based DNA sensor using pyrrolidinyl peptide nucleic acids for tuberculosis detection, Anal. Chim. Acta 1044 (2018) 102–109. [7] G. Zhu, X. Yin, D. Jin, B. Zhang, Y. Gu, Y. An, Paper-based immunosensors: current trends in the types and applied detection techniques, Trends Anal. Chem. 111 (2019) 100–117. [8] Y. Yang, E. Noviana, M.P. Nguyen, J. Geiss, D.S. Dandy, C.S. Henry, Paper-based microfluidic devices: emerging themes and applications, Anal. Chem. 89 (2017) 71–91. [9] R.J. Yang, C.C. Tseng, W.J. Ju, H.L. Wang, L.M. Fu, A rapid paper-based detection system for determination of human serum albumin concentration, Chem. Eng. J. 352 (2018) 241–246. [10] E.L. Rossini, M.I. Milani, E. Carrilho, L. Pezza, H.R. Pezza, Simultaneous determination of renal function biomarkers in urineusing a validated paper-based microfluidic analytical device, Anal. Chim. Acta 997 (2018) 16–23. [11] R.J. Yang, C.C. Tseng, W.J. Ju, L.M. Fu, M.P. Syu, Integrated microfluidic paperbased system for determination of whole blood albumin, Sens. Actuators B Chem. 273 (2018) 1091–1097. [12] P. Kassal, M.D. Steinberg, E. Horak, I.M. Steinberg, Wireless fluorimeter for mobile and low cost chemical sensing: a paperbasedchloride assay, Sens. Actuators B Chem. 275 (2018) 230–236. [13] C.C. Tseng, R.J. Yang, W.J. Ju, L.M. Fu, Microfluidic paper-based platform for whole blood creatinine detection, Chem. Eng. J. 348 (2018) 117–124. [14] C.C. Liu, Y.N. Wang, L.M. Fu, D.Y. Yang, Rapid integrated microfluidic paperbased system for sulfur dioxide detection, Chem. Eng. J. 316 (2017) 790–796. [15] C.C. Liu, Y.N. Wang, L.M. Fu, Y.H. Huang, Microfluidic paper-based chip platform for formaldehyde concentration detection, Chem. Eng. J. 332 (2018) 695–701. [16] J.M.C.C. Guzmana, L.L. Tayoa, C.C. Liu, Y.N. Wang, L.M. Fu, Rapid microfluidic paper-based platform for low concentration formaldehyde detection, Sens. Actuators B Chem. 255 (2018) 3623–3629. [17] C.C. Liu, Y.N. Wang, L.M. Fu, K.L. Chen, Microfluidic paper-based chip platform for benzoic acid detection in food, Food Chem. 249 (2018) 162–167. [18] G.G. Morbioli, T. Mazzu-Nascimento, A.M. Stockton, E. Carrilho, Technical aspects and challenges of colorimetric detection with microfluidic paper-based analytical devices (μPADs) – a review, Anal. Chim. Acta 970 (2017) 1–22. [19] J. Mettakoonpitak, C.S. Henry, Electrophoretic separations on Parafilm-paperbased analytical devices, Sens. Actuators B Chem. 273 (2018) 1022–1028. [20] Q. Kong, Y. Wang, L. Zhang, S. Ge, J. Yu, A novel microfluidic paper-based colorimetric sensor based on molecularly imprinted polymer membranes for highly selective and sensitive detection of bisphenol A, Sens. Actuators B Chem. 243 (2017) 130–136. [21] L. Ma, A. Nilghaz, J.R. Choi, X. Liu, X. Lu, Rapid detection of clenbuterol in milk using microfluidic paper-based ELISA, Food Chem. 246 (2018) 437–441. [22] L.M. Fu, C.C. Tseng, W.J. Ju, R.J. Yang, Rapid paper-based system for human serum creatinine detection, Inventions 3 (2018) 34. [23] T.M.G. Cardoso, F.R. de Souza, P.T. Garcia, D. Rabelo, C.S. Henry, W.K.T. Coltro, Versatile fabrication of paper-based microfluidic devices with high chemical resistance using scholar glue and magnetic masks, Anal. Chim. Acta 974 (2017) 63–68. [24] G.P. dos Santos, C.C. Corrêa, L.T. Kubota, A simple, sensitive and reduced cost paper-based device with low quantity of chemicals for the early diagnosis of Plasmodium falciparum malaria using an enzyme-based colorimetric assay, Sens. Actuators B Chem. 255 (2018) 2113–2120. [25] M.P. Nguyen, N.A. Meredith, S.P. Kelly, C.S. Henry, Design considerations for reducing sample loss in microfluidic paper-based analytical devices, Anal. Chim. Acta 1017 (2018) 20–25. [26] J. Lee, Y.J. Lee, Y.J. Ahn, S. Choi, G.J. Lee, A simple and facile paper-based colorimetric assay for detection of free hydrogen sulfide in prostate cancer cells, Sens. Actuators B Chem. 256 (2018) 828–834. [27] L.M. Fu, C.C. Liu, C.E. Yang, Y.N. Wang, C.H. Ko, A PET/paper chip platform for high resolution sulphur dioxide detection in foods, Food Chem. 286 (2019) 316–321. [28] T. Akyazi, L. Basabe-Desmonts, F. Benito-Lopez, Review on microfluidic paperbased analytical devices towards commercialization, Anal. Chim. Acta 1001 (2018) 1–17. [29] A. Nilghaz, L. Guan, W. Tan, W. Shen, Advances of paper-based microfluidics for diagnostics–The original motivation and current status, ACS Sens. 1 (2016) 1382–1393. [30] Y.S. Kim, Y. Yang, C.S. Henry, Laminated and infused Parafilm@-paper for paperbased analytical devices, Sens. Actuators B Chem. 255 (2018) 3654–3661. [31] L. Sun, Y. Jiang, R. Pan, M. Li, R. Wang, S. Chen, S. Fu, C. Man, A novel, simple and low-cost paper-based analytical device for colorimetric detection of Cronobacter spp, Anal. Chim. Acta 1036 (2018) 80–88. [32] J. Wang, W. Li, L. Ban, W. Du, X. Feng, B. Liu, A paper-based device with an
[33] [34] [35]
[36]
[37] [38] [39] [40] [41] [42] [43] [44] [45] [46] [47]
[48]
[49] [50] [51] [52] [53] [54] [55] [56] [57]
[58] [59] [60]
16
adjustable time controller for the rapid determination of tumor biomarkers, Sens. Actuators B Chem. 254 (2018) 855–862. C.H. Wang, J.J. Wu, G.B. Lee, Screening of highly-specific aptamers and their applications in paper-based microfluidic chips for rapid diagnosis of multiple bacteria, Sens. Actuators B Chem. 284 (2019) 395–402. A.W. Martinez, S.T. Phillips, G.M. Whitesides, E. Carrilho, Diagnostics for the developing world: microfluidic paper-based analytical devices, Anal. Chem. 82 (2010) 3–10. L. Guadarrama-Fernández, M. Novell, P. Blondeau, F.J. Andrade, A disposable, simple, fast and low-cost paper-based biosensor and its application to the determination of glucose in commercial orange juices, Food Chem. 265 (2018) 64–69. P.T. Garcia, E.F.M. Gabriel, G.S. Pessôa, J.C.S. Júnior, P.C.M. Filho, R.B.F. Guidugli, N.F. Höehr, M.A.Z. Arruda, W.K.T. Coltro, Paper-based microfluidic devices on the crime scene: a simple tool for rapid estimation of postmortem interval using vitreous humour, Anal. Chim. Acta 974 (2017) 69–74. A. Rayaprolu, S.K. Srivastava, K. Anand, L. Bhati, A. Asthana, C.M. Rao, Fabrication of cost-effective and efficient paper-based device for viscosity A. Measurement, Anal. Chim. Acta 1044 (2018) 86–92. F.A. Kappi, G.Z. Tsogas, A. Routs, D.C. Christodouleas, D.L. Giokas, Paper-based devices for biothiols sensing using the photochemical reduction of silver halides, Anal. Chim. Acta 1036 (2018) 89–96. L. Huang, P. Jiang, D. Wang, Y. Luo, M. Li, H. Lee, R.A. Gerhardt, A novel paperbased flexible ammonia gas sensor via silver and SWNT-PABS inkjet printing, Sens. Actuators B Chem. 197 (2014) 308–313. S. Liu, R. Cao, J. Wu, L. Guan, M. Li, J. Liu, J. Tian, Directly writing barrier-free patterned biosensors and bioassays on paper for low-cost diagnostics, Sens. Actuators B Chem. 285 (2019) 529–535. T. Tiana, H. Liua, L. Li, J. Yu, S. Ge, X. Song, M. Yan, Paper-based biosensor for noninvasive detection of epidermal growth factor receptor mutations in non-small cell lung cancer patients, Sens. Actuators B Chem. 251 (2017) 440–445. M. Rahbar, P.N. Nesterenko, B. Paull, M. Macka, High-throughput deposition of chemical reagents via pen-plotting technique for microfluidic paper-based analytical devices, Anal. Chim. Acta 1047 (2019) 115–123. L. Xiao, Z. Zhang, C. Wu, L. Han, H. Zhang, Molecularly imprinted polymer grafted paper-based method for the detection of 17β-estradiol, Food Chem. 221 (2017) 82–86. G.G. Morbioli, T. Mazzu-Nascimento, A.M. Stockton, E. Carrilho, Technical aspects and challenges of colorimetric detection with microfluidic paper-basedanalytical devices (μPADs) – a review, Anal. Chim. Acta 970 (2017) 1–22. Y.J. Lee, K.S. Eom, K. Shin, J.Y. Kang, S.H. Lee, Enzyme-loaded paper combined impedimetric sensor for the determination of the low-level of cholesterol in saliva, Sens. Actuators B Chem. 271 (2018) 73–81. Y. Fu, X. Zhou, D. Xing, Integrated paper-based detection chip with nucleic acid extraction and amplification for automatic and sensitive pathogen detection, Sens. Actuators B Chem. 261 (2018) 288–296. S. Doughan, U. Uddayasankar, A. Peri, U.J. Krull, Apaper-based multiplexed resonance energy transfer nucleic acid hybridization assay using a single form of upconversion nanoparticleas donor and three quantum dots as acceptors, Anal. Chim. Acta 962 (2017) 88–96. M. Pavithra, S. Muruganand, C. Parthiban, Development of novel paper based electrochemical immunosensor with self-made goldnanoparticle ink and quinone derivate for highly sensitive carcinoembryonic antigen, Sens. Actuators B Chem. 257 (2018) 496–503. S.M. Russell, R. de la Rica, Papertransducers to detect plasmon variations in colorimetric nanoparticle biosensors, Sens. Actuators B Chem. 270 (2018) 327–332. Z. Wang, J. Zhang, L. Liu, X. Wu, H. Kuang, C. Xu, L. Xu, A colorimetric paperbased sensor for toltrazuril and its metabolites in feed, chicken, and egg samples, Food Chem. 276 (2019) 707–713. M.M. Ali, C.L. Brown, S. Jahanshahi-Anbuhi, B. Kannan, Y. Li, C.D.M. Filipe, J.D. Brennan, A printed multicomponent paper sensor for bacterial detection, Sci. Rep. 7 (2017) 12335. X. Li, D.R. Ballerini, W. Shen, A perspective on paper-based microfluidics: current status and future trends, Biomicrofluid. 6 (2012) 011301. C. Teng, D. Xie, J. Wang, Z. Yang, G. Ren, Y. Zhu, Ultrahigh conductive graphene paper based on ball‐milling exfoliated graphene, Adv. Funct. Mater. 27 (2017) 1700240. D.R. Ballerini, X. Li, W. Shen, Patterned paper and alternative materials as substrates for low-cost microfluidic diagnostics, Microfluid. Nanofluid. 13 (2012) 769–787. P. Wang, Z. Cheng, Q. Chen, L. Qu, X. Miao, Q. Feng, Construction of a paperbased electrochemical biosensing platform for rapid and accurate detection of adenosine triphosphate (ATP), Sens. Actuators B Chem. 256 (2018) 931–937. D.M. Cate, J.A. Adkins, J. Mettakoonpitak, C.S. Henry, Recent developments in paper-based microfluidic devices, Anal. Chem. 87 (2015) 19–41. H. Wang, Y. Jian, Q. Kong, H. Liu, F. Lan, L. Liang, S. Ge, J. Yu, Ultrasensitive electrochemical paper-based biosensor for microRNA via strand displacement reaction and metal-organic frameworks, Sens. Actuators B Chem. 257 (2018) 561–569. A.A.S. Samson, J. Lee, J.M. Song, Inkjet printing-based photo-induced electron transfer reaction on parchment paper using riboflavin as a photosensitizer, Anal. Chim. Acta 1012 (2018) 49–59. N. Ruecha, K. Shin, O. Chailapakul, N. Rodthongkum, Label-free paper-based electrochemical impedance immunosensor for human interferon gamma detection, Sens. Actuators B Chem. 279 (2019) 298–304. L. Guadarrama-Fernández, M. Novell, P. Blondeau, F.J. Andrade, A disposable,
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al.
[61] [62] [63] [64]
[65] [66]
[67] [68] [69] [70] [71]
[72] [73] [74] [75] [76] [77]
[78] [79] [80] [81]
[82]
[83] [84]
[85]
[86]
simple, fast and low-cost paper-based biosensor and its application to the determination of glucose in commercial orange juices, Food Chem. 265 (2018) 64–69. N. Dossi, R. Toniolo, F. Terzi, N. Sdrigotti, F. Tubaro, G. Bontempelli, A cotton thread fluidic device with a wall-jet pencil-drawn paper based dual electrode detector, Anal. Chim. Acta 1040 (2018) 74–80. S. Bharadwaj, A. Pandey, B. Yagci, V. Ozguz, A. Qureshi, Graphene nano-mesh-AgZnO hybrid paper for sensitive SERS sensing and self-cleaning of organic pollutants, Chem. Eng. J. 336 (2018) 445–455. Y. Chen, W. Chu, W. Liu, X. Guo, Distance-based carcinoembryonic antigen assay on microfluidic paper immunodevice, Sens. Actuators B Chem. 260 (2018) 452–459. E. Jaworsk, G. Pomarico, B.B. Bern, K. Maksymiuk, R. Paolesse, A. Michalska, Allsolid-state paper based potentiometric potassium sensors containing cobalt(II) porphyrin/cobalt(III) corrole in the transducer layer, Sens. Actuators B Chem. 277 (2018) 306–311. Q. Huang, K. Zhang, Y. Yang, J. Ren, R. Sun, F. Huang, X. Wang, Highly smooth, stable and reflective Ag-paper electrode enabled by silver mirror reaction for organic optoelectronics, Chem. Eng. J. 370 (2019) 1048–1056. J. Park, J.K. Park, Pressed region integrated 3Dpaper-based microfluidic device that enables vertical flow multistep assays for the detection of C-reactive protein basedon programmed reagent loading, Sens. Actuators B Chem. 246 (2017) 1049–1055. R.A.G. de Oliveira, F. Camargo, N.C. Pesquero, R.C. Faria, A simple method to produce 2D and 3D microfluidic paper-based analytical devices for clinical analysis, Anal. Chim. Acta 957 (2017) 40–46. X. Weng, S.R. Ahmed, S. Neethirajan, A nanocomposite-based biosensor for bovine haptoglobin on a 3Dpaper-based analytical device, Sens. Actuators B Chem. 265 (2018) 242–248. L. Fan, Q. Hao, X. Kan, Three-dimensional graphite paper based imprinted electrochemical sensor for tertiary butylhydroquinone selective recognition and sensitive detection, Sens. Actuators B Chem. 256 (2018) 520–527. X. Sun, B. Li, C. Tian, F. Yu, N. Zhou, Y. Zhan, L. Chen, Rotational paper-based electrochemiluminescence immunodevices for sensitive and multiplexed detection of cancer biomarkers, Anal. Chim. Acta 1007 (2018) 33–39. G. Sriram, M.P. Bhat, P. Patil, U.T. Uthappa, H.Y. Jung, T. Altalhi, T. Kumeria, T.M. Aminabhavi, R.K. Pai, M.D.K. Madhuprasad, Paper-based microfluidic analytical devices for colorimetric detection of toxic ions: a review, Trends Anal, Chem. 93 (2017) 212–227. A.T. Singh, D. Lantigua, A. Meka, S. Taing, M. Pandher, G. Camci-Unal, Paperbased sensors: emerging themes and applications, Sensors 18 (2018) 2838. J.P. Rojas, D. Conchouso, A. Arevalo, D. Singh, I.G. Foulds, M.M. Hussain, Based origami flexible and foldable thermoelectric nanogenerator, Nano Energy 31 (2017) 296–301. W. Chu, Y. Chen, W. Liu, M. Zhao, H. Li, Paper-based chemiluminescence immunodevice with temporal controls of reagent transport technique, Sens. Actuators B Chem. 250 (2017) 324–332. A. Alba-Patiño, S.M. Russell, R. de la Rica, Origami-enabled signal amplification for paper-based colorimetric biosensors, Sens. Actuators B Chem. 273 (2018) 951–954. K.H. Chou, S.H. Yeh, R.J. Yang, Enhanced sample concentration on a three-dimensional origami paper-based analytical device with non-uniform assay channel, Microfluid. Nanofluid. 21 (2017) 112. S.A. Nogueira, A.D. Lemes, A.C. Chagas, M.L. Vieira, M. Talhavini, P.A.O. Morais, W.K.T. Coltro, Redox titration on foldable paper-based analytical devices for the visual determination of alcohol content in whiskey samples, Talanta 194 (2019) 363–369. L. Xie, X. Zi, H. Zeng, J. Sun, L. Xu, S. Chen, Low-cost fabrication of a paper-based microfluidic using a folded pattern paper, Anal. Chim. Acta 1053 (2019) 131–138. Y. Lin, D. Gritsenko, F. S, Y.C.I.X. Lu, J. Xu, Detection of heavy metal by paperbased microfluidics, Biosens. Bioelectron. 83 (2016) 256–266. R.S. Aparna, J.S.A. Devi, P. Sachidanandan, S. George, Polyethylene imine capped copper nanoclusters- fluorescent and colorimetric onsite sensor for the trace level detection of TNT, Sens. Actuators B Chem. 254 (2018) 811–819. J. Qi, B. Li, X. Wang, Z. Zhang, Z. Wang, J. Han, L. Chen, Three-dimensional paperbased microfluidic chip device for multiplexed fluorescence detection of Cu2+ and Hg2+ ions based on ion imprinting technology, Sens. Actuators B Chem. 251 (2017) 224–233. J. Bhardwaj, S. Devarakonda, S. Kumar, J. Jang, Development of a paper-based electrochemical immunosensor using an antibody-single walled carbon nanotubes bio-conjugate modified electrode for label-free detection of foodborne pathogens, Sens. Actuators B Chem. 253 (2017) 115–123. M.I.G.S. Almeida, B.M. Jayawardane, S.D. Kolev, I.D. McKelvie, Developments of microfluidic paper-based analytical devices (μPADs) for water analysis: a review, Talanta 177 (2018) 176–190. S. Ge, J. Zhao, S. Wang, F. Lan, M. Yan, J. Yu, Ultrasensitive electrochemiluminescence assay of tumor cells and evaluation of H2O2 on apaper-based closed-bipolar electrode by in-situ hybridization chain reaction amplification, Biosens. Bioelectron. 102 (2018) 411–417. K. Chu, P. Chen, Y. You, H. Chang, W. Kao, Y. Chu, C. Wu, J. Shyue, Integration of paper-based microarray and time-of-flight secondary ion mass spectrometry (ToFSIMS) for parallel detection and quantification of molecules in multiple samples automatically, Anal. Chim. Acta 1005 (2018) 61–69. Y. Xu, P. Man, Y. Huo, T. Ning, C. Li, B. Man, C. Yang, Synthesis of the 3D AgNF/ AgNP arrays for the paper-based surface enhancement Raman scattering application, Sens. Actuators B Chem. 265 (2018) 302–309.
[87] Y. Wu, Y. Ren, L. Han, Y. Yan, H. Jiang, Three-dimensional paper based platform for automatically running multiple assays in a single step, Talanta 200 (2019) 177–185. [88] E. Erçağ, A. Üzer, Ş. Eren, Ş. Sağlam, H. Filik, R. Apak, Rapid detection of nitroaromatic and nitramine explosives on chromatographic paper and their reflectometric sensing on PVC tablets, Talanta 85 (2011) 2226–2232. [89] J. Wang, L. Yang, B. Liu, H. Jiang, R. Liu, J. Yang, G. Han, Q. Mei, Z. Zhang, Inkjetprinted silver nanoparticle paper detects airborne species from crystalline explosives and their ultratrace residues in open environment, Anal. Chem. 86 (2014) 3338–3345. [90] P. Ryan, D. Zabetakis, D. Stenger, S. Trammell, Integrating paper chromatography with electrochemical detection for the trace analysis of TNT in soil, Sensors 15 (2015) 17048–17056. [91] M. Ueland, L. Blanes, R.V. Taudte, B.H. Stuart, N. Cole, P. Willis, P. Doble, Capillary-driven microfluidic paper-based analytical devices for lab on a chip screening of explosive residues in soil, J. Chromatograp. A 1436 (2016) 28–33. [92] S.T. Krauss, V.C. Holt, J.P. Landers, Simple reagent storage in polyester-paper hybrid microdevices for colorimetric detection, Sens. Actuators B Chem. 246 (2017) 740–747. [93] K.L. Peters, I. Corbin, L.M. Kaufman, K. Zreibe, L. Blanes, B.R. McCord, Simultaneous colorimetric detection of improvised explosive compounds using microfluidic paper based analytical devices (μPADs), Anal. Methods 7 (2015) 63–70. [94] L. Shriver-Lake, D. Zabetakis, W. Dressick, D. Stenger, S. Trammell, Paper-based electrochemical detection of chlorate, Sensors 18 (2018) 328. [95] S.S.B. Moram, C. Byram, S.N. Shibu, B.M. Chilukamarri, V.R. Soma, Ag/Au nanoparticle-loaded paper-based versatile surface-enhanced Raman spectroscopy substrates for multiple explosives detection, ACS Omega 3 (2018) 8190–8201. [96] W. Xiao, Y. Gao, Y. Zhang, J. Li, Z. Liu, J. Nie, J. Li, Enhanced 3D paper-based devices with a personal glucose meter for highly sensitive and portable biosensing of silver ion, Biosens. Bioelectron. 137 (2019) 154–160. [97] H. Arabyarmohammadi, A.K. Darban, M. Abdollahy, B. Ayati, Simultaneous immobilization of heavy metals in soil environment by pulp and paper derived nanoporous biochars, J. Environ. Health Sci. Eng. 16 (2018) 109–119. [98] S.H. Nam, Y.J. An, Disc method: an efficient assay for evaluating metal toxicity to soil algae, Environ. Pollut. 216 (2016) 1–8. [99] P.G. Sutariya, H. Soni, S.A. Gandhi, A. Pandya, Single-step fluorescence recognition of As3+, Nd3+ and Br− using pyrene-linked calix[4]arene: application to real samples, computational modelling and paper-based device, New J. Chem. 43 (2019) 737–747. [100] P.G. Sutariya, H. Soni, S.A. Gandhi, A. Pandya, Novel tritopic calix[4]arene CHEFPET fluorescence paper based probe for La3+, Cu2+, and Br−: its computational investigation and application to real samples, J. Lumin. 212 (2019) 171–179. [101] P.G. Sutariya, H. Soni, S.A. Gandhi, A. Pandya, Novel luminescent paper based calix[4]arene chelation enhanced fluorescence- photoinduced electron transfer probe for Mn2+, Cr3+ and F−, J. Lumin. 208 (2019) 6–17. [102] B.M. Jayawardane, I.D. McKelvie, S.D. Kolev, A paper-based device for measurement of reactive phosphate in water, Talanta 100 (2012) 454–460. [103] B.M. Jayawardane, W. Wongwilai, K. Grudpan, S.D. Kolev, M.W. Heaven, D.M. Nash, I.D. McKelvie, Evaluation and application of a paper-based device for the determination of reactive phosphate in soil solution, J. Environ. Qual. 43 (2014) 1081–1085. [104] B.M. Jayawardane, I.D. McKelvie, S.D. Kolev, Development of a gas-diffusion microfluidic paper-based analytical device (μPAD) for the determination of ammonia in wastewater samples, Anal. Chem. 87 (2015) 4621–4626. [105] A.G. Wang, T. Dong, H. Mansour, G. Matamoros, A.L. Sanchez, F. Li, Paper-based DNA reader for visualized quantification of soil-transmitted helminth Infections, ACS Sens. 3 (2018) 205–210. [106] E. Pellegrini, M. Contin, L. Vittori Antisari, G. Vianello, C. Ferronato, M. De Nobili, A new paper sensor method for field analysis of acid volatile sulfides in soils, Environ. Toxicol. Chem. 37 (2018) 3025–3031. [107] S.H. Nam, J.I. Kwak, Y.J. An, Assessing applicability of the paper-disc method used in combination with flow cytometry to evaluate algal toxicity, Environ. Pollut. 234 (2018) 979–987. [108] H. Liu, W. Gao, Y. Tian, A. Liu, Z. Wang, Y. Cai, Z. Zhao, Rapidly detecting tetrabromobisphenol A in soils and sediments by paper spray ionization mass spectrometry combined with isotopic internal standard, Talanta 191 (2019) 272–276. [109] P. Basuri, A. Baidya, T. Pradeep, Sub-parts-per-trillion level detection of analytes by superhydrophobic preconcentration paper spray ionization mass spectrometry (SHPPSI MS), Anal. Chem. 91 (2019) 7118–7124. [110] P. Naik, S. Jaitpal, P. Shetty, D. Paul, An integrated one-step assay combining thermal lysis and loop-mediated isothermal DNA amplification (LAMP) in 30 min from E. Coli and M. Smegmatis cells on a paper substrate, Sens. Actuators B Chem. 291 (2019) 74–80. [111] T.S. Park, J.Y. Yoon, Smartphone detection of Escherichia coli from field water samples on paper microfluidics, IEEE Sens. J. 15 (2015) 1902–1907. [112] J. Zhang, Z. Yang, Q. Liu, H. Liang, Electrochemical biotoxicity detection on a microfluidic paper-based analytical device via cellular respiratory inhibition, Talanta 202 (2019) 384–391. [113] G.A.R.Y. Suaifan, M. Zourob, Portable paper-based colorimetric nanoprobe for the detection of Stachybotrys chartarum using peptide labeled magnetic nanoparticles, Microchim. Acta 186 (2019) 230. [114] T. Soga, Y. Jimbo, K. Suzuki, D. Citterio, Inkjet-printed paper-based colorimetric sensor array for the discrimination of volatile primary amines, Anal. Chem. 85 (2013) 8973–8978. [115] P. Tang, G. Sun, Highly sensitive colorimetric paper sensor for methyl
17
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al.
[116] [117] [118] [119] [120] [121] [122] [123] [124] [125] [126] [127] [128] [129] [130] [131] [132] [133]
[134]
[135] [136] [137] [138] [139] [140] [141] [142] [143] [144] [145]
isothiocyanate (MITC): using its toxicological reaction, Sens. Actuators B Chem. 261 (2018) 178–187. Y. Chen, R.E. Owyeung, S.R. Sonkusale, Combined optical and electronic papernose for detection of volatile gases, Anal. Chim. Acta 1034 (2018) 128–136. A. Fraiwan, H. Lee, S. Choi, A paper-based cantilever array sensor: monitoring volatile organic compounds with naked eye, Talanta 158 (2016) 57–62. T. Kuretake, S. Kawahara, M. Motooka, S. Uno, An electrochemical gas biosensor based on enzymes immobilized on chromatography paper for ethanol vapor detection, Sensors 17 (2017) 281. M. Motooka, S. Uno, Improvement in limit of detection of enzymatic biogas sensor utilizing chromatography paper for breath analysis, Sensors 18 (2018) 440. Z. Wen, S. Song, C. Wang, F. Qu, T. Thomas, T. Hu, P. Wang, M. Yang, Large-scale synthesis of dual-emitting-based visualization sensing paper for humidity and ethanol detection, Sens. Actuators B Chem. 282 (2019) 9–15. M. Luo, K. Shao, Z. Long, L. Wang, C. Peng, J. Ouyang, N. Na, A paper-based plasma-assisted cataluminescence sensor for ethylene detection, Sens. Actuators B Chem. 240 (2017) 132–141. R.S. Alkasir, A. Rossner, S. Andreescu, Portable colorimetric paper-based biosensing device for the assessment of bisphenol A in indoor dust, Environ. Sci. Technol. 49 (2015) 9889–9897. N. Colozz, K. Kehe, G. Dionisi, T. Popp, A. Tsoutsoulopoulos, D. Steinritz, D. Moscone, F. Arduini, A wearable origami-like paper-based electrochemical biosensor for sulfur mustard detection, Biosens. Bioelectron. 129 (2019) 15–23. L. Huang, P. Jiang, D. Wang, Y. Luo, M. Li, H. Lee, R.A. Gerhardt, A novel paperbased flexible ammonia gas sensor via silver and SWNT-PABS inkjet printing, Sens. Actuators B Chem. 197 (2014) 308–313. L.R. Shobin, S. Manivannan, Carbon nanotubes on paper: flexible and disposable chemiresistors, Sens. Actuators B Chem. 220 (2015) 1178–1185. A. Maity, B. Ghosh, Fast response paper based visual color change gas sensor for efficient ammonia detection at room temperature, Sci. Reports 8 (2018) 16851. A. Maity, A.K. Raychaudhuri, B. Ghosh, High sensitivity NH3 gas sensor with electrical readout made on paper with perovskite halide as sensor material, Sci. Rep. 9 (2019) 7777. J.F.D.S. Petruci, A.A. Cardoso, Portable and disposable paper-based fluorescent sensor for in situ gaseous hydrogen sulfide determination in near real-time, Anal. Chem. 88 (2016) 11714–11719. A. Quddious, S. Yang, M. Khan, F. Tahir, A. Shamim, K. Salama, H. Cheema, Disposable, paper-based, inkjet-printed humidity and H2S gas sensor for passive sensing applications, Sensors 16 (2016) 2073. J.F. da Silveira Petruci, A.A. Cardoso, Sensitive luminescent paper-based sensor for the determination of gaseous hydrogen sulfide, Anal. Methods 7 (2015) 2687–2692. J. Zhang, L. Huang, Y. Lin, L. Chen, Z. Zeng, L. Shen, Q. Chen, W. Shi, Pencil-trace on printed silver interdigitated electrodes for paper-based NO2 gas sensors, Appl. Phys. Lett. 106 (2015) 143101. H. Kan, M. Li, J. Luo, B. Zhang, J. Liu, Z. Hu, G. Zhang, S. Jaing, H. Liu, PbS nanowires-on-paper sensors for room-temperature gas detection, IEEE Sens. J. 19 (2019) 846–851. J. Sitanurak, N. Wangdi, T. Sonsa-ard, S. Teerasong, T. Amornsakchai, D. Nacapricha, Simple and green method for direct quantification of hypochlorite in household bleach with membraneless gas-separation microfluidic paper-based analytical device, Talanta 187 (2018) 91–98. E.S. Dhummakupt, P.M. Mach, D. Carmany, P.S. Demond, T.S. Moran, T. Connell, H.S. Wylie, N.E. Manicke, J.M. Nilles, T. Glaros, Direct analysis of aerosolized chemical warfare simulants captured on a modified glass-based substrate by “paper-spray” ionization, Anal. Chem. 89 (2017) 10866–10872. H. Sun, Y. Jia, H. Dong, L. Fan, J. Zheng, Multiplex quantification of metals in airborne particulate matter via smartphone and paper-based microfluidics, Anal. Chim. Acta 1044 (2018) 110–118. H. Sun, Y. Jia, H. Dong, L. Fan, Graphene oxide nanosheets coupled with paper microfluidics for enhanced on-site airborne trace metal detection, Microsyst. Nanoeng. 5 (2019) 4. W. Dungchai, Y. Sameenoi, O. Chailapakul, J. Volckens, C.S. Henry, Determination of aerosol oxidative activity using silver nanoparticle aggregation on paper-based analytical devices, Analyst 138 (2013) 6766–6773. P. Rattanarat, W. Dungchai, D. Cate, J. Volckens, O. Chailapakul, C.S. Henry, Multilayer paper-based device for colorimetric and electrochemical quantification of metals, Anal. Chem. 86 (2014) 3555–3562. D.T. Nguyen, H.R. Kim, J.H. Jung, K.B. Lee, B.C. Kim, The development of paper discs immobilized withluciferase/D-luciferin for the detection of ATP from airborne bacteria, Sens. Actuators B Chem. 260 (2018) 274–281. A.J. Gimenez, G. Luna-Barcenas, I.C. Sanchez, J.M. Yanez-Limon, Paper-based ZnO oxygen sensor, IEEE Sens. J. 15 (2015) 1246–1251. H. Zhao, L. Zang, H. Zhao, Y. Zhang, Y. Zheng, Z. Zhang, W. Cao, Oxygen sensing properties of gadolinium labeled hematoporphyrin monomethyl ether based on filter paper, Sens. Actuators B Chem. 206 (2015) 351–356. H. Zhao, T. Zhang, R. Qi, J. Dai, S. Liu, T. Fei, Drawn on paper: a reproducible humidity sensitive device by handwriting, ACS Appl, Mater. Interfaces 9 (2017) 28002–28009. X. Zang, C. Shen, Y. Chu, B. Li, M. Wei, J. Zhong, M. Sanghadasa, L. Lin, Laser‐induced molybdenum carbide–graphene composites for 3D foldable paper electronics, Adv. Mater. 30 (2018) 1800062. R.M. Morais, M. dos Santos Klem, G.L. Nogueira, T.C. Gomes, N. Alves, Low cost humidity sensor based on PANI/PEDOT: PSS printed on paper, IEEE Sens. J. 18 (2018) 2647–182651. J. Zhang, A.B. Dichiara, I. Novosselov, D. Gao, J. Chung, Polyacrylic acid coated
[146] [147] [148] [149] [150] [151] [152] [153] [154] [155] [156] [157] [158] [159] [160] [161] [162]
[163] [164] [165] [166] [167] [168] [169] [170] [171] [172]
[173]
[174]
18
carbon nanotube–paper composites for humidity and moisture sensing, J. Mater. Chem. C Mater. Opt. Electron. Devices 7 (2019) 5374–5380. P. Tian, X. Gao, G. Wen, L. Zhong, Z. Wang, Z. Guo, Novel fabrication of polymer/ carbon nanotube composite coated Janus paper for humidity stress sensor, J. Colloid Interface Sci. 532 (2018) 517–526. X. Zang, Y. Jiang, X. Wang, X. Wang, J. Ji, M. Xue, Highly sensitive pressure sensors based on conducting polymer-coated paper, Sens. Actuators B Chem. 273 (2018) 1195–1201. S. Chen, Y. Song, F. Xu, Flexible and highly sensitive resistive pressure sensor based on carbonized crepe paper with corrugated structure, ACS Appl. Mater. Interfaces 10 (2018) 34646–34654. W. Liu, J. Kou, H. Xing, B. Li, Based chromatographic chemiluminescence chip for the detection of dichlorvos in vegetables, Biosens. Bioelectron. 52 (2014) 76–81. W. Liu, Y. Guo, J. Luo, J. Kou, H. Zheng, B. Li, Z. Zhang, A molecularly imprinted polymer based a lab-on-paper chemiluminescence device for the detection of dichlorvos, Spectrochim. Acta A. Mol. Biomol. Spectrosc. 141 (2015) 51–57. Z. Ayazi, F. Shekari Esfahlan, P. Matin, Graphene oxide reinforced polyamide nanocomposite coated on paper as a novel layered sorbent for microextraction by packed sorbent, Int. J. Environ. Anal. Chem. 98 (2018) 1118–1134. A. Apilux, W. Siangproh, N. Insin, O. Chailapakul, V. Prachayasittikul, Paperbased thioglycolic acid (TGA)-capped CdTe QD device for rapid screening of organophosphorus and carbamate insecticides, Anal. Methods 9 (2017) 519–527. W. Yang, L. Zhang, H. Liu, Z. Gu, Smartphone-based paper microfluidic device for potentiometric detection of pesticide, Chinese J. Anal. Chem. 44 (2016) 586–590. H.J. Kim, Y. Kim, S.J. Park, C. Kwon, H. Noh, Development of colorimetric paper sensor for pesticide detection using competitive-inhibiting reaction, Biochip J. 12 (2018) 326–331. S. Nouanthavong, D. Nacapricha, C.S. Henry, Y. Sameenoi, Pesticide analysis using nanoceria-coated paper-based devices as a detection platform, Analyst 141 (2016) 1837–1846. J. Ding, B. Li, L. Chen, W. Qin, A three‐dimensional origami paper‐based device for potentiometric biosensing, Angew. Chem. Int. Ed. 55 (2016) 13033–13037. J. Chang, H. Li, T. Hou, F. Li, Based fluorescent sensor for rapid naked-eye detection of acetylcholinesterase activity and organophosphorus pesticides with high sensitivity and selectivity, Biosens. Bioelectronics 86 (2016) 971–977. C. Liu, F.A. Gomez, A microfluidic paper‐based device to assess acetylcholinesterase activity, Electrophoresis 38 (2017) 1002–1006. G. Scordo, D. Moscone, G. Palleschi, F. Arduini, A reagent-free paper-based sensor embedded in a 3D printing device for cholinesterase activity measurement in serum, Sens. Actuators B Chem. 258 (2018) 1015–1021. Y. Wu, Y. Sun, F. Xiao, Z. Wu, R. Yu, Sensitive inkjet printing paper-based colormetric strips for acetylcholinesterase inhibitors with indoxyl acetate substrate, Talanta 162 (2017) 174–179. M. Kavruk, V.C. Özalp, H.A. Öktem, Portable bioactive paper-based sensor for quantification of pesticides, J. Anal. Methods Chem. (2013) 932946. Z. Ayazi, F.S. Esfahlan, Z.M. Khoshhesab, ZnO nanoparticles doped polyamide nanocomposite coated on cellulose paper as a novel sorbent for ultrasound-assisted thin film microextraction of organophosphorous pesticides in aqueous samples, Anal. Methods 10 (2018) 3043–3051. C. Zhang, H. Cui, Y. Han, F. Yu, X. Shi, Development of a biomimetic enzymelinked immunosorbent assay based on molecularly imprinted polymers on paper for the detection of carbaryl, Food Chem. 240 (2018) 893–897. A. Mohammadi, F. Ghasemi, M.R. Hormozi-Nezhad, Development of a paperbased plasmonic test strip for visual detection of methiocarb insecticide, IEEE Sens. J. 17 (2017) 6044–6049. Q. Wang, Y. Liu, Y. Bai, S. Yao, Z. Wei, M. Zhang, L. Wang, L. Wang, Superhydrophobic SERS substrates based on silver dendrite-decorated filter paper for trace detection of nitenpyram, Anal. Chim. Acta 1049 (2019) 170–178. A. Apilux, C. Isarankura-Na-Ayudhya, T. Tantimongcolwat, V. Prachayasittikul, Based acetylcholinesterase inhibition assay combining a wet system for organophosphate and carbamate pesticides detection, EXCLI J. 14 (2013) 307–319. M.E. Badawy, A.F. El-Aswad, Bioactive paper sensor based on the acetylcholinesterase for the rapid detection of organophosphate and carbamate pesticides, Int. J. Anal. Chem. (2014) 536823. Y. Ma, Y. Wang, Y. Luo, H. Duan, D. Li, H. Xu, E.K. Fodjo, Rapid and sensitive onsite detection of pesticide residues in fruits and vegetables using screen-printed paper-based SERS swabs, Anal. Methods 10 (2018) 4655–4664. H. Evard, A. Kruve, R. Lõhmus, I. Leito, Paper spray ionization mass spectrometry: study of a method for fast-screening analysis of pesticides in fruits and vegetables, J. Food Anal. 41 (2015) 221–225. M. Lee, K. Oh, H.K. Choi, S.G. Lee, H.J. Youn, H.L. Lee, D.H. Jeong, Subnanomolar sensitivity of filter paper-based SERS sensor for pesticide detection by hydrophobicity change of paper surface, ACS Sens. 3 (2018) 151–159. C. Zhang, T. You, N. Yang, Y. Gao, L. Jiang, P. Yin, Hydrophobic paper-based SERS platform for direct-droplet quantitative determination of melamine, Food Chem. 287 (2019) 363–368. D. Deng, Q. Lin, H. Li, Z. Huang, Y. Kuang, H. Chen, J. Kong, Rapid detection of malachite green residues in fish using a surface-enhanced Raman scattering-active glass fiber paper prepared by in situ reduction method, Talanta 200 (2019) 272–278. P.A. Atanasov, N.N. Nedyalkov, N. Fukata, W. Jevasuwan, T. Subramani, M. Terakawa, Ya Nakajima, Surface-enhanced Raman spectroscopy (SERS) of mancozeb and thiamethoxam assisted by gold and silver nanostructures produced by laser techniques on paper, Appl. Spectrosc. 73 (2019) 313–319. S. Cinti, C. Minotti, D. Moscone, G. Palleschi, F. Arduini, Fully integrated ready-touse paper-based electrochemical biosensor to detect nerve agents, Biosens.
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al. Bioelectronics 93 (2017) 46–51. [175] L.J. Sun, Y. Xie, Y.F. Yan, H. Yang, H.Y. Gu, N. Bao, Based analytical devices for direct electrochemical detection of free IAA and SA in plant samples with the weight of several milligrams, Sens. Actuators B Chem. 247 (2017) 336–342. [176] S. Lee, J. Park, J.K. Park, Foldable paper-based analytical device for the detection of an acetylcholinesterase inhibitor using an angle-based readout, Sens. Actuators B Chem. 273 (2018) 322–327. [177] A.T. Jafry, H. Lee, A.P. Tenggara, H. Lim, Y. Moon, S.H. Kim, Y. Lee, S.M. Kim, S. Park, D. Byun, J. Lee, Double-sided electrohydrodynamic jet printing of twodimensional electrode array in paper-based digital microfluidics, Sens. Actuators B Chem. 282 (2019) 831–837. [178] A. İncel, O. Akın, A. Cagır, Ü. Yıldızc, M.M. Demir, Smart phone assisted detection and quantification of cyanide in drinking water by paper based sensing platform, Sens. Actuators B Chem. 252 (2017) 886–893. [179] Y. Li, Y. Chen, H. Yu, L. Tian, Z. Wang, Portable and smart devices for monitoring heavy metal ions integrated with nanomaterials, Trends Anal, Chem. 98 (2018) 190–200. [180] N.N. Hamidon, Y. Hong, G.I. Salentijn, E. Verpoorte, Water-based alkyl ketene dimer ink for user-friendly patterning in paper microfluidics, Anal. Chim. Acta 1000 (2018) 180–190. [181] M. Rahbar, B. Paull, M. Macka, Instrument-free argentometric determination of chloride via trapezoidal distance-based microfluidic paper devices, Anal. Chim. Acta 1063 (2019) 1–8. [182] A. Sánchez-Calvo, M.T. Fernández-Abedul, M.C. Blanco-López, A. Costa-García, Paper-based electrochemical transducer modified with nanomaterials for mercury determination in environmental waters, Sens. Actuators B Chem. 290 (2019) 87–92. [183] P. Vijitvarasan, S. Oaew, W. Surareungchai, Based scanometric assay for lead ion detection using DNAzyme, Anal. Chim. Acta 896 (2015) 152–159. [184] J. Xu, Y. Zhang, L. Li, Q. Kong, L. Zhang, S. Ge, J. Yu, Colorimetric and electrochemiluminescence dual-mode sensing of lead Ion based on integrated Lab-onpaper device, ACS Appl. Mater. Interfaces 10 (2018) 3431–3440. [185] H. Sun, W. Li, Z.Z. Dong, C. Hu, C.H. Leung, D.L. Ma, K. Ren, A suspending-droplet mode paper-based microfluidic platform for low-cost, rapid, and convenient detection of lead (II) ions in liquid solution, Biosens. Bioelectronics 99 (2018) 361–367. [186] P. Li, J. Li, M. Bian, D. Huo, C. Hou, P. Yang, M. Yang, A redox route for the fluorescence detection of lead ions in sorghum, river water ad tap water and a desk study of a paper-based probe, Anal. Methods 10 (2018) 3256–3262. [187] X. Lin, S.X. Li, F.Y. Zheng, An integrated system for field analysis of Cd (ii) and Pb (ii) via preconcentration using nano-TiO2/cellulose paper composite and subsequent detection with a portable X-ray fluorescence spectrometer, RSC Adv. 6 (2016) 9002–9006. [188] N. Fakhri, M. Hosseini, O. Tavakoli, Aptamer-based colorimetric determination of Pb2+ using a paper-based microfluidic platform, Anal. Methods 10 (2018) 4438–4444. [189] E. de Almeida, V.F. do Nascimento Filho, A.A. Menegário, Based diffusive gradients in thin films technique coupled to energy dispersive X-ray fluorescence spectrometry for the determination of labile Mn, Co, Ni, Cu, Zn and Pb in river water, Spectrochim. Acta Part B At. Spectrosc. 71 (2018) 70–74. [190] Y. Zhang, M. Li, H. Liu, S. Ge, J. Yu, Label-free colorimetric logic gates based on free gold nanoparticles and the coordination strategy between cytosine and silver ions, New J. Chem. 40 (2016) 5516–5522. [191] J. Dhavamani, L.H. Mujawar, M.S. El-Shahawi, Hand drawn paper-based optical assay plate for rapid and trace level determination of Ag+ in water, Sens. Actuators B Chem. 258 (2018) 321–330. [192] A. Sadollahkhani, A. Hatamie, O. Nur, M. Willander, B. Zargar, I. Kazeminezhad, Colorimetric disposable paper coated with ZnO@ ZnS core–shell nanoparticles for detection of copper ions in aqueous solutions, ACS Appl. Mater. Interfaces 6 (2014) 17694–17701. [193] X. Liu, C. Zong, L. Lu, Fluorescent silver nanoclusters for user-friendly detection of Cu2+ on a paper platform, Analyst 137 (2012) 2406–2414. [194] Y. Cui, X. Wang, Q. Zhang, H. Zhang, H. Li, M. Meyerhoff, Colorimetric copper ion sensing in solution phase and on paper substrate based on catalytic decomposition of S-nitrosothiol, Anal. Chim. Acta 1053 (2019) 155–161. [195] L. Liu, M.R. Xie, F. Fang, Z.Y. Wu, Sensitive colorimetric detection of Cu2+ by simultaneous reaction and electrokinetic stacking on a paper-based analytical device, Microchem. J. 139 (2018) 357–362. [196] X. Sun, B. Li, A. Qi, C. Tian, J. Han, Y. Shi, B. Lin, L. Chen, Improved assessment of accuracy and performance using a rotational paper-based device for multiplexed detection of heavy metals, Talanta 178 (2018) 426–431. [197] G.H. Chen, W.Y. Chen, Y.C. Yen, C.W. Wang, H.T. Chang, C.F. Chen, Detection of mercury (II) ions using colorimetric gold nanoparticles on paper-based analytical devices, Anal. Chem. 86 (2014) 6843–6849. [198] N.T.N. Anh, A.D. Chowdhury, R.A. Doong, Highly sensitive and selective detection of mercury ions using N, S-codoped graphene quantum dots and its paper strip based sensing application in wastewater, Sens. Actuators B Chem. 252 (2017) 1169–1178. [199] S. Abbasi-Moayed, H. Golmohammadi, M.R. Hormozi-Nezhad, A nanopaper-based artificial tongue: a ratiometric fluorescent sensor array on bacterial nanocellulose for chemical discrimination applications, Nanoscale 10 (2018) 2492–2502. [200] L. Bu, J. Peng, H. Peng, S. Liu, H. Xiao, D. Liu, Z. Pan, Y. Chen, F. Chen, Y. He, Fluorescent carbon dots for the sensitive detection of Cr (VI) in aqueous media and their application in test papers, RSC Adv. 6 (2016) 95469–95475. [201] W. Alahmad, K. Uraisin, D. Nacapricha, T. Kaneta, A miniaturized chemiluminescence detection system for a microfluidic paper-based analytical device and its
[202] [203] [204] [205]
[206]
[207] [208] [209] [210]
[211] [212]
[213] [214] [215] [216] [217] [218] [219]
[220] [221] [222] [223] [224] [225]
[226] [227]
[228]
19
application to the determination of chromium (III), Anal. Methods 8 (2016) 5414–5420. S. Faham, G. Khayatian, H. Golmohammadi, R. Ghavami, A paper-based optical probe for chromium by using gold nanoparticles modified with 2, 2′-thiodiacetic acid and smartphone camera readout, Microchim. Acta 185 (2018) 374. H. Asano, Y. Shiraishi, Microfluidic paper-based analytical device for the determination of hexavalent chromium by photolithographic fabrication using a photomask printed with 3D printer, Anal. Sci. 34 (2018) 71–74. J.P. Devadhasan, J. Kim, A chemically functionalized paper-based microfluidic platform for multiplex heavy metal detection, Sens. Actuators B Chem. 273 (2018) 18–24. H. Asano, Y. Shiraishi, Development of paper-based microfluidic analytical device for iron assay using photomask printed with 3D printer for fabrication of hydrophilic and hydrophobic zones on paper by photolithography, Anal. Chim. Acta 883 (2015) 55–60. J.C. Hofstetter, J.B. Wydallis, G. Neymark, T.H. Reilly III, J. Harrington, C.S. Henry, Quantitative colorimetric paper analytical devices based on radial distance measurements for aqueous metal determination, Analyst 143 (2018) 3085–3090. W. Xu, X. Chen, S. Cai, J. Chen, Z. Xu, H. Jia, J. Chen, Superhydrophobic titania nanoparticles for fabrication of paper-based analytical devices: an example of heavy metals assays, Talanta 181 (2018) 333–339. J.J. Li, C.J. Hou, D.Q. Huo, C.H. Shen, X.G. Luo, H.B. Fa, M. Yang, J. Zhou, Detection of trace nickel ions with a colorimetric sensor based on indicator displacement mechanism, Sens. Actuators B Chem. 241 (2017) 1294–1302. S. Karita, T. Kaneta, Chelate titrations of Ca2+ and Mg2+ using microfluidic paperbased analytical devices, Anal. Chim. Acta 924 (2016) 60–67. M.A. Ostad, A. Hajinia, T. Heidari, A novel direct and cost effective method for fabricating paper-based microfluidic device by commercial eye pencil and its application for determining simultaneous calcium and magnesium, Microchem. J. 133 (2017) 545–550. H. Kudo, K. Yamada, D. Watanabe, K. Suzuki, D. Citterio, Based analytical device for zinc ion quantification in water samples with power-free analyte concentration, Micromachines 8 (2017) 127. X. Liu, Y. Yang, Q. Li, Z. Wang, X. Xing, Y. Wang, Portably colorimetric paper sensor based on ZnS quantum dots for semi-quantitative detection of Co2+ through the measurement of grey level, Sens. Actuators B Chem. 260 (2018) 1068–1075. Y.C. Liu, C.H. Hsu, B.J. Lu, P.Y. Lin, M.L. Ho, Determination of nitrite ions in environment analysis with a paper-based microfluidic device, Dalton Trans. 47 (2018) 14799–14807. T.M. Cardoso, P.T. Garcia, W.K. Coltro, Colorimetric determination of nitrite in clinical, food and environmental samples using microfluidic devices stamped in paper platforms, Anal. Methods 7 (2015) 7311–7317. F. Pena-Pereira, L. Villar-Blanco, I. Lavilla, C. Bendicho, Test for arsenic speciation in waters based on a paper-based analytical device with scanometric detection, Anal. Chim. Acta 1011 (2018) 1–10. P. Devi, A. Thakur, R.Y. Lai, S. Saini, R. Jain, P. Kumar, Progress in the materials for optical detection of arsenic in water, Trend Anal, Chem. 110 (2019) 97–115. M. Cuartero, G.A. Crespo, E. Bakker, Based thin-layer coulometric sensor for halide determination, Anal. Chem. 87 (2015) 1981–1990. A. Yakoh, P. Rattanarat, W. Siangproh, O. Chailapakul, Simple and selective paper-based colorimetric sensor for determination of chloride ion in environmental samples using label-free silver nanoprisms, Talanta 178 (2018) 134–140. N. Vasimalai, M.T. Fernández-Argüelles, B. Espiña, Detection of sulfide using mercapto tetrazine-protected fluorescent gold nanodots: preparation of paperbased testing kit for on-site monitoring, ACS Appl, Mater. Interfaces 10 (2018) 1634–1645. M.C. Díaz-Liñán, A.I. López-Lorente, S. Cárdenas, R. Lucena, Molecularly imprinted paper-based analytical device obtained by a polymerization-free synthesis, Sens. Actuators B Chem. 287 (2019) 138–146. F. Arduini, S. Cinti, V. Caratelli, L. Amendola, G. Palleschi, D. Moscone, Origami multiple paper-based electrochemical biosensors for pesticide detection, Biosens.Bioelectronics 126 (2019) 346–354. S. Cinti, D. Talarico, G. Palleschi, D. Moscone, F. Arduini, Novel reagentless paperbased screen-printed electrochemical sensor to detect phosphate, Anal. Chim. Acta 919 (2016) 78–84. J.F. da Silveira Petruci, P.C. Hauser, A.A. Cardoso, Colorimetric paper-based device for gaseous hydrogen cyanide quantification based on absorbance measurements, Sens. Actuators B Chem. 268 (2018) 392–397. M. Saraji, N. Bagheri, Based headspace extraction combined with digital image analysis for trace determination of cyanide in water samples, Sens. Actuators B Chem. 270 (2018) 28–34. M. Zarejousheghani, S. Schrader, M. Möder, T. Mayer, H. Borsdorf, Negative electrospray ionization ion mobility spectrometry combined with paper-based molecular imprinted polymer disks: a novel approach for rapid target screening of trace organic compounds in water samples, Talanta 190 (2018) 47–54. M.L. Scala-Benuzzi, J. Raba, G.J. Soler-Illia, R.J. Schneider, G.A. Messina, Novel electrochemical paper-based immunocapture assay for the quantitative determination of ethinylestradiol in water samples, Anal. Chem. 90 (2018) 4104–4111. M.L. Scala-Benuzzi, E.A. Takara, M. Alderete, G.J. Soler-Illia, R.J. Schneider, J. Raba, G.A. Messina, Ethinylestradiol quantification in drinking water sources using a fluorescent paper based immunosensor, Microchem. J. 141 (2018) 287–293. S.D. Alcaine, K. Law, S. Ho, A.J. Kinchla, D.A. Sela, S.R. Nugen, Bioengineering bacteriophages to enhance the sensitivity of phage amplification-based paper
Sensors & Actuators: B. Chemical 301 (2019) 126855
C.-T. Kung, et al. fluidic detection of bacteria, Biosens. Bioelectronics 82 (2016) 14–19. [229] S. Rengaraj, A. Cruz-Izquierdo, J.L. Scott, M. Di Lorenzo, Impedimetric paperbased biosensor for the detection of bacterial contamination in water, Sens. Actuators B Chem. 265 (2018) 50–58. [230] M. Rong, Y. Liang, D. Zhao, B. Chen, C. Pan, X. Deng, Y. Chen, J. He, A ratiometric fluorescence visual test paper for an anthrax biomarker based on functionalized manganese-doped carbon dots, Sens. Actuators B Chem. 265 (2018) 498–505. [231] T. Akyazi, A. Tudor, D. Diamond, L. Basabe-Desmonts, L. Florea, F. Benito-Lopez, Driving flows in microfluidic paper-based analytical devices with a cholinium based poly (ionic liquid) hydrogel, Sens. Actuators B Chem. 261 (2018) 372–378. [232] S.M. Tawfik, M. Sharipov, S. Kakhkhorov, M.R. Elmasry, Y.I. Lee, Multiple emitting amphiphilic conjugated polythiophenes‐coated CdTe QDs for picogram detection of trinitrophenol explosive and application using chitosan film and paper‐based sensor coupled with smartphone, Adv. Science (2019) 1801467. [233] L. Baptista‐Pires, J. Orozco, P. Guardia, A. Merkoçi, Architecting graphene oxide rolled‐up micromotors: a simple paper‐based manufacturing technology, Small 14 (2018) 1702746. [234] X. Weng, S. Neethirajan, Paper‐based microfluidic aptasensor for food safety, J. Food Saf. 38 (2018) e12412. [235] Y. Yao, C. Jiang, J. Ping, Flexible freestanding graphene paper-based potentiometric enzymatic aptasensor for ultrasensitive wireless detection of kanamycin, Biosens. Bioelectronics 123 (2019) 178–184. [236] Y. Yao, C. Jiang, J. Ping, Flexible freestanding graphene paper-based potentiometric enzymatic aptasensor for ultrasensitive wireless detection of kanamycin, Biosens. Bioelectronics 123 (2019) 178–184. [237] K.V. Ragavan, P. Egan, S. Neethirajan, Multi mimetic Graphene Palladium nanocomposite based colorimetric paper sensor for the detection of neurotransmitters, Sens. Actuators B Chem. 273 (2018) 1385–1394. [238] N.T.N. Anh, A.D. Chowdhury, R.A. Doong, Highly sensitive and selective detection of mercury ions using N, S-codoped graphene quantum dots and its paper strip based sensing application in wastewater, Sens. Actuators B Chem. 252 (2017) 1169–1178. [239] P. Teengam, W. Siangproh, A. Tuantranont, C.S. Henry, T. Vilaivan, O. Chailapakul, Electrochemical paper-based peptide nucleic acid biosensor for detecting human papillomavirus, Anal. Chim. Acta 952 (2017) 32–40. [240] L. Cao, C. Fang, R. Zeng, X. Zhao, F. Zhao, Y. Jiang, Z. Chen, A disposable paperbased microfluidic immunosensor based on reduced graphene oxide-tetraethylene pentamine/Au nanocomposite decorated carbon screen-printed electrodes, Sens. Actuators B Chem. 252 (2017) 44–54. [241] M.S. Khan, S.K. Misra, K. Dighe, Z. Wang, A.S. Schwartz-Duval, D. Sar, D. Pan, Electrically-receptive and thermally-responsive paper-based sensor chip for rapid detection of bacterial cells, Biosens. Bioelectronics 110 (2018) 132–140. [242] N. Ruecha, K. Shin, O. Chailapakul, N. Rodthongkum, Label-free paper-based electrochemical impedance immunosensor for human interferon gamma detection, Sens. Actuators B Chem. 279 (2019) 298–304. [243] R. Meelapsom, P. Jarujamrus, M. Amatatongchai, S. Chairam, C. Kulsing, W. Shen, Chromatic analysis by monitoring unmodified silver nanoparticles reduction ondouble layer microfluidic paper-based analytical devices for selective and sensitivedetermination of mercury(II), Talanta 155 (2016) 193–201. [244] N. Pourreza, H. Golmohammadi, S. Rastegarzadeh, Highly selective and portable chemosensor for mercury determination in water samples using curcumin
nanoparticles in a paper based analytical device, RSC Adv. 6 (2016) 69060–69066. [245] W.W. Chen, X.E. Fang, H. Li, H.M. Cao, J.L. Kong, A simple paper-based colorimetric device for rapid mercury(II) assay, Sci. Rep. 6 (2016) 7. [246] S.K. Patil, D. Das, A nanomolar detection of mercury (II) ion by a chemodosimetric rhodamine-based sensor in an aqueous medium: potential applications in real water samples and as paper strips Spectrochim, Acta A Mol. Biomol. Spectrosc. 210 (2019) 44–51. [247] M. Zhao, H. Li, W. Liu, W. Chu, Y. Chen, Paper-based laser induced fluorescence immunodevice combining with CdTe embedded silica nanoparticles signal enhancement strategy, Sens. Actuators B Chem. 242 (2017) 87–94. [248] Y. Yang, J. Wu, J. Deng, K. Yuan, X. Chen, N. Liu, T. Luan, Rapid and on-site analysis of amphetamine-type illicit drugs in whole blood and raw urine by slugflow microextraction coupled with paper spray mass spectrometry, Anal. Chim. Acta 1032 (2018) 75–82. [249] M. Yu, R. Wen, L. Jiang, S. Huang, Z. Fang, B. Chen, L. Wang, Rapid analysis of benzoic acid and vitamin C in beverages by paper spray mass spectrometry, Food Chem. 268 (2018) 411–415. [250] D. Kim, J. Lee, B. Kim, Optimization and application of paper-based spray ionization mass spectrometry for analysis of natural organic matter, Anal. Chem. 90 (2018) 12027–12034. Chia-Te Kung received the B.S. and M.S. degrees from the Department of Medicine and Public Health Institute, Kaohsiung Medical University, Kaohsiung, Taiwan, in 1991 and 2011, respectively. He has been with the Emergency Department, Kaohsiung Chang Gung Memorial Hospital, since 1991. He is currently an Associate Professor with the Department of Medicine, Chang Gung University. His specialties include emergency medicine, critical care medicine, microfluidics paper-based devices and their biomedical applications, and disaster medicine. Chih-Yao Hou received M.S. and Ph.D. degrees from the Department of Food Science from National Pingtung University of Science and Technology, Taiwan, in 2004 and 2008, respectively. He is currently an Assistant Professor in the Department of Seafood Science at National Kaohsiung University of Science and Technology. His current research involves food engineering, food protein chemistry, food inspection and analysis, and microfluidic paper-based devices and applications. Yao-Nan Wang received M.S. and Ph.D. degrees from the Department of Mechanical Engineering from National Cheng Kung University (NCKU), Taiwan, in 2003 and 2008, respectively. He is currently an Associate Professor in the Department of Vehicle Engineering at National Pingtung University of Science and Technology. His current research involves thermo-fluid engineering and integration of microdevices. Lung-Ming Fu received M.S. and Ph.D. degrees in Engineering Science from National Cheng Kung University (NCKU), Taiwan, in 1997 and 2001. He had his postdoc training in Department of Engineering Science at NCKU during 2002-2003. He is currently a Distinguished Professor of Engineering Science Department at National Cheng Kung University, Tainan, Taiwan. His research interests are in microfluidic systems, microfluidic paper-based devices and applications, MEMS fabrication technologies, microsensor and computational fluid dynamics.
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