Biogenic amines- and sulfides-responsive gold nanoparticles for real-time visual detection of raw meat, fish, crustaceans, and preserved meat

Biogenic amines- and sulfides-responsive gold nanoparticles for real-time visual detection of raw meat, fish, crustaceans, and preserved meat

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Journal Pre-proofs Biogenic amines- and sulfides-responsive gold nanoparticles for real-time visual detection of raw meat, fish, crustaceans, and preserved meat Cheuk-Fai CHOW PII: DOI: Reference:

S0308-8146(19)32046-1 https://doi.org/10.1016/j.foodchem.2019.125908 FOCH 125908

To appear in:

Food Chemistry

Received Date: Revised Date: Accepted Date:

29 May 2019 13 November 2019 13 November 2019

Please cite this article as: CHOW, C-F., Biogenic amines- and sulfides-responsive gold nanoparticles for real-time visual detection of raw meat, fish, crustaceans, and preserved meat, Food Chemistry (2019), doi: https://doi.org/ 10.1016/j.foodchem.2019.125908

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© 2019 Published by Elsevier Ltd.

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Biogenic

amines-

and

sulfides-responsive

gold

2

nanoparticles for real-time visual detection of raw meat,

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fish, crustaceans, and preserved meat

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Cheuk-Fai CHOW*

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Department of Science and Environmental Studies, The Education University of Hong Kong,

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10 Lo Ping Road, Tai Po, Hong Kong SAR, China

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*Email: [email protected]

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Abstract

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A colorimetric probe based on gold nanoparticles (AuNPs) which is sensitive to two important

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volatile biogenic markers, i.e., dimethyl sulfide and histamine, is developed to monitor the

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spoilage of raw meat, fish, crustaceans, and preserved meat. The colorimetric detection is

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attributed to the transformation of the non-aggregated form of AuNPs to its aggregated form

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upon binding of the biomarkers. The AuNPs enable the detection of dimethyl sulfide and

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histamine at limits of 0.5 and 0.035 μg/mL, respectively. Furthermore, the probe exhibits

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excellent selectivity for those markers in the presence of other volatiles commonly generated

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by spoiled real meat and seafood. A sequential and positive causative relationship is exhibited

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among the storage period, the total bacteria count, the DMS evolved, and the chemosensing

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signal generated. Thus, this probe serves as a nondestructive and cost-effective detector for the

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real-time monitoring of meat spoilage.

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Keywords: dimethyl sulfide, dimethyl disulfide, dimethyl trisulfide, histamine, chemosensing

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1. Introduction

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The explosive growth of food safety problems pushes us to search for a simple and accurate

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food monitoring system. Detection of volatile biogenic biomarkers released from food is a

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common strategy to determine food freshness and avoid food poisoning (WHO, Food Safety).

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Common approach to the quality control of meat and seafood is to monitor the levels of volatile

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biogenic sulfides and amines, respectively, they release (Alexandrakis, Brunton, Downey, &

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Scannell, 2012; Mikš-Krajnik, Yoon, & Yuk, 2015; Tománková, Borˇilová, Streinhauserová,

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& Gallas, 2012; Al-Attabi, D’arcy, & Deeth, 2009; Romano, Perello, deRevel, & Lonvaud-

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Funel, 2008). Research has demonstrated that dimethyl sulfide (DMS, CH3SCH3), dimethyl

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disulfide (DMSS, CH3SSCH3), and dimethyl trisulfide (DMSSS, CH3SSSCH3) levels in raw

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beef, pork, and poultry increase as the meat spoils (Lovestead & Bruno, 2010; Varlet &

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Fernandez, 2010; Isogal et al., 2009). Furthermore, histamine is a well-known biomarker for

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seafood monitoring (Scallan, Griffin, Angulo, Tauxe, & Hoekstra, 2011; Landete, de las Rivas,

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Marcobal, & Munoz, 2007; Vinci & Antonelli, 2002; Onal, 2007; Liu, Petty, Sazama, &

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Swager, 2015). For example, according to the U.S. Food and Drug Administration (FDA), the

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histamine level in fresh mackerel should not exceed 50 μg/g (FDA, 2004). Machiels (2003)

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and Jaffres (2011) used gas chromatography-mass spectrometry (GC-MS) to assess the degree

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of spoilage of fresh beef and shrimp by analyzing biogenic sulfides and amines levels

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respectively. Furthermore, the analysis of biogenic sulfides and amines recently described in

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the literature make use of molecular imprinting methods (Greene & Shimizu 2005), indicator-

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displacement assays (Chow, Lam & Wong, 2013; Chow, Ho, Sun, Lu, Wong, Tang, Gong,

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2017), and enzymatic techniques (Mertz & Zimmerman, 2003). However, although those

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analytical methods are precise and reasonably accurate, they are costly, require special

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procedures and conditions, and need highly specialized equipment (UV-vis spectrometer,

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spectrofluorometer, and GC-MS). Therefore, simple methods and technologies for monitoring

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the freshness of food products are essential.

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Nanotechnology has been starting to attract industrial and academic research attention as

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a means to address food freshness and food poisoning problems for three decades. Gold

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nanoparticles (AuNPs), silver nanoparticles (AgNPs), zinc oxide nanoparticles (ZnO-NPs), and

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titanium dioxide nanoparticles (TiO2-NPs) are often used as the active packaging materials to

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inhibit bacterial growth on food (Akbar & Anal, 2014; De Moura, Mattoso, & Zucolotto, 2012;

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El-Wakil, Hassan, Abou-Zeid, & Dufresne, 2015; Bumbudsanpharoke & Ko, 2015; Matteo,

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Alessandra, & Saverio, 2009; Liu, Lu, Huang, Li & Xu, 2018). Furthermore, nano-clay and

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bio-nano-composites, such as chitosan, carboxymethyl cellulose, starch, and cellophane, have

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been used as barriers to prevent the contact of oxygen and moisture with food (Youssef & El-

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Sayed, 2018). However, while these nano-technological approaches are proven to prevent food

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spoilage, there are only rare examples of nanotechnology being used to monitor food freshness

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(Ali, 2012; Chen, Zhou & Zhao, 2018; Liu, Lu, Huang, Li & Xu, 2018).

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Accordingly, in the current study, we applied AuNPs as a naked-eye colorimetric sensor

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for the detection of DMS, allowing us to monitor the freshness of foods readily (raw chicken,

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raw pork, raw beef, preserved raw chicken, preserved raw pork, preserved raw beef, raw

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salmon, raw tuna, raw toothfish, raw lobster, raw shrimp, and raw prawn). The basic principle

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of this technology is that free AuNPs, which initially present a red color, form grey-colored

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aggregates in the presence of DMS produced during food spoilage. Although AuNPs have been

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used in biology and biochemistry for the detection of sulfur-containing compounds such as

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cysteine, esterase, and DNA (Jongjinakool et al., 2014; Li et al., 2012; Li et al., 2014), no

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studies of AuNP are found (i) to determine DMS in real food samples and (ii) to correlate its

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sensing signal produced with the number of bacteria generated and concentration of the volatile

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biomarker generated.

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2. Experimental Section

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2.1 Materials and chemicals

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Potassium gold(III) chloride (KAuCl4), DMS (99%), and histamine were obtained from

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Aldrich (Steinheim, Germany). DMSS (99%) was obtained from Acros (Geel, Belgium).

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DMSSS (98%) was purchased from TCI (Tokyo, Japan). Dimethyl sulfoxide (DMSO, 99%)

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was purchased from Anaqua Chemicals Supply (Cleveland, USA). Potassium dihydrogen

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phosphate, trisodium citrate, and sodium borohydride (NaBH4) were purchased from

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Honeywell Riedel-de Haen (Seelze, Germany). Total plate count agar (tryptone glucose yeast

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agar) was purchased from Oxoid Ltd., (Basingstoke, Hampshire, England). The water used in

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all syntheses and spectroscopic titrations was deionized and sterilized.

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2.2 Synthesis and characterization

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2.2.1 Synthesis and characterization of AuNPs

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KAuCl4 (3 × 10-5 mol) and trisodium citrate (2 × 10-4 mol) were added to a conical flask

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containing 50 mL water. NaBH4 (9 × 10-5 mol) was then added, and the mixture was stirred

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under ambient conditions for 1 h. During the reaction, the color of the mixture changed from

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pale-yellow to deep-red (immediately after NaBH4 addition) and finally to red. The red solution

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was mixed with DMSO (33.33 mL) and then diluted with water to 100.00 mL in a volumetric

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flask. The mixture was allowed to stand overnight prior to titration experiments. The stability

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of AuNPs (82.5 μg/mL) in H2O/DMSO (2:1, v/v) was assessed by monitoring the UV-Vis

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absorption of the mixture at 520 nm over 400 h.

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2.2.2 Titration of the AuNP solution by various analytes

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Titrations of AuNP (82.5 μg/mL) against DMS, DMSS, DMSSS, histamine, acetic acid,

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triethylamine, ethylphenol, and phenol (0–50 μg/mL) in H2O/DMSO (2:1, v/v) were conducted

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under ambient conditions. The UV-Vis spectroscopic responses of the resulting solutions at

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520 nm were monitored.

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2.2.3 Response times of AuNP solutions towards DMS, DMSS, DMSSS, and histamine

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The response times of AuNP solutions (82.5 μg/mL) in H2O/DMSO (2:1, v/v) towards

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DMS (1.0 μg/mL), DMSS (0.8 μg/mL), DMSSS (0.8 μg/mL), and histamine (0.16 μg/mL)

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were assessed under ambient conditions by monitoring the UV-Vis absorptions at 520 and 670

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nm of the mixtures over time (0–25 h). The scanning frequency was 0.5 min per cycle.

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2.3 Analysis of real meat and seafood samples by (i) AuNP; (ii) GC-MS; and (iii) bacteria

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counts

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2.3.1 Sample processing

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Twelve different types of fresh meat in four categories, i.e., (i) raw chicken, pork, and beef,

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(ii) raw tuna, salmon, and toothfish, (iii) raw lobster, prawn, and shrimp, and (iv) preserved

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raw chicken, pork, and beef, were tested in this study. Each category was randomly purchased

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from a supermarket. All the samples purchased were skinless and boneless. For the lobster,

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prawn, and shrimp, their shells were aseptically removed in the laboratory. All the batches were

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brought to the laboratory in an ice chest and analyzed within 4 h. Seven kinds of meat including

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the raw chicken, pork, beef, preserved raw chicken, preserved raw pork, preserved raw beef,

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and raw shrimp originated from China; while the raw lobster came from Canada; the raw prawn

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came from Malaysia, raw tuna originated from Philippine, raw salmon and toothfish came from

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Norway and France respectively. Each batch was cut into small portions (6(L)×4(W)×2(H) cm3)

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for the experiments. 200-mL microwave boxes with lids, plastic containers, and thermoplastic

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polyurethane films were sterilized in an autoclave and/or under UV irradiation.

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2.3.2 Chemosensing by AuNP

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6 × 100-g meat samples were used to conduct the sensing experiment, and the whole set

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of experiments was repeated three times. In general, six 200-mL microwave boxes with each

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containing the 100-g meat sample and a plastic container with 3.0 mL of AuNP solution (82.5

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μg/mL) capped by a thermoplastic polyurethane film were sealed and kept in a refrigerator at

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4 °C for 0–16 days. The headspace left in the box was around 1/3 of its volume. After storage

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at a particular day, the color of AuNP solutions was analyzed by using the pentone color chart

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(Red: Pantone 1979c, Purple: Pantone 242c, Grey: Pantone 5285c; and Pale Grey: Pantone

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5305c) and UV-Vis spectroscopy. GC-MS was used to determine the amount of DMS

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generated and diffused in the solutions. The meat samples were tested for total bacteria count.

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Three independent tests were conducted for each type of meat.

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2.3.3 GC-MS analysis

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GC-MS experiments were carried out on a Hewlett-Packard 6890 GC system equipped

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with a 5973 mass-selective detector. Injections were performed with an HP 7683 autosampler.

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Helium was used as the carrier gas at a flow rate of 1 mL/min. The separation was performed

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with an HP-5MS capillary column (30 m × 0.25 mm, 0.25 µm). The GC conditions were a 10:1

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injection split with the column temperature starting at 40 °C (1 min) and then increasing at

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20 °C/min up to 100 °C (1 min), 20 °C/min up to 180 °C (1 min), 10 °C/min up to 230 °C, and

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40 °C/min up to 280 °C (held for 1 min). The injection temperature was 280 °C, and the transfer

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line temperature was 280 °C. The ionizing voltage was 70 eV, and the source temperature was

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250 °C. The mass-selective detector was operated in full scan mode with an m/z range of 50–

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550. The solvent delay was 1 min.

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2.3.4 Microbiological analysis

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The total aerobic bacteria counts for the meat samples were obtained using the pour plate

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method as defined by the National Standard of China (GB 4789.2-2016). The meat (25 g) was

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blended with KH2PO4 buffer (225 mL) for 2 min to form a 1:10 mixture. From this solution,

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serial dilutions from 1:102 to 1:107 were prepared. A 1-mL aliquot of the dilution was used as

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the bacteria group, and 1 mL of the KH2PO4 buffer alone was used as the control. The sample

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and control were added to separate Petri dishes (90 mm diameter). Total plate count agar (20

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mL) was then poured into the dishes, which were rotated to mix the solutions and agar evenly.

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The dishes having 30–300 colony-forming units (CFUs) were selected for conducting total

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plate counts.

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2.4 Statistical analysis

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The linear regression model was used to study the relationship among the storage period,

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the total bacteria count, the DMS evolved, and the sensing signal generated from AuNP for

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raw beef in 4 °C by the package SPSS 25 (Starkey, Geesink, Oddy, & Hopkins, 2015; Starkey,

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Geesink, van de Ven, & Hopkins, 2017). The regression coefficients, standard errors, and

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probability level were evaluated from the models, and a sequential model was validated to test

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the causative relationship between those factors.

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3. Results and Discussion

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3.1 Characterization of AuNPs

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3.1.1 Synthesis and Morphology of AuNPs

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AuNPs were synthesized by reacting to a KAuIIICl4 complex with three molar equivalents

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of NaBH4 as a reducing agent and 6.7 molar equivalents of trisodium citrate as the capping

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agent. Aqueous DMSO, i.e., H2O/DMSO (2:1, v/v) was used as the medium as it stabilizes

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AuNPs and does not freeze at low temperature (67% hydration of DMSO decreases its melting

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point from 18 to -18 °C). Figure 1a shows a transmission electron microscopy (TEM) image

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of disaggregated AuNPs with diameters of 12 ± 5 nm. Figure 1b shows a TEM image of the

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DMS-induced aggregate form of the sodium-citrate-capped AuNPs.

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3.1.2 Chemosensing properties of AuNPs

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Titrations of AuNP solutions (82.5 μg/mL) against biogenic sulfides and amines were

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conducted under ambient conditions in aqueous DMSO. Figures 2a–b show the UV-Vis

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responses of AuNP solutions towards DMS and histamine, respectively. As the more biogenic

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compound is added, the absorption of the AuNP solution at 520 nm decreases while that at 670

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nm increases. The color of test solution changes from red (Pantone 1979c) to purple (Pantone

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242c) and finally to pale gray (Pantone 5305c) (Figures 2a–b, insets). Figures S1–2 show the

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UV-Vis spectroscopic changes of AuNP solutions in response to increasing amounts of two

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other common biogenic sulfides, DMSS and DMSSS. The AuNP method detection limits for

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DMS, DMSS, DMSSS, and histamine were found to be 0.5, 0.2, 0.25, and 0.035 μg/mL,

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respectively. Thus, the results confirm that biogenic sulfides and amines induce the aggregation

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of free AuNPs, resulting in UV-Vis spectroscopic changes.

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Figure 2c shows the results obtained from the spectroscopic titrations of AuNP solutions

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(82.5 μg/mL) with the analytes DMS, DMSS, DMSSS, histamine, acetic acid, triethylamine,

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ethylphenol, and phenol (0–50 μg/mL). Of these analytes, only DMS, DMSS, DMSSS, and

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histamine induce UV-Vis responses at 520 nm in the AuNP solutions. The naked-eye detection

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limits for DMS, DMSS, DMSSS, and histamine were found to be 1.5, 0.325, 0.40, and 0.075

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μg/mL, respectively (Table S1). Figure S3 shows the response time for the above detections.

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In the presence of DMSS (0.8 μg/mL), the absorption of the AuNP solution (82.5 μg/mL) at

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520 nm decreases with increasing reaction time while that at 670 nm increases in the first 5

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min and then starts to drop until becoming steady at 1,400 min.

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3.2. Analysis of real meat and seafood samples by (i) AuNP; (ii) GC-MS; and (iii) bacteria

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counts

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Chemosensing by AuNP solutions for real samples was studied using four different classes

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of samples (raw meat, fish, crustaceans, and preserved raw meat) during storage at 4 °C for 16

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days. The AuNP solutions were assessed in terms of their color changes and UV-Vis

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spectroscopic signals (A0-A/A0 at 520 nm). The real samples were assessed in terms of their

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total bacteria counts and the amount of DMS generated.

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Figures 3a–b show that, for raw beef stored at 4 °C, the total bacteria count, the DMS

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generated, and the UV-Vis spectroscopic signal (A0-A/A0 at 520 nm) of the AuNP solution

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increase with the increasing number of storage days. Figure 3c shows the color changes

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observed for the AuNP solution with increasing storage time for raw beef. The color of AuNP

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solution gradually changes from its original red to purple then to grey-purple from day 1 to 15.

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Figures S4–S14 show the results of the same experimental setup for raw chicken, pork,

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preserved beef, preserved chicken, preserved pork, salmon, tuna, toothfish, lobster, shrimp, and

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prawn, respectively, stored at 4 °C in terms of total bacteria count and UV-Vis signal (A0-A/A0

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at 520 nm). All show a similar sequential and positive causative relationship.

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The microbiological criteria for food are commonly used as indicators of food quality. In

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the current study, the foods were divided into satisfactory, acceptable, and unsatisfactory

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classes according to their bacterial colony counts. The satisfactory class is microbiologically

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safe, the acceptable level exhibits the potential to cause public health problems, and the

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unsatisfactory level necessitates medical attention for the consumer (Centre for Food Safety,

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2007 and 2014). Table S2 shows the hygiene quality (total plate counts) for different categories

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of food. Figures 4a–b show the relationship between the UV-Vis spectroscopic signals (A0-

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A/A0 at 520 nm) generated by the AuNP detector solutions with respect to the total bacteria

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counts for the raw and preserved raw meat, respectively.

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3.3. Statistic relationship among the sensing signal, storage period, bacteria growth, and DMS

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generated.

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The statistical relationships among those variables were analyzed by the linear regression

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model fitted using the package SPSS 25 (Starkey, Geesink, Oddy, & Hopkins, 2015; Starkey,

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Geesink, van de Ven, & Hopkins, 2017). We postulated that the relationship is either in a

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multivariate or sequential way. Two different models were used to identify their relationship.

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The models are as follows:

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Model 1. Sensing Signal = Storage period + Bacteria growth + DMS generated Model 2. Storage day → Bacteria growth → DMS generated → Sensing signal Model 2.1 Bacteria growth = Storage period Model 2.2 DMS generated = Bacteria growth Model 2.3 Sensing Signal = DMS generated

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Among all the models proposed, Models 2.1–2.3 were statistical significant with P = 0.000

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for their corresponding variables (Table 1). All the positive coefficients in Models 2.1–2.3

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revealed the positive causative relationships between the factors. R2 values of Models 2.1–2.3

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were found as 0.970–0.986. While the Model 1 was statistically insignificance (P > 0.05). It is

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believed that the factors tested in the Model 2 are in a sequential and positive causative

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relationship (the equations of Models 2.1–2.3 are as follows, respectively, Bacteria growth =

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0.253 × Storage period + 4.886; DMS generated = 2.571 × Bacteria growth - 13.432; and

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Sensing Signal = 0.042 × DMS generated + 0.022).

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Although beef, chicken, and pork are different kinds of meat, they show a similar

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relationship between their total bacteria counts and AuNP chemosensing responses. With

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increasing total bacteria count found in the meat (raw and preserved raw), the sensing signal

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generated by the AuNP increases. The signal responses for the raw meat are 0.075, 0.15, and

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0.26 when the total bacteria counts are 106, 107, and 108, respectively. The signal responses

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from the preserved raw meat are 0, 0.1, and 0.25 when the total bacteria counts are 106, 107,

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and 108, respectively. According to food safety standards, raw meat and meat mixed with

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dressings, dips, and pastes are classified as unsatisfactory when the CFU is higher than 107.

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Thus, response signals (A0-A/A0 at 520 nm) of >0.15 and >0.1 can be used as alarm values for

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the spoilage of raw and preserved raw meat, respectively.

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Figures 4c–d demonstrate the correlations between the total bacteria counts and AuNP

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detector UV-Vis signals (A0-A/A0 at 520 nm) for raw fish and crustaceans, respectively.

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Salmon, tuna, and toothfish are representative examples of sea fish, while lobster, shrimp, and

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prawn are crustaceans. All results present a positive relationship between total bacteria count

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and AuNP chemosensing response. The signals from the raw fish are 0.15, 0.45, and 0.95 when

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their total bacteria counts are 106, 107, and 108, respectively. The signals from the crustaceans

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are 0.2, 0.35, and 0.7 when their total bacteria counts are 106, 107, and 108, respectively. The

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higher levels of biogenic amines were found as the reason for the larger sensing signal response

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for the fish and crustaceans compared to those for the meat samples (Cohen et al., 2015;

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Odeyemi et al., 2018). According to food safety standards, raw seafood, including sushi,

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sashimi, raw ready-to-eat fish, and crustaceans, are classified as unsatisfactory when the CFU

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is higher than 107. Thus, UV-Vis signals of >0.45 and >0.35 can be used as alarms for the

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spoilage of raw fish and crustaceans, respectively.

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4. Conclusions

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AuNPs were successfully synthesized, and their sensing properties toward various volatile

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biogenic compounds (VBCs) were evaluated. The results indicated that AuNPs are highly

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stable in a 2:1 H2O/DMSO mixture and that their colorimetric response is selective for DMS,

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DMSS, DMSSS, and histamine but not acetic acid, trimethylamine, ethylphenol, and phenol.

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The limits of detection for DMS, DMSS, DMSSS, and histamine are 0.5, 0.2, 0.25, and 0.035

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μg/mL, respectively. Furthermore, naked-eye detection limits for these four VBCs using the

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developed probe are 1.5, 0.325, 0.4, and 0.075 μg/mL.

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The AuNP solution was applied to the detection of VBCs from 12 different raw meat

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samples stored at 4 °C, and a strong correlation between their bacteria counts and AuNP

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sensing signal was observed. AuNP solution UV-Vis signals (A0-A/A0 at 520 nm) of 0.15, 0.1,

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0.45, and 0.35 were found to represent alarm values for dangerous spoilage levels (i.e., CFUs

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of 107) in raw meat, preserved raw meat, raw fish and raw crustaceans, respectively.

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Acknowledgments

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This work was funded by Grants from the Innovation Technology Commission of Hong Kong

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SAR (ITS/251/16FX).

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Conflicts of interest

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The authors declare no conflicts of interest.

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Table 1. The statistical relationships among the storage period, the bacteria growth, the amount

406

of DMS evolved, and the color changes of the AuNP sensor for the freshness of raw beef

407

(regression coefficients, standard errors, and probability level).

408

409

Model 1a Intercept Storage period Bacteria DMS

Coefficient 0.414 0.013 -0.078 0.053

Std. error 0.22 0.008 0.043 0.013

P-value 0.2 0.267 0.211 0.06

Model 2.1b Intercept Storage period

Coefficient 4.886 0.253

Std. error 0.198 0.022

P-value 0.000 0.000

Model 2.2c Intercept Bacteria growth

Coefficient -13.432 2.571

Std. error 1.408 0.208

P-value 0.001 0.000

Model 2.3d Coefficient Std. error P-value Intercept 0.022 0.013 0.167 DMS generated 0.042 0.003 0.000 aR2 = 0.995; bR2 = 0.970; cR2 = 0.975; dR2 = 0.986

21

410 411

Figure 1. TEM images of (a) the non-aggregated form of sodium-citrate-capped AuNPs, and

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(b) the DMS-induced aggregated form of the sodium-citrate-capped AuNPs.

22

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Figure 2. UV-Vis spectroscopic titration results and (insets) naked-eyed detectable responses

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of AuNP solutions (82.5 μg/mL) to (a) DMS (0–2.5 μg/mL) and (b) histamine (0–0.12 μg/mL).

416

(c) Responses of AuNP solutions (82.5 μg/mL) to DMS, DMSS, DMSSS, histamine, acetic

417

acid, triethylamine, ethylphenol and phenol (0–50 μg/mL). All titrations were conducted under

418

ambient conditions in H2O/DMSO (2:1, v/v). 23

419 420

Figure 3. Total bacteria count (—●—) and (a) UV-Vis signals (A0-A/A0 at 520 nm) of AuNP

421

solutions (—▲—), (b) DMS generated (——) by raw beef vs. storage time (4 °C), and (c)

422

naked-eyed-detectable responses of AuNP solutions (82.5 μg/mL) with storage time for raw

423

beef (4°C). The error bars are the standard errors of the means from three independent

424

experiments. 24

425 426 427

Figure 4. UV-Vis signals (A0-A /A0 at 520 nm) for AuNP solutions generated with respect to

428

total bacteria count in (a) raw chicken, pork, and beef, and (b) preserved raw chicken, pork,

429

and beef (in BBQ sauce), (c) raw salmon, tuna, and toothfish, and (d) raw lobster, shrimp, and

430

prawn. The error bars are the standard errors of the means from three independent experiments.

431 432 433

25

Supporting information

434 435 436

Biogenic

amines-

and

sulfides-responsive

gold

437

nanoparticles for real-time visual detection of raw meat,

438

fish, crustaceans, and preserved meat

439 440

Cheuk-Fai CHOW*

441 442

Department of Science and Environmental Studies, The Education University of Hong Kong,

443

10 Lo Ping Road, Tai Po, Hong Kong SAR, China

444

*Email: [email protected]

445 446

26

447

Table S1. The naked-eye detection limits of the AuNP solution to DMS, DMSS, DMSSS, and

448

histamine in various H2O:DMSO mixture. Naked

eye DMS

DMSS

DMSSS

Histamine

detection limit H2O: DMSO ratio 7:3

0.5 μg/mL

0.25 μg/mL

0.25 μg/mL

----

6.67:3.33

1.5 μg/mL

0.325 μg/mL

0.4 μg/mL

0.075 μg/mL

6:4

2.5 μg/mL

0.5 μg/mL

1 μg/mL

----

449 450

27

451

Table S2. Classification of Microbiological Quality Food category

Examples

Results (CFU/g) Satisfactory

Extended

shelf Modified

life food products packaging

atmosphere <106 (MAP)

requiring

vacuum-packed

refrigeration*

products,

e.g.,

Acceptable

Unsatisfactory

106-<108

≥108

106-<107

≥107

or

beef,

pork, chicken, fish, fruit, and vegetables Raw ready-to-eat Sushi, sashimi, smoked <106 meat

and

fish, salmon, etc.

cold smoked fish* 452

* Centre for Food Safety, 2014

28

453 454 455

Figure S1. (a) UV-Vis spectroscopic titrations and (b) naked eyed responses of AuNP solution

456

(82.5 μg/mL) by DMSS (0–1.25 μg/mL). The studies were conducted at the ambient conditions

457

in H2O:DMSO mixture (vol:vol 2:1).

29

458 459 460

Figure S2. (a) UV-Vis spectroscopic titrations and (b) naked eyed responses of AuNP solution

461

(82.5 μg/mL) by DMSSS (0–1.25 μg/mL). The studies were conducted at the ambient

462

conditions in H2O:DMSO mixture (vol:vol 2:1).

30

463 464

Figure S3. The UV-Vis spectroscopic responses, A/A0 520 nm () and 670 nm (◄), of the

465

AuNP solution in the presence of DMSS (0.8 μg/mL) with respect to time. The reaction was

466

conducted at the ambient conditions in H2O:DMSO mixture (vol:vol 2:1).

31

467 468 469

Figure S4. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

470

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw chicken with respect

471

to the storage day (4 ºC) (——). The error bars are the standard errors of the means from

472

three independent experiments.

473

474 475 476

Figure S5. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

477

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw pork with respect

478

to the storage day (4 ºC) (——). The error bars are the standard errors of the means from

479

three independent experiments.

32

480 481 482

Figure S6. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

483

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw preserved beef

484

(BBQ sauce) with respect to the storage day (4ºC) (——). The error bars are the standard

485

errors of the means from three independent experiments.

486

487 488 489

Figure S7. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

490

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw preserved chicken

491

(BBQ sauce) with respect to the storage day (4ºC) (——). The error bars are the standard

492

errors of the means from three independent experiments.

33

493 494

Figure S8. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

495

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw preserved pork

496

(BBQ sauce) with respect to the storage day (4ºC) (——). The error bars are the standard

497

errors of the means from three independent experiments.

498

499 500 501

Figure S9. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

502

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw salmon fish with

503

respect to the storage day (4ºC) (——). The error bars are the standard errors of the means

504

from three independent experiments.

34

505 506 507

Figure S10. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

508

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw tuna fish with

509

respect to the storage day (4ºC) (——). The error bars are the standard errors of the means

510

from three independent experiments.

511

512 513 514

Figure S11. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

515

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw toothfish with

516

respect to the storage day (4ºC) (——). The error bars are the standard errors of the means

517

from three independent experiments.

35

518 519 520

Figure S12. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

521

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw lobster with respect

522

to the storage day (4ºC) (——). The error bars are the standard errors of the means from

523

three independent experiments.

524

525 526 527

Figure S13. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

528

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw shrimp with respect

529

to the storage day (4ºC) (——). The error bars are the standard errors of the means from

530

three independent experiments.

36

531 532

Figure S14. Total bacteria count (—●—) and (a) UV-Vis spectroscopic signals (A0-A /A0 at

533

520 nm) of the AuNP solutions (—▲—) and (b) DMS generated from raw prawn with respect

534

to the storage day (4ºC) (——). The error bars are the standard errors of the means from

535

three independent experiments.

536 537 538 539 540 541 542

Highlights    

A novel AuNP-based sensor for meat/fish spoilage is developed The sensor detects dimethyl sulfide at 0.5 ppm and histamine at 0.035 ppm The sensor exhibits excellent selectivity for the markers of interest A sequential and positive causative statistic model of the detection is established

543 544 545

Declaration of interests

546 547 548

☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

549 550 551

☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:

37

552 553 554 555 556 557

Author Contributions Section

558 559

Biogenic amines- and sulfides-responsive gold nanoparticles for real-time visual detection of

560

raw meat, fish, crustaceans, and preserved meat

561 562

Cheuk-Fai CHOW*

563

Department of Science and Environmental Studies, The Education University of Hong Kong,

564

10 Lo Ping Road, Tai Po, Hong Kong SAR, China

565

*Email: [email protected]

566

567

Chow C.F. is the sole author of this manuscript. He designed the study, wrote the article, and

568

made the final approval of the version to be submitted.

569 570 571

38