Native and Modified Starches as Matrix for Edible Films and Covers

S, Elevina E Pérez

doi:10.19080/nfsij.2017.03.555615

Cited by 8 publications

(6 citation statements)

References 73 publications

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“…Our results were in similarity to theirs that all coated fillets had lower PV than the control and shows that Gel/Ch coating could efficiently decrease lipid oxidation in fillets (Nowzari et al, 2013). It is demonstrated that chitosan, starch, and gelatin may be considered as the natural barriers against oxygen permeation and chitosan is presumed as a potential natural antioxidant for stabilizing lipid‐containing foods (Jonaidi Jafari et al, 2018; Perez Sira & Dufour, 2017).…”

Section: Resultsmentioning

confidence: 99%

Improving the quality of the chicken fillet using chitosan, gelatin, and starch coatings incorporated with bitter orange peel extract during refrigeration

Azizkhani,

Kavosi,

Partovi

2023

Food Science & Nutrition

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The preserving potential of biopolymer coatings can be improved by adding natural antimicrobial and antioxidant compounds. The objective of this study was to evaluate the effect of natural coatings (gelatin (Gel), chitosan (Ch), and modified starch (MS)) incorporated with bitter orange peel extract (BOE) on the quality of the chicken fillets during cold. BOE had a high amount of phenolic compounds (145.28 mgGAE/g). Coating the fillets with pure BOE exerted a higher inhibitory effect against bacterial growth compared to composite coatings without extract. Lower microbial count (2–3 log CFU/g on days 9 and 12 of storage) was observed in the samples coated with composite biopolymers incorporated with BOE in comparison to the coatings without BOE. Composite coatings of Gel/MS/BOE showed lower FFA in the fillets followed by Gel/Ch/BOE and MS/Ch/BOE. The lowest TVB‐N belonged to MS/Ch/BOE followed by Gel/Ch/BOE and Gel/MS/BOE which were 17.05, 17.39, and 19.40 mg/100 g at the end of the storage. Among the samples, pure BOE, Gel/MS/BOE, Gel/Ch/BOE, and MS/Ch/BOE showed the lowest peroxide value and the coatings containing chitosan had a slower rate of hydroperoxide generation. Drip loss showed a descending trend in all coated samples except for an enhancement in control and BOE‐coated fillets, 6.42% and 6.39%, respectively, on day 12 of storage. Samples coated with Gel/MS and Gel/MS/BOE had the lowest drip loss during the storage period (5.96% and 5.98%, respectively). It should be noted that coatings containing chitosan had higher antimicrobial and antioxidant effects. The effect of the coatings as antimicrobial barriers and preservative agents were as follows: Gel/Ch/BOE > MS/Ch/BOE > Gel/MS/BOE. It can be concluded that the applied composite coatings in this work have a high potential to maintain and improve the quality of raw chicken fillets during storage in the refrigerator.

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Section: Resultsmentioning

confidence: 99%

Improving the quality of the chicken fillet using chitosan, gelatin, and starch coatings incorporated with bitter orange peel extract during refrigeration

Azizkhani,

Kavosi,

Partovi

2023

Food Science & Nutrition

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“…Hydrogen bonds are responsible for the low mobility of starch molecules and, consequently, for the typical lower flexibility of these bioplastics when compared to conventional synthetic plastics [8]. This limitation can be fixed through the addition of plasticizers and organic substances incorporated in different concentrations into the starch gel to improve the film's mechanical properties.…”

Section: Starch-based Bioplastics Physicochemical Propertiesmentioning

confidence: 99%

“…Concurrently, there is a concerted effort to develop alternative products from renewable and natural resources that can degrade more quickly after disposal. In this context, eco-efficient packaging stands out, produced using materials that respect the ecological, economic, and social premises of sustainability, with a focus on polymers derived from biomass [8,9]. Apart from being sourced from inexhaustible supplies, these materials appear to be capable of ensuring the quality of both fresh and processed food products [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

From Fields to Films: Exploring Starch from Agriculture Raw Materials for Biopolymers in Sustainable Food Packaging

Gonçalves,

Silva,

Andrade

et al. 2024

Agriculture

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In the wake of escalating global concerns over the environmental impact of plastic pollution, there has been an unprecedented call for sustainable alternatives. The food-packaging industry, responsible for a staggering 40% of global plastic consumption, faces mounting challenges driven by environmental degradation and concerns about fossil fuel depletion. Motivated by these challenges, there is a growing interest in reducing reliance on traditional packaging and exploring eco-friendly solutions derived from renewable resources. Eco-efficient packaging, specifically derived from agricultural raw materials, emerges as a promising solution that aligns with ecological, economic, and social sustainability principles. Starch, abundant and versatile, emerges as a frontrunner among agricultural raw materials for biopolymers. Its inherent properties, including low cost, availability, biodegradability, and biocompatibility, make it a compelling choice. Starch-based bioplastics, with their potential to replace synthetic primary packaging materials, have gained traction due to their satisfactory mechanical and barrier properties. This review delves into the realm of starch-based films and coatings for food applications. It explores fundamental properties, advantages, and limitations, offering insights into potential improvements through various treatments or additive combinations. As technological advances drive the popularity of biodegradable starch-based packaging, this review aims to contribute to the ongoing discourse, providing a comprehensive overview and paving the way for more functional and widely applicable products in the ever-evolving landscape of sustainable packaging.

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“…The selection of a plasticizer for edible film/coating formulation should consider the adaptability and persistence of the plasticizer, as well as the required physical characteristics for the developed film/coating. Glycerol has been the plasticizer most frequently used to formulate films/coatings to be applied on fruit and vegetables [ 2 , 20 , 23 , 28 ], providing increased moisture content and gas permeability to these structures when compared to other plasticizers (e.g., sorbitol) [ 35 ].…”

Section: Materials Used To Formulate Probiotic-loaded Edible Films/coatings For Application To Fresh and Minimally Processed Fruit And Vementioning

confidence: 99%

Current Advances on the Development and Application of Probiotic-Loaded Edible Films and Coatings for the Bioprotection of Fresh and Minimally Processed Fruit and Vegetables

Oliveira

Fernandes

Souza

2021

Foods

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The application of probiotics has emerged as an innovative bioprotection technology to preserve fresh and minimally processed fruit and vegetables. This review discusses the most recent advances on the development and application of probiotic-loaded edible films/coatings as a strategy to preserve fresh or minimally processed fruit and vegetables. Available studies have shown a variety of materials, including hydrocolloids (polysaccharides and proteins) and lipids, used alone or in combination to formulate edible films/coatings loaded with probiotics. Plasticizers and surfactants are usually required to formulate these edible films/coatings. The reported antimicrobial effects of probiotic-loaded edible films/coating and quality parameters of coated fruit and vegetables could vary according to the characteristics of the materials used in their formulation, loaded probiotic strain and its dose. The antimicrobial effects of these films/coatings could be linked to the action of various metabolites produced by embedded probiotic cells with inhibitory effects on microorganisms contaminating fruit and vegetable surfaces. The implication of the use of probiotic-loaded edible films/coatings should be their antimicrobial effects against pathogenic and spoilage microorganisms and efficacy to control the ripening of fruit and vegetables, helping the coated products to maintain their safety, quality, nutritional and functional characteristics for a more prolonged storage period.

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Native and Modified Starches as Matrix for Edible Films and Covers

Cited by 8 publications

References 73 publications

Improving the quality of the chicken fillet using chitosan, gelatin, and starch coatings incorporated with bitter orange peel extract during refrigeration

Improving the quality of the chicken fillet using chitosan, gelatin, and starch coatings incorporated with bitter orange peel extract during refrigeration

From Fields to Films: Exploring Starch from Agriculture Raw Materials for Biopolymers in Sustainable Food Packaging

Current Advances on the Development and Application of Probiotic-Loaded Edible Films and Coatings for the Bioprotection of Fresh and Minimally Processed Fruit and Vegetables

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