Preparation of Gelatin Films Incorporated with Tea Polyphenol

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Preparation of Gelatin Films Incorporated with Tea PolyphenolNanoparticles for Enhancing Controlled Release Antioxidant Properties Fei Liu, John Antoniou, Yue Li , Jiang Yi, Wallace Yokoyama, Jianguo Ma, and Fang Zhong J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.5b00003 • Publication Date (Web): 31 Mar 2015 Downloaded from http://pubs.acs.org on April 4, 2015

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Journal of Agricultural and Food Chemistry

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Preparation of Gelatin Films Incorporated with Tea

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Polyphenol-Nanoparticles for Enhancing Controlled Release Antioxidant

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Properties

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Fei Liu,† John Antoniou,† Yue Li,† Jiang Yi,† Wallace Yokoyama,‡ Jianguo Ma,† and

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Fang Zhong*,†

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†

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of Food Science and Technology, Jiangnan University, Wuxi 214122, P.R. China

9

‡

Key Laboratory of Food Colloids and Biotechnology, Ministry of Education, School

Western Regional Research Center, ARS, USDA, Albany, CA 94710, United States

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*Corresponding author:

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Fang Zhong

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Tel: +86-510-85197876, Fax: +86-510-85197876, E-mail: [email protected]

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ABSTRACT Gelatin

films

incorporated

with

chitosan

nanoparticles

of

various

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free/encapsulated tea polyphenols (TP) ratios were prepared in order to investigate the

18

influence of different ratios on physico-chemical and antioxidant properties of films.

19

The TP containing nanoparticles were prepared by cross-linking chitosan

20

hydrochloride (CSH) with sulfobutylether-β-cyclodextrin sodium (SBE-β-CD) at

21

three different encapsulation efficiencies (EE, ~50%, ~80% and ~100%) of TP. The

22

stability of TP-loaded nanoparticles was maintained during film drying process from

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the analysis of free TP content in the redissolved film solutions. Composite films

24

showed no significant difference in visual aspects while the light transmittance

25

(250-550 nm) was decreased with incorporation of TP. Nanoparticles appeared to be

26

homogeneously dispersed within the film matrix by microstructure analysis (SEM and

27

AFM). TP loaded films had ferric reducing and DPPH radical scavenging power that

28

corresponded to the EEs. Sunflower oil packaged in bags made of gelatin films

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embedded with nanoparticles of 80% EE showed the best oxidation inhibitory effect,

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followed by 100% EE, 50% EE and free TP over 6 weeks storage. However, when the

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gelatin film was placed over the headspace and not in contact with the oil the free TP

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showed the best effect. The results indicate that sustained release of TP in the

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contacting surface can ensure the protective effects which vary with free/encapsulated

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mass ratios, thus improving antioxidant activities instead of increasing the dosage.

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KEYWORDS:

Gelatin

film,

tea

polyphenols,

nanoparticles, oil, oxidation inhibition 2

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cyclodextrin,

chitosan

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INTRODUCTION

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Lipid oxidation or oxidative rancidity, besides microbial growth, is the main

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cause of food spoilage particularly for food rich in polyunsaturated fatty acids.1,2 In

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order to prevent oxidation and extend shelf life, synthetic antioxidants like BHA, BHT,

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TBHQ and PG have been widely used as food additives for decades. With the concern

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of undesirable side effects and potential risks, the search for natural antioxidants as

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alternatives to synthetic antioxidants is therefore of increasing attention in food

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applications recently.

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Direct addition of antioxidants into food may encounter the limitation that once

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the activity of antioxidants was neutralized by the reaction with food compounds, the

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protection ceases and the quality of the food degrades at an increased rate.1 Since the

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lipid oxidation process are generally induced from the surface of foodstuffs, many

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efforts have been made to incorporate antioxidants into food packaging/edible film to

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control the oxidation of food product,3-6 with the expection that antioxidants released

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by a controlled diffusion to the food can retard the oxidation and extend the shelf life.7

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Natural antioxidants such as resveratrol,8 curcuma ethanol extracts,9 and green tea

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extracts or tea polyphenols (TP)6,10 have been successfully incorporated to fabricate

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antioxidant active packaging or edible films. According to Gómez-Estaca, et al.1, one

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of the valid solutions for slowing down the releasing process of active compounds in

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films is the inclusion of antioxidants in the matrix of nanoparticles that increase the

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tortuosity of the diffusion path. Furthermore, the problem that antioxidants may loss

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activity with time thus eliminating the antioxidant activity of films remains despite 3

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that the hydrophilic antioxidants (like TP) can be incorporated directly into films.10

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Nano-encapsulation before being incorporated in the film matrix can also protect TP

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or other active substances from premature reactions with oxygen and light.

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Tea catechins, the main compounds in TP can form inclusion complexes with

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β-cyclodextrin and the complex can maintain the antioxidant capacity of tea

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catechins.11 Chitosan nanoparticles could be formulated based on the ionic gelation

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between chitosan and sulfobutylether-β-cyclodextrin (SBE-β-CD),12 allowing an

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efficient encapsulation of TP. Although gelatin films incorporated with TP-loaded

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chitosan-tripolyphosphate nanoparticles have been studied before by our research

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group,13 there was no direct comparison between the encapsulated TP and the free TP

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in the film. Free TP would be homogenously distributed in the film whereas the

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encapsulated TP would be slowly released from nanoparticles to regions of film

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without antioxidants. Moreover, it has been reported that incorporation of nisin in the

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form of a nano-emulsion (half free and half encapsulated) showed the best results

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against food pathogens when compared to completely encapsulated (100%) and free

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nisin.14 The migration of some free TP to the film surface may be required in order to

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inhibit the initial oxidation, and perhaps both free TP and encapsulated TP within the

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film matrix are necessary to guarantee long term oxidative stability. For TP chitosan

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nanoparticles-incorporated films, it is still not known what differences in antioxidant

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properties would be presented when different free/nano-encapsulated active agent

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ratios are applied.

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In addition to carrying and protecting bioactive compounds, nanoparticles such 4

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as blank chitosan nanoparticles can improve the barrier, thermal and mechanical

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properties of films such as those based on hydroxypropyl methylcellulose (HPMC),15

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starch,16 tara gum17 and gelatin.18 Among them, the addition of chitosan nanoparticles

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with smaller particle sizes resulted in stronger mechanical properties and better barrier

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properties as observed by de Moura, et al.15 in HPMC films. Therefore the inclusion

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of antioxidants in chitosan nanoparticles into polymer matrices might bring a twofold

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advantage: the performance improvement of food packaging/edible film material and

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the provision of an additional antioxidant function.19

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In this study, TP was encapsulated in the matrix of CSH and SBE-β-CD

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nanoparticles and the TP containing nanoparticles were added into gelatin films. As a

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natural antioxidant, TP is subject to oxidation. In order to determine if encapsulation

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improved antioxidative lifetime of TP and protected it from degradation, gelatin films

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were also prepared embedded with free TP. The objective of this study was to

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investigate the antioxidant activities of gelatin films incorporated with free TP and

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TP-loaded

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encapsulation efficiencies.

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MATERIALS AND METHODS

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Materials. Gelatin (type B from bovine skin) and glycerol were purchased from

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China Medicine (Group) Shanghai Chemical Reagent Co. (Shanghai, China). CSH,

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molecular weight 100 kDa and degree of deacetylation 86%, derived from crab shells

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was obtained from Golden-Shell Biochemical Co., Ltd. (Hangzhou, China).

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SBE-β-CD (food grade), molecular weight 2.082 kDa and an average degree of

CSH-SBE-β-CD

nanoparticle

(CSN)

suspensions

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with

different

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substitution 6, was purchased from Kunshan Chemical Industries Co., Ltd. (Jiangsu,

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China). TP, polyphenol content ≥98% and catechins ≥90% (determined by

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manufacturer), was obtained from Qiangsheng Medicine Science Technology Co., Ltd.

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(Shanghai, China). 2, 2-diphenyl-1-picrylhydrazyl (DPPH) was purchased from

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Sigma Chemical Co. (St. Louis, MO, USA). All other reagents were analytical grade.

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Preparation of CSNs. CSNs were prepared according to a previously reported

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method,20 with minor modifications. Briefly, 24 mL of 2, 4 or 8 mg/mL SBE-β-CD in

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distilled water was added drop-wise to 72 mL of 0.5, 1 or 2 mg/mL CSH aqueous

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solutions, respectively, while under vigorous magnetic stirring leading to the

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formation of nanoparticles via the ionic gelation mechanism. The mass ratios of

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CSH/SBE-β-CD were controlled at 3:4 (w/w) in all cases. TP-loaded CSNs were

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prepared by adding an aqueous TP solution to the SBE-β-CD solution to obtain a

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concentration of 1 mg TP/mL and stirred for 24 h at room temperature to promote

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inclusion complex formation. The TP-SBE-β-CD solution was combined with the

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CSH solution. The nanoparticle suspensions were immediately analysed or used in

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film forming. All TP loaded films contained the same total amount of TP.

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Characterization of CSNs. The z-average particle size and size distribution of the

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nanoparticle suspensions were determined by dynamic light scattering (DLS,

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Zeta-PALS + BI-90Plus, Brookhaven Instrument Co., Holtsville, NY) at a fixed

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scattering angle of 90° at 25 ± 1 °C. All measurements were run in quadruplicate. The

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morphology of nanoparticles was examined by a high-performance digital imaging

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transmission electron microscope (TEM, JEOL 2100, Hitachi High-Technologies 6

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Corporation, Tokyo, Japan). The TEM samples were prepared by placing one drop of

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the suspension on a copper grid and staining with 2% (w/v) phosphotungstic acid, and

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air drying. Once dried, the sample was imaged by the microscope with an accelerating

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voltage of 100 kV.

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Encapsulation Efficiency of TP loaded-CSNs. The encapsulation efficiency (EE) of

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TP in CSNs was determined according to Hu, et al.21 Briefly, TP-loaded nanoparticles

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were carefully transferred into an AmiconUltra-4 centrifugal filter device (Millipore

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Co., Billerica, MA) with a 10,000 MW cut-off Ultracel membrane. After

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centrifugation at 4000 × g for 10 min, the concentration of TP in the ultrafiltrate was

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determined by the Folin-Ciocalteu method. Prior to measurement, the filtrate was

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5-fold diluted with distilled water. The total content of TP was calculated from the TP

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concentration in the aqueous medium before CSNs formation. The EE of TP was

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calculated using the Formula (1):

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EE (%) = ((Total Content of TP – Content of TP in Ultrafiltrate)

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/Total Content of TP) × 100

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Preparation of Films. The gelatin films were prepared by our previously reported

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method with some modifications.22 Briefly, 8% (w/v) gelatin solutions were prepared

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by hydrating gelatin powders in distilled water for 1 h at room temperature and then

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dissolved by heating at 65 °C with continuous stirring. Glycerol (1.6%) was added as

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a plasticizer in order to make the films less brittle and easier to handle. The

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composition of the gelatin films including films with TP-loaded nanoparticles

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formulations are shown in Table 1. The 8% gelatin-1.6% glycerol solutions (25 mL)

(1)

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were diluted with water (75 mL) or nanoparticle suspensions to 2% (w/v) gelatin in all

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film-forming solutions. A homogeneous solution was achieved after stirring for 1 h.

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Films were prepared by casting the 2% gelatin solutions (35 mL) in square Petri

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dishes (10 cm × 10 cm) and drying at 25 °C in an oven to a constant weight

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(approximately 36 h). The films were peeled off and conditioned at 25 °C and 53%

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relative humidity (RH) for at least 48 hours in a controlled environmental chamber

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(Shengxing Experimental Equipment Co., Ltd. Shanghai, China) before testing.

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Total Phenol Assay. The total phenolic content of films was estimated by the

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Folin-Ciocalteu method according to Jouki, et al.23 Initially cut conditioned films (2.5

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cm × 2.5 cm) were weighed and redissolved in 10 mL of distilled water at 40 °C for 1

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minute, and centrifuged (10000 x g, 10 min) at 20 °C. Supernatant (1 mL) and

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distilled water (1 mL) were thoroughly mixed with Folin-Ciocalteu reagent (5 mL, 10%

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v/v). After 6 min, 4 mL of 7.5% (w/v) sodium carbonate was added. The mixture was

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stirred thoroughly and allowed to stand at room temperature for 60 min prior to

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recording the absorbance at 765 nm in a spectrophotometer (Shimadzu UV-2450,

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Japan). The concentration of total phenol was expressed as mg gallic acid equivalent/g

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film sample according to the following Formula (2):

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Total Phenolic Content = (C × V )/M

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(2)

where C is the concentration of gallic acid obtained from the standard curve

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(mg/mL), V is the volume of the supernatant (mL) and M is the weight of film (g).

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Characterization of Films.

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Visual Appearance and Light Transmission. The film-forming solutions and films

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were evaluated visually for uniform color and the presence of insoluble particles. The

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ultraviolet and visible light transmittance properties of the films were measured

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according to the method of Bitencourt, et al.9 Film samples of 10 x 25 mm were

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placed in the light path of a spectrophotometer (UV-2450, Shimadzu, Tokyo, Japan).

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Transmittance was recorded from 200 to 800 nm in triplicate.

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Microstructure. Cross-section morphology of films was analyzed using a field

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emission scanning electron microscope (SEM, S-4800, Hitachi, Japan). Films were

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cryofractured by immersion in liquid nitrogen and conditioned in a desiccator at 25 °C

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before measurement. Samples were mounted on the specimen holder using

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double-sided adhesive tapes and then sputter coated with gold under vacuum. The

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samples were scanned with an accelerating voltage of 1 kV.

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An atomic force microscope (AFM, Bruker Dimension Icon, Bruker Co.,

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Germany) was used to observe surface morphology of films in tapping mode, and 50

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µm × 50 µm images under ambient conditions were obtained. All samples were

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analyzed in triplicate using a Bruker Nanoscope software (Version 1.40) to calculate

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the roughness values. The obtained parameters were: Ra, which is the arithmetic

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average of the absolute values of the surface height deviations (Z) measured from the

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mean plane and Rq, which is the root mean square average of height deviations taken

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from the mean image data plane. Ra and Rq were calculated from the following

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Formulas (3) & (4):

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N ∑j=1 Zj 

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Ra =

190

= 

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Determination of Antioxidant Activities In Vitro. In vitro antioxidant properties of

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films were performed based on the procedure reported by Wu, et al.10 The supernatant

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was prepared as stated in Total Phenol Assay part and was collected for further

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analyses including ferric reducing power and DPPH radical scavenging activity.

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Ferric Reducing Power. The determination of reducing power was measured as

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described by Li, et al.24 with slight modifications. Briefly, 1.0 mL of redissolved film

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solution was mixed with 2.5 mL of phosphate buffer (0.2 M, pH 6.6) and 2.5 mL

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potassium ferricyanide (1%, w/v). After incubating at 50 °C for 20 min and rapidly

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cooling, 2.5 mL of trichloroacetic acid (10%, w/v) was added to the mixture followed

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by centrifugation at 10000 x g for 10 min. The obtained supernatant (2.5 mL) was

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treated with 2.5 mL of distilled water and 0.5 mL of 0.1% ferric chloride (w/v). The

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absorbance of the reaction mixture was record at 700 nm (Shimadzu UV-2450, Japan)

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after 10 min reaction. Higher absorbance indicates higher reducing power.

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DPPH Radical Scavenging Activity. The method described by Yi, et al.25 was used

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to evaluate the DPPH radical scavenging activity, with slight modifications. Two mL

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of film supernatant was mixed with 2.5 mL (0.1 mM) of DPPH dissolved in ethanol.

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The mixture was kept in dark for 30 min at room temperature followed by

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centrifugation at 8000 x g for 5 min. The absorbance was measured at 517 nm. The

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assay was carried out in triplicate. The DPPH radical scavenging activity was

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calculated as follows (5):

N

(3)

∑ 

(4)



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DPPH Scavenging % =100 × (1- (As - Ab )/Ac )

(5)

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where As represents the absorbance of sample after film supernatant was added,

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Ab the absorbance of film supernatant alone and Ac the absorbance of control as

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distilled water was mixed with DPPH solution instead of sample.

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POV and TBARS of Sunflower Oil in Contact with or without Touching Films.

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Two methods were used to evaluate the antioxidant properties of films in contact with

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oil or above the headspace of the oil. The antioxidant properties of the films in contact

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with the oil was determined by the method of Bao, et al.13 The films were transformed

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into 4 cm x 4 cm bags by heat sealing and 1 mL of fresh sunflower oil was added to

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the bags. The antioxidant properties of the films placed over the headspace of the oil

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was determined according to Jongjareonrak, et al.4 and Wu, et al.26 10 mL of fresh

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sunflower oil was poured into a glass cell (30 mm diameter × 50 mm height) and

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covered with the film (4 cm × 4cm) sealed with glue and parafilm. All samples were

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stored in a humidity controlled chamber (53 ± 2% RH) at 28 °C. Samples for peroxide

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value (POV) and thiobarbituric acid reactive substances (TBARS) analysis were

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collected at intervals of 1 week over a period of 6 weeks. Samples without film

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packaging were also assessed as control.

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POV Analysis. POV was determined by AOCS Cd 8-53 Official Method.27 The

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amount of oil sample analyzed varied and depended on its oxidation degree. The oil

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sample was dissolved in 50 mL of a mixture of acetic acid/chloroform (3:2 v/v) within

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a 250 mL Erlenmeyer flask. Then saturated KI solution (0.5 mL) was added and the

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flask was allowed to stand for 1 min with occasional agitation. After addition of 11

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distilled water (50 mL), the mixture was titrated against sodium thiosulfate (0.01 M)

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with starch as an indicator. A blank titration was treated the same but without

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containing oil. POV (meq of oxygen/kg) was calculated using the following Formula

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(6):

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POV = 1000 × S × c/m

(6)

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In this formula, S is the volume of sodium thiosulfate solution (blank corrected)

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in mL; c is the normality of sodium thiosulfate solution and m is the weight of oil

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sample in grams.

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TBARS Analysis. TBARS were detected using AOCS Cd 19-90 method.28 The oil

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sample (50-200 mg) was solubilized in 10 mL of 1-butanol, mixed with 10 mL of 0.2%

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TBA in 1-butanol, heated at a 95 °C water bath for 2 h and rapidly cooled in an ice

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bath. The absorbance was measured at 532 nm against a corresponding blank

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(reaction with all the reagents and treatments except the oil). The standard curve was

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calculated from the TBARS reaction of a series of aliquots (0.1-1 mL) of 0.2 mM 1, 1,

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3, 3-tetra-ethoxypropane (95%) prepared in 1-butanol. The results were expressed as

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µmol malonaldehyde (MDA)/g of oil (n=3).

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Statistical Analysis. Data were presented as mean value ± standard deviation. The

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data were analyzed by one-way analysis of variance (ANOVA) using the SPSS 19.0

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package (IBM, New York). Duncan’s-multiple range test was used to determine the

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significant differences of the mean values (P