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Changes in physicochemical properties of corn starch upon modifications by atmospheric pressure plasma jet
Accepted Manuscript Changes in physicochemical properties of corn starch upon modifications by atmospheric pressure plasma jet Tsung-Yen Wu, Chih-Ren Chang, Tsai-Ju Chang, Yu-Ju Chang, Ying Liew, Chi-Fai Chau PII: DOI: Reference:
S0308-8146(19)30111-6 https://doi.org/10.1016/j.foodchem.2019.01.043 FOCH 24138
To appear in:
Food Chemistry
Received Date: Revised Date: Accepted Date:
1 October 2018 19 December 2018 4 January 2019
Please cite this article as: Wu, T-Y., Chang, C-R., Chang, T-J., Chang, Y-J., Liew, Y., Chau, C-F., Changes in physicochemical properties of corn starch upon modifications by atmospheric pressure plasma jet, Food Chemistry (2019), doi: https://doi.org/10.1016/j.foodchem.2019.01.043
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Changes in physicochemical properties of corn starch upon
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modifications by atmospheric pressure plasma jet
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Tsung-Yen WUa, Chih-Ren CHANGb,c, Tsai-Ju CHANGb, Yu-Ju CHANGb, Ying LIEWb, and Chi-
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Fai CHAUb,*
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a
Agricultural Chemistry Division, Taiwan Agricultural Research Institute, Council of Agriculture,
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No.189, Zhongzheng Rd., Wufeng Dist., Taichung 41362, Taiwan
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b
Department of Food Science and Biotechnology, National Chung Hsing University, 145 Xingda
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Road, Taichung 40227, Taiwan c
Department of Traditional Chinese Medicine, Puli Branch of Taichung Veterans General Hospital, No.1, Rongguang Rd., Puli Township, Nantou County 545, Taiwan
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*Corresponding authors. Department of Food Science and Biotechnology, National Chung Hsing
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University, 145 Xingda Road, Taichung 40227, Taiwan
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E-mail address: [email protected] (C.-F. Chau)
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Telephone: +886-4-22852420
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Fax: +886-4-22876211
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Running title: Modifications of corn starch by employing atmospheric pressure plasma jet
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1
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Abstract
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The influences of atmospheric pressure plasma jet on different physicochemical properties of
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corn starch were evaluated after treated with the plasma jet (30 min) at different strengths (400W-
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800W). Our results demonstrated that residual aging effects of plasma on starch could be eliminated
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by washing the treated samples with distilled water at a ratio of 1:30, w/v.
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treatments, significant (p < 0.05) reductions in pasting properties including peak viscosity, final
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viscosity, and setback of starch samples (up to -87.1%, -92.0%, and -93.3%, respectively) were
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observed with increasing plasma intensity.
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paste clarity of starch sample.
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etching resulted in some physical changes on starch granules.
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physicochemical properties of corn starch by employing the plasma jet treatment might be useful in
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food applications requiring starch ingredients of low viscosity and high paste clarity.
After plasma and washing
Apparently, plasma jet could increase the solubility and
Surface morphological characterization illustrated that plasma Modifications in these
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Keywords: corn starch, atmospheric pressure plasma jet, physicochemical property, starch
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modification
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2
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1. Introduction Plasma is known as the fourth state of matter, which can be divided into high temperature and
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low temperature plasma.
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Atmospheric pressure non-thermal plasma can be generated at room temperature (290-300 K) without
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any quenching.
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applicability on some thermosensitive compounds, lower cost, and an increase in treatment efficiency
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(Nehra et al., 2008; Misra et al., 2011).
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The latter is further subdivided into thermal and non-thermal plasma.
The advantages of this non-thermal plasma in food applications might include its
Starch is one of the most widely used biopolymers in various industries, such as stabilizers and
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thickeners in food, textile, paper, and pharmaceutical industry (Thirumdas et al., 2017a).
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wider applications of starches, different chemical, physical, and enzymatic modifications were
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needed to improve their physicochemical properties (Colussi et al., 2014).
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be considered as a physical approach for starch modification. It generated different types of reactive
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species which interacted with starches and induced chemical changes to develop novel starch
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functionalities (Zhu, 2017).
To explore
Plasma technology could
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Interactions between plasma and starch would modify starch molecules through several
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mechanisms, such as cross-linking, depolymerization, and plasma etching (Morent et al., 2011).
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Different reactive species generated by plasma might lead to alterations in structures or some
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physicochemical parameters (e.g. swelling, solubility, and viscosity) of starch molecules.
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effects of plasma treatment on starches depended on several factors, including apparatus types,
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treatment conditions (feed gas, power input, and exposure time), and also the type and composition
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of starch (Zhu, 2017).
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The
In view of the advantages like simple construction, easy adoption, and high handling efficiency,
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the uses of atmospheric pressure air plasma jet has been exploited in a diversity of food research.
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this study, corn starch samples were treated with gases produced by an air plasma jet at different
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strengths.
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and compared.
In
Changes in different physicochemical properties of the treated samples were evaluated Potential applications of the air plasma jet on the modifications of corn starch were 3
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also discussed.
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2. Materials and methods
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2.1. Air plasma jet treatment
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A schematic diagram of the experimental setup is shown in Figure 1.
In this study, the input
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powers for generating cold plasma were 400W, 600W, and 800W.
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contained 73% amylopectin and 27% amylose was purchased from Sigma-Aldrich, Co. (St. Louis,
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MO, USA).
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height of 476 mm) filled with plasma gases generated from air plasma jet (SAP003X, Creating Nano
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Technologies, Inc., Taiwan) and held for 30 min.
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the treated starch samples were immediately washed with distilled water at different ratios (1:15 and
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1:30, w/v) to eliminate the residual aging effects of plasma on starch.
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centrifuged at 4000×g for 5 min and then dried in an oven at 40°C for 24 h.
Corn starch (S-4126) which
This native corn starch was placed in a reaction chamber (diameter of 295 mm and
After reacted with plasma gases in the chamber,
The starch suspension was
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To determine a proper starch-to-water ratio for washing to cease the residual aging effect of
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plasma, changes in the viscosity of treated samples were analyzed at days 0, 1, and 7 according to the
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methods as described by Wu et al. (2018) with slight modifications.
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referred to the sample analysis conducted immediately after washing and drying.
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referred to the analyses of washed samples after a storage for 24 hours and 7 days, respectively.
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set of controlled observations was also performed on the starch samples without washing after the
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plasma treatment.
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2.2. Determination of pasting properties
More specifically, day 0 Day 1 and day 7 A
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Pasting properties of corn starch samples were determined by the methods described by Wu et
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al. (2018) with slight modifications, and measured with a Rapid Visco Analyser (Model RVA-Super
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3, Newport Scientific Pty Ltd., NSW, Australia), which was controlled by the Thermocline software
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(version 2.3, Newport Scientific Pty Ltd., NSW, Australia).
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mL of distilled water in a canister.
Starch sample (3 g) was mixed with 25
The mixture was equilibrated at 50°C for 1 min, heated to 95°C 4
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at a rate of 12.2°C per min.
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50°C at a rate of 11.8°C per min and maintained at 50°C for 2 min.
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viscosity during pasting), trough viscosity (minimum viscosity at 95°C), breakdown (difference
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between the peak viscosity and trough viscosity), final viscosity, setback (difference between the final
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viscosity and trough viscosity) and pasting temperature were recorded.
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expressed by centipoise (cP).
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2.3. Determination of swelling power and water soluble index
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Sample was then held at 95°C for 2.5 min, followed by a cooling to
The units of viscosity were
The swelling power and water soluble index of starch samples were determined by the methods
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described by Li and Yeh (2001) with slight modifications.
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at 95°C for 30 min with intermittent shaking.
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an iced water bath.
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supernatant was dried in an air oven at 100°C to constant weight (W1).
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The peak viscosity (maximum
Starch suspension (2%, w/v) was heated
The suspension was cooled to room temperature in
After centrifuged at 8000×g for 20 min, the precipitate was weighed (WS).
The water soluble index and
swelling power were calculated using the following equations:
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Water soluble index (%) = [W1/weight of starch sample] × 100
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Swelling power (g/g) = WS/[weight of starch sample × (100% - water soluble index%)]
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The
2.4. Determination of starch paste clarity
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Clarity of starch paste was determined according to the methods of Wongsagonsup et al. (2014).
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Starch paste solution (1%, w/v) was prepared by heating starch sample in distilled water at 95°C for
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30 min, shaken thoroughly every 5 min, followed by a cooling to room temperature.
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of light transmittance (%T) at 650 nm was determined spectrophotometrically against distilled water.
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2.5. Morphological characterization
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The percentage
Optical and polarized light micrographs of corn starch samples were determined by Nikon
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microscope (Optiphot 2-Pol, Nikon, Tokyo, Japan) equipped with a polarizer.
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micrographs were taken with a tabletop scanning electron microscope (SEM; TM-1000, Hitachi,
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Tokyo, Japan).
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sputter coated with gold powder (at 2 mbar for 3 minutes) prior to SEM observation.
Scanning electron
Samples were mounted on a specimen holder using double-sided sticky tape and
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2.6. Statistical analysis Experimental results were statistically analyzed using the SPSS statistics program (version 20.0;
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SPSS, Armonk, NY, USA).
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multiple range test to compare mean values.
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0.05.
Analysis of variance (ANOVA) was performed using Duncan’s Statistical significance difference was defined at p <
The data presented are means of three replicates.
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3. Results and discussion
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3.1. Plasma treatment
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Aging effects and its subsequent surface modification were common phenomenon in polymers
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after plasma treatment.
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polymers over the storage period were usual.
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plasma oxidation and surface adaptation.
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Hasnain, 2014; Thirumdas et al., 2017a) which involved a continuous reaction of high-energy active
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substances (residual free radicals) produced by plasma and atmospheric oxygen.
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induce the formation of reactive oxygen and nitrogen species, as well as many unstable polar
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functional groups on the polymer surface.
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would be diminished due to the alteration in interfacial properties by a mechanism called surface
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adaptation (Siow et al. 2006).
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Changes in chemical compositions and characteristics of the treated The aging effect was basically attributed to post-
Oxidation was in fact a depolymerization process (Ali &
Plasma might
However, it was interesting that these functional groups
In Figure 2, the corn starch samples were first treated by the highest output (800W) of the power
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supply.
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(day 0), RVA analyses showed that the viscosity of treated samples dropped dramatically after the
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first 24 hours (day 1) and even became null after 7 days of storage.
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in viscosity was partly attributed to the aging effects of the residual reactive species being trapped in
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the treated starch samples as well as the instability of polar functional groups.
As compared with the initial viscosity measured immediately after the plasma treatment
It was inferred that the decrease
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In this study, the treated samples were washed with distilled water at different ratios with the
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purpose to remove the residual reactive species generated by the air plasma jet since the reactive 6
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species formed during plasma treatment dissolved readily in water (Thirumdas et al., 2018).
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3 (A) illustrates that washing the samples with distilled water at a ratio of 1:15 (w/v) could slightly
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mitigate the instability and reduction of viscosity during storage.
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the samples with a relatively larger amount of distilled water (at 1:30, w/v) was more effective in
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resolving the loss in viscosity and improving the stability of the plasma-treated samples.
Figure
As shown in Figure 3 (B), washing
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On the basis of these findings, the starch samples to be used in the other experiments of this
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study would be prepared by reacting with plasma at different strengths (400W, 600W, and 800W),
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followed by washing with an optimal amount of distilled water (at 1:30, w/v) and drying for further
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uses.
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3.2. Pasting properties
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Table 1 summarizes the pasting properties of native corn starch (control) and the other starch
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samples after the plasma treatment and subsequent washing.
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final viscosity of the starch samples decreased significantly (p < 0.05) with an increase in plasma
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intensity.
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dropping from 3181 cP (native) to 2793 cP (400W).
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significant reduction (p < 0.05) of viscosity down to 1451 cP (-54.4%) and 410 cP (-87.1%),
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respectively, were observed.
Peak viscosity, trough viscosity, and
With the plasma intensity at 400W, peak viscosity decreased (p < 0.05) by -12.2%, At higher intensities (600W and 800W), a more
157
After the plasma treatment at different strengths (400-800W), trough viscosity was found to
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decrease significantly (p < 0.05) from 2055 cP (native sample) to 141-1466 cP (ranging from -26.7%
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to -93.1%).
160
to -92.0% for the treated samples) was also noted.
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observed.
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starch sample prepared with plasma at 800W had the lowest viscosity.
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depolymerization are competitive reactions during plasma treatment (Wongsagonsup et al., 2014).
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It was inferred that the plasma reactive species might weaken bond strengths or even break down the
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bonds of starch molecules.
A remarkable decline in final viscosity from 3459 cP (native) to 277-2489 cP (-28.0% No apparent changes in pasting temperature were
Overall, the higher the plasma intensity, the lower the viscosity.
Table 1 shows that
In fact, cross-linking and
Destabilization of starch paste or granule resulted from molecular 7
166 167
depolymerization and granular corrosion could lead to a viscosity reduction (Zhu, 2017). In parallel to the changes in viscosity, a reducing trend in the breakdown values was observed as
168
the plasma intensity increased.
169
ability to resist heating and shear stress during cooking (Adebowale et al., 2005).
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starch samples with lower breakdown values, especially of those being prepared at 800W, presented
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a better ability to withstand heating and shear stress.
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Starch samples with lower breakdown values indicated their greater It implied that the
Setback signified the degree of amylose re-association and the retrogradation tendency of starch
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paste (Charles et al., 2004; Zaidul et al., 2007).
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decreased tendency towards retrogradation.
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but plunged (p < 0.05) to 1024 cP (-27.1% at 400W), 391 cP (-72.2% at 600W), and 136 cP (-93.3%
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at 800W) after the plasma treatments.
177
procedures, which was plasma treatment followed by washing, contributed to an improvement in
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paste-cooling stability and reduced retrogradation of corn starch.
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In general, starch with lower setback value had a
The setback of the native sample was 1404 cP initially,
The above results demonstrated that the sample preparation
Thus, it could be concluded that plasma treatment tended to decrease corn starch paste viscosity
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and retrogradation.
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nitrogen and helium glow-plasma would reduce the viscosity, breakdown, and setback of potato
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starch during pasting process.
183
due to the destruction of starch structure and facilitated leaching of amylose molecules after applying
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another type of plasma has also been reported (Thirumdas et al., 2017b).
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treatment on starch pasting properties were therefore associated with different starch variety, plasma
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types, and treatment conditions, which included feed gas, input power, and reaction time (Thirumdas
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et al., 2017a; Zhu, 2017).
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3.3. Swelling power and water soluble index
Some similar observations reported by Zhang et al. (2015) have suggested that
In contrast, an elevation in granule swelling, solubility, and viscosity
The influences of plasma
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Swelling powers and water soluble indexes of different starch samples are shown in Table 2.
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No apparent changes in swelling power were observed between the native starch (19.14 g/g) and the
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other three plasma-treated samples (19.22-19.35 g/g). 8
The water soluble indexes of treated starch
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samples at different plasma intensities (25.34-50.70%) were about 1.3- to 2.6-fold higher (p < 0.05)
193
than that of the native starch (19.46%), in particular that a 800W intensity brought about the highest
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water solubility.
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species would increase the solubility (Bie et al., 2015).
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was observed on corn starch treated by corona electrical discharge plasma (Nemtanu & Minea, 2006).
197
3.4. Starch paste clarity
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The molecular degradation and oxidation of starch resulted from active plasma However, an opposite trend in solubility
As shown in Table 2, the clarity value of native corn starch was 15.7%.
Corn starch samples
199
that underwent plasma treatments (at 400-800W) had significantly higher clarity values (17.95-
200
29.63%), which were approximately 1.14- to 1.89-fold increase against the control.
201
with the trends reported by Thirumdas et al. (2017b), the results revealed that these treatments would
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improve the starch paste clarity. Depolymerization was one of the underlying causes of the increase
203
in dispersion and solubility during gelatinization, and this ended up in a raise in the clarity
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(Wongsagonsup et al., 2014).
205
hydroxyl groups or more hydrogen bonds to the surrounding water molecules (Nemtanu &
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Brasoveanu, 2010).
207
In agreement
Improved clarity might also be attributed to an increased exposure of
Starch clarity plays a pivotal role in food industry application, especially jelly or jelly-related
208
products.
209
in corn starch rendered its low paste clarity.
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applications in food industry.
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could eliminate residual reactive species, and thus offer an opportunity for widening the uses of corn
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starch in food processing.
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3.5. Morphology of starch granules
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Comparing with other types of native starch, high amylose content, lipids, and proteins These characteristics of corn starch limited its
Our results suggested that washing the starch after a plasma treatment
The polarized light and SEM micrographs of native and plasma-treated corn starches are shown
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in Figure 4.
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polarized light.
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gelatinization or crystalline region destruction.
The Maltese crosses of all starch samples (treated or untreated) were clearly seen under It indicated that air plasma jet belonging to non-thermal plasma did not cause These results agreed with the findings from Zhang 9
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et al. (2015) in which potato starch underwent nitrogen glow-plasma, ending without significant
219
changes in starch granule.
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As illustrated in the SEM micrographs of different corn starch samples (Figure 4), the surface
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morphology of corn starch granules had polyhedral and irregular shapes with a diameter ranging from
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4 to 20 μm.
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surface of the starch granules and no significant changes in the overall morphology were observed.
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The phenomenon of slight scratches might be generated by the high energy electron passed through
225
granules during plasma treatment (Brabosa-Canovas et al., 2000).
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appearances of starch granule surfaces were affected by the plasma intensity.
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intensity, the more the surface etching.
228
would worsen the surface damage on starch granules (Thirumdas et al., 2015).
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After the plasma treatments, only some slight fissures or scratches appeared on the
Figure 4 also revealed that the The higher the
In fact, it has been reported that a high plasma intensity
Formation of cavities, fissures or tiny deposits on the surface of starch granules after plasma
230
treatment have also been reported by Thirumdas et al. (2017a).
231
morphology changes might be subjected to various gas compositions in plasma treatment.
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plasma caused a surface corrosion while nitrogen plasma had no effect on starch granules (Zhang et
233
al., 2015).
It was interesting that the surface Helium
234 235
4. Conclusions
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In conclusion, an inference that the plasma treatment at different intensities (400-800W) initiated
237
depolymerization of native corn starch, resulting in production of small molecular fragments and
238
hydrophilic functional groups could be drawn from the results.
239
conditions might lead to a reduction of viscosity and an increase in solubility and starch paste clarity
240
of starch.
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the plasma and subsequent washing treatments might avail food applications requiring starch with
242
low viscosity as well as high paste clarity and solubility.
Consequently, the aforementioned
The modifications of different physicochemical properties of corn starch by employing
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Acknowledgements
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This work was supported by the Ministry of Science and Technology of the Republic of China
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(MOST 106-2320-B-005-006-MY3) as well as the Council of Agriculture, the Republic of China
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(107AS-3.3.1-CI-C1).
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Declarations of interest
249
None
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Figure 1. Schematic diagram of the experimental setup using atmospheric pressure jet plasma as a
316
tool to modify starch characteristics.
14
100
3500 3000
Viscosity (cP)
2500 60
2000 1500
40 1000
Temperature (℃ )
80
20
500 0
0 0
317 318 319 320
2
6
4
10
8
12
Time (min) native 800W 800W-T1 Figure 2. Changes in the viscosity of native and plasma-treated (at 800W) starch samples (without 800W-T7 temperature
washing) after stored for 0-7 days.
15
321
(A) at a ratio of 1:15 w/v
322 323 324
(B) at a ratio of 1:30 w/v
325 326
Figure 3. Effects of water washing treatment on the viscosity of plasma-treated
327
(at 800W) starch samples after stored for 0 and 7 days.
16
328
(A1) native (control)
(B1) native (control)
329 330
(A2) 400W
(B2) 400W
331 332
(A3) 600W
(B3) 600W
333 334
(A4) 800W
(B4) 800W
335 336
Figure 4. Polarized light and SEM micrographs of native and plasma-treated corn starch
337
samples.
338
A1: polarized light micrographs of native corn starch; A2, A3, and A4: polarized light
339
micrographs of corn starches treated with plasma at different strengths (400W, 600W, and
340
800W, respectively); B1: SEM micrographs of native corn starch; B2, B3, and B4: SEM
341
micrographs of corn starches treated with plasma at different strengths (400W, 600W, and
342
800W, respectively). 17
343 344
Table 1. Pasting properties of native and plasma-treated corn starch samples Peak
Trough Breakdown
Treatments
viscosity
Pasting
Final
viscosity
Setback viscosity (cP)
(cP) (cP)
temperature (°C)
(cP)
(cP)
native
3181 a
2055 a
1126 b
3459 a
1404 a
76.20 a
400W
2793 b
1466 b
1327 a
2489 b
1024 b
76.75 a
600W
1451 c
581 c
870 c
972 c
391 c
76.00 a
800W
410 d
141 d
269 d
277 d
136 d
77.08 a
345
Values (mean of three determinations) in the same column with different superscripts are significantly
346
different (Duncan, p < 0.05).
18
347
Table 2. Swelling power, water soluble index and starch paste clarity of native and plasma-treated
348
corn starch samples Treatments
Swelling power (g/g)
Water soluble index (%)
Starch paste clarity (%T)
native
19.14 ± 0.45 a
19.46 ± 1.68 a
15.70 ± 0.13 a
400W
19.35 ± 1.10 a
25.34 ± 2.46 b
17.95 ± 0.07 b
600W
19.22 ± 1.25 a
32.85 ± 2.49 c
20.17 ± 0.37 c
800W
19.23 ± 0.75 a
50.70 ± 3.80 d
29.63 ± 0.21 d
349
Values (mean ± SD of three determinations) in the same column with different superscripts are
350
significantly different (Duncan, p < 0.05).
351 352
Highlights
353
Development of an effective way to remove residual aging effects caused by plasma
354
Production of low viscosity starch by atmospheric pressure plasma jet treatment
355
Improvement in paste-cooling stability and reduced retrogradation of corn starch
356
Favorable for applications requiring starch with high paste clarity and solubility
357
A fast and alternative physical approach for starch modification
358 359
19
S0308-8146(19)30111-6 https://doi.org/10.1016/j.foodchem.2019.01.043 FOCH 24138
To appear in:
Food Chemistry
Received Date: Revised Date: Accepted Date:
1 October 2018 19 December 2018 4 January 2019
Please cite this article as: Wu, T-Y., Chang, C-R., Chang, T-J., Chang, Y-J., Liew, Y., Chau, C-F., Changes in physicochemical properties of corn starch upon modifications by atmospheric pressure plasma jet, Food Chemistry (2019), doi: https://doi.org/10.1016/j.foodchem.2019.01.043
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1
Changes in physicochemical properties of corn starch upon
2
modifications by atmospheric pressure plasma jet
3
Tsung-Yen WUa, Chih-Ren CHANGb,c, Tsai-Ju CHANGb, Yu-Ju CHANGb, Ying LIEWb, and Chi-
4
Fai CHAUb,*
5
a
Agricultural Chemistry Division, Taiwan Agricultural Research Institute, Council of Agriculture,
6
No.189, Zhongzheng Rd., Wufeng Dist., Taichung 41362, Taiwan
7
b
Department of Food Science and Biotechnology, National Chung Hsing University, 145 Xingda
8 9 10
Road, Taichung 40227, Taiwan c
Department of Traditional Chinese Medicine, Puli Branch of Taichung Veterans General Hospital, No.1, Rongguang Rd., Puli Township, Nantou County 545, Taiwan
11 12
*Corresponding authors. Department of Food Science and Biotechnology, National Chung Hsing
13
University, 145 Xingda Road, Taichung 40227, Taiwan
14
E-mail address: [email protected] (C.-F. Chau)
15
Telephone: +886-4-22852420
16
Fax: +886-4-22876211
17 18
Running title: Modifications of corn starch by employing atmospheric pressure plasma jet
19
1
20
Abstract
21
The influences of atmospheric pressure plasma jet on different physicochemical properties of
22
corn starch were evaluated after treated with the plasma jet (30 min) at different strengths (400W-
23
800W). Our results demonstrated that residual aging effects of plasma on starch could be eliminated
24
by washing the treated samples with distilled water at a ratio of 1:30, w/v.
25
treatments, significant (p < 0.05) reductions in pasting properties including peak viscosity, final
26
viscosity, and setback of starch samples (up to -87.1%, -92.0%, and -93.3%, respectively) were
27
observed with increasing plasma intensity.
28
paste clarity of starch sample.
29
etching resulted in some physical changes on starch granules.
30
physicochemical properties of corn starch by employing the plasma jet treatment might be useful in
31
food applications requiring starch ingredients of low viscosity and high paste clarity.
After plasma and washing
Apparently, plasma jet could increase the solubility and
Surface morphological characterization illustrated that plasma Modifications in these
32 33
Keywords: corn starch, atmospheric pressure plasma jet, physicochemical property, starch
34
modification
35
2
36 37
1. Introduction Plasma is known as the fourth state of matter, which can be divided into high temperature and
38
low temperature plasma.
39
Atmospheric pressure non-thermal plasma can be generated at room temperature (290-300 K) without
40
any quenching.
41
applicability on some thermosensitive compounds, lower cost, and an increase in treatment efficiency
42
(Nehra et al., 2008; Misra et al., 2011).
43
The latter is further subdivided into thermal and non-thermal plasma.
The advantages of this non-thermal plasma in food applications might include its
Starch is one of the most widely used biopolymers in various industries, such as stabilizers and
44
thickeners in food, textile, paper, and pharmaceutical industry (Thirumdas et al., 2017a).
45
wider applications of starches, different chemical, physical, and enzymatic modifications were
46
needed to improve their physicochemical properties (Colussi et al., 2014).
47
be considered as a physical approach for starch modification. It generated different types of reactive
48
species which interacted with starches and induced chemical changes to develop novel starch
49
functionalities (Zhu, 2017).
To explore
Plasma technology could
50
Interactions between plasma and starch would modify starch molecules through several
51
mechanisms, such as cross-linking, depolymerization, and plasma etching (Morent et al., 2011).
52
Different reactive species generated by plasma might lead to alterations in structures or some
53
physicochemical parameters (e.g. swelling, solubility, and viscosity) of starch molecules.
54
effects of plasma treatment on starches depended on several factors, including apparatus types,
55
treatment conditions (feed gas, power input, and exposure time), and also the type and composition
56
of starch (Zhu, 2017).
57
The
In view of the advantages like simple construction, easy adoption, and high handling efficiency,
58
the uses of atmospheric pressure air plasma jet has been exploited in a diversity of food research.
59
this study, corn starch samples were treated with gases produced by an air plasma jet at different
60
strengths.
61
and compared.
In
Changes in different physicochemical properties of the treated samples were evaluated Potential applications of the air plasma jet on the modifications of corn starch were 3
62
also discussed.
63 64
2. Materials and methods
65
2.1. Air plasma jet treatment
66
A schematic diagram of the experimental setup is shown in Figure 1.
In this study, the input
67
powers for generating cold plasma were 400W, 600W, and 800W.
68
contained 73% amylopectin and 27% amylose was purchased from Sigma-Aldrich, Co. (St. Louis,
69
MO, USA).
70
height of 476 mm) filled with plasma gases generated from air plasma jet (SAP003X, Creating Nano
71
Technologies, Inc., Taiwan) and held for 30 min.
72
the treated starch samples were immediately washed with distilled water at different ratios (1:15 and
73
1:30, w/v) to eliminate the residual aging effects of plasma on starch.
74
centrifuged at 4000×g for 5 min and then dried in an oven at 40°C for 24 h.
Corn starch (S-4126) which
This native corn starch was placed in a reaction chamber (diameter of 295 mm and
After reacted with plasma gases in the chamber,
The starch suspension was
75
To determine a proper starch-to-water ratio for washing to cease the residual aging effect of
76
plasma, changes in the viscosity of treated samples were analyzed at days 0, 1, and 7 according to the
77
methods as described by Wu et al. (2018) with slight modifications.
78
referred to the sample analysis conducted immediately after washing and drying.
79
referred to the analyses of washed samples after a storage for 24 hours and 7 days, respectively.
80
set of controlled observations was also performed on the starch samples without washing after the
81
plasma treatment.
82
2.2. Determination of pasting properties
More specifically, day 0 Day 1 and day 7 A
83
Pasting properties of corn starch samples were determined by the methods described by Wu et
84
al. (2018) with slight modifications, and measured with a Rapid Visco Analyser (Model RVA-Super
85
3, Newport Scientific Pty Ltd., NSW, Australia), which was controlled by the Thermocline software
86
(version 2.3, Newport Scientific Pty Ltd., NSW, Australia).
87
mL of distilled water in a canister.
Starch sample (3 g) was mixed with 25
The mixture was equilibrated at 50°C for 1 min, heated to 95°C 4
88
at a rate of 12.2°C per min.
89
50°C at a rate of 11.8°C per min and maintained at 50°C for 2 min.
90
viscosity during pasting), trough viscosity (minimum viscosity at 95°C), breakdown (difference
91
between the peak viscosity and trough viscosity), final viscosity, setback (difference between the final
92
viscosity and trough viscosity) and pasting temperature were recorded.
93
expressed by centipoise (cP).
94
2.3. Determination of swelling power and water soluble index
95
Sample was then held at 95°C for 2.5 min, followed by a cooling to
The units of viscosity were
The swelling power and water soluble index of starch samples were determined by the methods
96
described by Li and Yeh (2001) with slight modifications.
97
at 95°C for 30 min with intermittent shaking.
98
an iced water bath.
99
supernatant was dried in an air oven at 100°C to constant weight (W1).
100
The peak viscosity (maximum
Starch suspension (2%, w/v) was heated
The suspension was cooled to room temperature in
After centrifuged at 8000×g for 20 min, the precipitate was weighed (WS).
The water soluble index and
swelling power were calculated using the following equations:
101
Water soluble index (%) = [W1/weight of starch sample] × 100
102
Swelling power (g/g) = WS/[weight of starch sample × (100% - water soluble index%)]
103
The
2.4. Determination of starch paste clarity
104
Clarity of starch paste was determined according to the methods of Wongsagonsup et al. (2014).
105
Starch paste solution (1%, w/v) was prepared by heating starch sample in distilled water at 95°C for
106
30 min, shaken thoroughly every 5 min, followed by a cooling to room temperature.
107
of light transmittance (%T) at 650 nm was determined spectrophotometrically against distilled water.
108
2.5. Morphological characterization
109
The percentage
Optical and polarized light micrographs of corn starch samples were determined by Nikon
110
microscope (Optiphot 2-Pol, Nikon, Tokyo, Japan) equipped with a polarizer.
111
micrographs were taken with a tabletop scanning electron microscope (SEM; TM-1000, Hitachi,
112
Tokyo, Japan).
113
sputter coated with gold powder (at 2 mbar for 3 minutes) prior to SEM observation.
Scanning electron
Samples were mounted on a specimen holder using double-sided sticky tape and
5
114 115
2.6. Statistical analysis Experimental results were statistically analyzed using the SPSS statistics program (version 20.0;
116
SPSS, Armonk, NY, USA).
117
multiple range test to compare mean values.
118
0.05.
Analysis of variance (ANOVA) was performed using Duncan’s Statistical significance difference was defined at p <
The data presented are means of three replicates.
119 120
3. Results and discussion
121
3.1. Plasma treatment
122
Aging effects and its subsequent surface modification were common phenomenon in polymers
123
after plasma treatment.
124
polymers over the storage period were usual.
125
plasma oxidation and surface adaptation.
126
Hasnain, 2014; Thirumdas et al., 2017a) which involved a continuous reaction of high-energy active
127
substances (residual free radicals) produced by plasma and atmospheric oxygen.
128
induce the formation of reactive oxygen and nitrogen species, as well as many unstable polar
129
functional groups on the polymer surface.
130
would be diminished due to the alteration in interfacial properties by a mechanism called surface
131
adaptation (Siow et al. 2006).
132
Changes in chemical compositions and characteristics of the treated The aging effect was basically attributed to post-
Oxidation was in fact a depolymerization process (Ali &
Plasma might
However, it was interesting that these functional groups
In Figure 2, the corn starch samples were first treated by the highest output (800W) of the power
133
supply.
134
(day 0), RVA analyses showed that the viscosity of treated samples dropped dramatically after the
135
first 24 hours (day 1) and even became null after 7 days of storage.
136
in viscosity was partly attributed to the aging effects of the residual reactive species being trapped in
137
the treated starch samples as well as the instability of polar functional groups.
As compared with the initial viscosity measured immediately after the plasma treatment
It was inferred that the decrease
138
In this study, the treated samples were washed with distilled water at different ratios with the
139
purpose to remove the residual reactive species generated by the air plasma jet since the reactive 6
140
species formed during plasma treatment dissolved readily in water (Thirumdas et al., 2018).
141
3 (A) illustrates that washing the samples with distilled water at a ratio of 1:15 (w/v) could slightly
142
mitigate the instability and reduction of viscosity during storage.
143
the samples with a relatively larger amount of distilled water (at 1:30, w/v) was more effective in
144
resolving the loss in viscosity and improving the stability of the plasma-treated samples.
Figure
As shown in Figure 3 (B), washing
145
On the basis of these findings, the starch samples to be used in the other experiments of this
146
study would be prepared by reacting with plasma at different strengths (400W, 600W, and 800W),
147
followed by washing with an optimal amount of distilled water (at 1:30, w/v) and drying for further
148
uses.
149
3.2. Pasting properties
150
Table 1 summarizes the pasting properties of native corn starch (control) and the other starch
151
samples after the plasma treatment and subsequent washing.
152
final viscosity of the starch samples decreased significantly (p < 0.05) with an increase in plasma
153
intensity.
154
dropping from 3181 cP (native) to 2793 cP (400W).
155
significant reduction (p < 0.05) of viscosity down to 1451 cP (-54.4%) and 410 cP (-87.1%),
156
respectively, were observed.
Peak viscosity, trough viscosity, and
With the plasma intensity at 400W, peak viscosity decreased (p < 0.05) by -12.2%, At higher intensities (600W and 800W), a more
157
After the plasma treatment at different strengths (400-800W), trough viscosity was found to
158
decrease significantly (p < 0.05) from 2055 cP (native sample) to 141-1466 cP (ranging from -26.7%
159
to -93.1%).
160
to -92.0% for the treated samples) was also noted.
161
observed.
162
starch sample prepared with plasma at 800W had the lowest viscosity.
163
depolymerization are competitive reactions during plasma treatment (Wongsagonsup et al., 2014).
164
It was inferred that the plasma reactive species might weaken bond strengths or even break down the
165
bonds of starch molecules.
A remarkable decline in final viscosity from 3459 cP (native) to 277-2489 cP (-28.0% No apparent changes in pasting temperature were
Overall, the higher the plasma intensity, the lower the viscosity.
Table 1 shows that
In fact, cross-linking and
Destabilization of starch paste or granule resulted from molecular 7
166 167
depolymerization and granular corrosion could lead to a viscosity reduction (Zhu, 2017). In parallel to the changes in viscosity, a reducing trend in the breakdown values was observed as
168
the plasma intensity increased.
169
ability to resist heating and shear stress during cooking (Adebowale et al., 2005).
170
starch samples with lower breakdown values, especially of those being prepared at 800W, presented
171
a better ability to withstand heating and shear stress.
172
Starch samples with lower breakdown values indicated their greater It implied that the
Setback signified the degree of amylose re-association and the retrogradation tendency of starch
173
paste (Charles et al., 2004; Zaidul et al., 2007).
174
decreased tendency towards retrogradation.
175
but plunged (p < 0.05) to 1024 cP (-27.1% at 400W), 391 cP (-72.2% at 600W), and 136 cP (-93.3%
176
at 800W) after the plasma treatments.
177
procedures, which was plasma treatment followed by washing, contributed to an improvement in
178
paste-cooling stability and reduced retrogradation of corn starch.
179
In general, starch with lower setback value had a
The setback of the native sample was 1404 cP initially,
The above results demonstrated that the sample preparation
Thus, it could be concluded that plasma treatment tended to decrease corn starch paste viscosity
180
and retrogradation.
181
nitrogen and helium glow-plasma would reduce the viscosity, breakdown, and setback of potato
182
starch during pasting process.
183
due to the destruction of starch structure and facilitated leaching of amylose molecules after applying
184
another type of plasma has also been reported (Thirumdas et al., 2017b).
185
treatment on starch pasting properties were therefore associated with different starch variety, plasma
186
types, and treatment conditions, which included feed gas, input power, and reaction time (Thirumdas
187
et al., 2017a; Zhu, 2017).
188
3.3. Swelling power and water soluble index
Some similar observations reported by Zhang et al. (2015) have suggested that
In contrast, an elevation in granule swelling, solubility, and viscosity
The influences of plasma
189
Swelling powers and water soluble indexes of different starch samples are shown in Table 2.
190
No apparent changes in swelling power were observed between the native starch (19.14 g/g) and the
191
other three plasma-treated samples (19.22-19.35 g/g). 8
The water soluble indexes of treated starch
192
samples at different plasma intensities (25.34-50.70%) were about 1.3- to 2.6-fold higher (p < 0.05)
193
than that of the native starch (19.46%), in particular that a 800W intensity brought about the highest
194
water solubility.
195
species would increase the solubility (Bie et al., 2015).
196
was observed on corn starch treated by corona electrical discharge plasma (Nemtanu & Minea, 2006).
197
3.4. Starch paste clarity
198
The molecular degradation and oxidation of starch resulted from active plasma However, an opposite trend in solubility
As shown in Table 2, the clarity value of native corn starch was 15.7%.
Corn starch samples
199
that underwent plasma treatments (at 400-800W) had significantly higher clarity values (17.95-
200
29.63%), which were approximately 1.14- to 1.89-fold increase against the control.
201
with the trends reported by Thirumdas et al. (2017b), the results revealed that these treatments would
202
improve the starch paste clarity. Depolymerization was one of the underlying causes of the increase
203
in dispersion and solubility during gelatinization, and this ended up in a raise in the clarity
204
(Wongsagonsup et al., 2014).
205
hydroxyl groups or more hydrogen bonds to the surrounding water molecules (Nemtanu &
206
Brasoveanu, 2010).
207
In agreement
Improved clarity might also be attributed to an increased exposure of
Starch clarity plays a pivotal role in food industry application, especially jelly or jelly-related
208
products.
209
in corn starch rendered its low paste clarity.
210
applications in food industry.
211
could eliminate residual reactive species, and thus offer an opportunity for widening the uses of corn
212
starch in food processing.
213
3.5. Morphology of starch granules
214
Comparing with other types of native starch, high amylose content, lipids, and proteins These characteristics of corn starch limited its
Our results suggested that washing the starch after a plasma treatment
The polarized light and SEM micrographs of native and plasma-treated corn starches are shown
215
in Figure 4.
216
polarized light.
217
gelatinization or crystalline region destruction.
The Maltese crosses of all starch samples (treated or untreated) were clearly seen under It indicated that air plasma jet belonging to non-thermal plasma did not cause These results agreed with the findings from Zhang 9
218
et al. (2015) in which potato starch underwent nitrogen glow-plasma, ending without significant
219
changes in starch granule.
220
As illustrated in the SEM micrographs of different corn starch samples (Figure 4), the surface
221
morphology of corn starch granules had polyhedral and irregular shapes with a diameter ranging from
222
4 to 20 μm.
223
surface of the starch granules and no significant changes in the overall morphology were observed.
224
The phenomenon of slight scratches might be generated by the high energy electron passed through
225
granules during plasma treatment (Brabosa-Canovas et al., 2000).
226
appearances of starch granule surfaces were affected by the plasma intensity.
227
intensity, the more the surface etching.
228
would worsen the surface damage on starch granules (Thirumdas et al., 2015).
229
After the plasma treatments, only some slight fissures or scratches appeared on the
Figure 4 also revealed that the The higher the
In fact, it has been reported that a high plasma intensity
Formation of cavities, fissures or tiny deposits on the surface of starch granules after plasma
230
treatment have also been reported by Thirumdas et al. (2017a).
231
morphology changes might be subjected to various gas compositions in plasma treatment.
232
plasma caused a surface corrosion while nitrogen plasma had no effect on starch granules (Zhang et
233
al., 2015).
It was interesting that the surface Helium
234 235
4. Conclusions
236
In conclusion, an inference that the plasma treatment at different intensities (400-800W) initiated
237
depolymerization of native corn starch, resulting in production of small molecular fragments and
238
hydrophilic functional groups could be drawn from the results.
239
conditions might lead to a reduction of viscosity and an increase in solubility and starch paste clarity
240
of starch.
241
the plasma and subsequent washing treatments might avail food applications requiring starch with
242
low viscosity as well as high paste clarity and solubility.
Consequently, the aforementioned
The modifications of different physicochemical properties of corn starch by employing
243 10
244
Acknowledgements
245
This work was supported by the Ministry of Science and Technology of the Republic of China
246
(MOST 106-2320-B-005-006-MY3) as well as the Council of Agriculture, the Republic of China
247
(107AS-3.3.1-CI-C1).
248
Declarations of interest
249
None
250
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310
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311
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312 313
Zhu,
F.
(2017).
Plasma
modification
of
starch.
https://doi.org/10.1016/j.foodchem.2017.04.024.
13
Food
chemistry,
232,
476-486.
314 315
Figure 1. Schematic diagram of the experimental setup using atmospheric pressure jet plasma as a
316
tool to modify starch characteristics.
14
100
3500 3000
Viscosity (cP)
2500 60
2000 1500
40 1000
Temperature (℃ )
80
20
500 0
0 0
317 318 319 320
2
6
4
10
8
12
Time (min) native 800W 800W-T1 Figure 2. Changes in the viscosity of native and plasma-treated (at 800W) starch samples (without 800W-T7 temperature
washing) after stored for 0-7 days.
15
321
(A) at a ratio of 1:15 w/v
322 323 324
(B) at a ratio of 1:30 w/v
325 326
Figure 3. Effects of water washing treatment on the viscosity of plasma-treated
327
(at 800W) starch samples after stored for 0 and 7 days.
16
328
(A1) native (control)
(B1) native (control)
329 330
(A2) 400W
(B2) 400W
331 332
(A3) 600W
(B3) 600W
333 334
(A4) 800W
(B4) 800W
335 336
Figure 4. Polarized light and SEM micrographs of native and plasma-treated corn starch
337
samples.
338
A1: polarized light micrographs of native corn starch; A2, A3, and A4: polarized light
339
micrographs of corn starches treated with plasma at different strengths (400W, 600W, and
340
800W, respectively); B1: SEM micrographs of native corn starch; B2, B3, and B4: SEM
341
micrographs of corn starches treated with plasma at different strengths (400W, 600W, and
342
800W, respectively). 17
343 344
Table 1. Pasting properties of native and plasma-treated corn starch samples Peak
Trough Breakdown
Treatments
viscosity
Pasting
Final
viscosity
Setback viscosity (cP)
(cP) (cP)
temperature (°C)
(cP)
(cP)
native
3181 a
2055 a
1126 b
3459 a
1404 a
76.20 a
400W
2793 b
1466 b
1327 a
2489 b
1024 b
76.75 a
600W
1451 c
581 c
870 c
972 c
391 c
76.00 a
800W
410 d
141 d
269 d
277 d
136 d
77.08 a
345
Values (mean of three determinations) in the same column with different superscripts are significantly
346
different (Duncan, p < 0.05).
18
347
Table 2. Swelling power, water soluble index and starch paste clarity of native and plasma-treated
348
corn starch samples Treatments
Swelling power (g/g)
Water soluble index (%)
Starch paste clarity (%T)
native
19.14 ± 0.45 a
19.46 ± 1.68 a
15.70 ± 0.13 a
400W
19.35 ± 1.10 a
25.34 ± 2.46 b
17.95 ± 0.07 b
600W
19.22 ± 1.25 a
32.85 ± 2.49 c
20.17 ± 0.37 c
800W
19.23 ± 0.75 a
50.70 ± 3.80 d
29.63 ± 0.21 d
349
Values (mean ± SD of three determinations) in the same column with different superscripts are
350
significantly different (Duncan, p < 0.05).
351 352
Highlights
353
Development of an effective way to remove residual aging effects caused by plasma
354
Production of low viscosity starch by atmospheric pressure plasma jet treatment
355
Improvement in paste-cooling stability and reduced retrogradation of corn starch
356
Favorable for applications requiring starch with high paste clarity and solubility
357
A fast and alternative physical approach for starch modification
358 359
19