Commentary - Journal of Food Technology and Preservation (2022) Volume 6, Issue 10

Antimicrobial nanofillers strengthened biopolymer composite for dynamic nourishment bundling applications.

Arash Moeini^*

Department of Biological and Agricultural Engineering, University Putra Malaysia, Selangor, Malaysia

*Corresponding Author:

Arash Moeini
Department of Biological and Agricultural Engineering
University Putra Malaysia, Selangor, Malaysia
Email: arashmoeini1@upm.edu.my

Received: 27-Sep-2022, Manuscript No. AAFTP-22-79404; Editor assigned: 29-Sep-2022, PreQC No. AAFTP-22-79404 (PQ); Reviewed: 13-Oct-2022, QC No. AAFTP-22-79404; Revised: 18-Oct-2022, Manuscript No. AAFTP-22-79404 (R); Published: 25-Oct-2022, DOI:10.35841/2591-796X-6.10.147

Citation: Moeini A. Antimicrobial nanofillers strengthened biopolymer composite for dynamic nourishment bundling applications. J Food Technol Pres. 2022;6(10):147

Abstract

Active nourishment bundling is pivotal these days due to the rising buyer requests for less handled and preservative-free nourishments. Too, due to developing concern and abuse of manufactured non-biodegradable polymers, there's rising intrigued in renewable biopolymer materials within the bundling framework. This survey comprehensively talks about the status of feasible biopolymer-based utilitarian movies joined with different antimicrobial nanofillers for dynamic nourishment bundling applications.

Keywords

Biodegradable polymers, Antimicrobial nanofillers, Renewable biopolymer materials.

Introduction

The utilization of these nanofillers straightforwardly in bundling materials deflects the utilize of additives in nourishment. Subsequently, this survey fundamentally centers on the later inquire about headways including the utilization of antimicrobial nanofillers in biopolymeric nourishment bundling materials. The biopolymers, primarily polysaccharides, protein, and engineered polyestersbased, started from different sources like plants, creatures, or microorganisms are briefly surveyed. Advance, the antimicrobial nanofillers utilized within the planning of biobased composites is comprehensively examined. The later advance on utilizing different biopolymeric nanocomposites in antimicrobial nourishment bundling is additionally summarized. At long last, the issues related to security concerns approximately the utilize of bio-based nanocomposite are too briefly expressed [1].

The reason of this chapter is to conduct a organized and efficient survey of distributed writing on the current state of information with respect to silver-based antimicrobial bundling; in specific, the antibacterial capacity of silver nanoparticles (AgNPs) has been compiled in this chapter. The discharge energy and antimicrobial properties of AgNPs consolidated into biobased polymers such as polylactic corrosive and polyhydroxyalkanoates have been broadly looked into. Furthermore, enteric infections are a developing concern in numerous ranges, particularly in nourishments. This chapter audits the utilization of silver to battle enteric infections [2].

The thermoplastic arrowroot starch and biocomposite movies were effectively created utilizing the arrangement casting method. The expansion of arrowroot fiber into biopolymer movies appeared change in water vapor penetrability, and straight burning rate of biocomposite films. The arrowroot fiber strengthened biocomposite movies appeared way better warm solidness than the thermoplastic film. The expansion of arrowroot fiber into thermoplastic biopolymer film quickened the biodegradation handle of biocomposite movies. Biopolymeric composites are maintainable, ecofriendly, and green bundling materials. Bio-nanocomposites move forward boundary and mechanical properties of the nourishment bundling films. Bio-nanocomposites movies have antioxidant and antimicrobial characteristics. Biopolymeric composites decrease nourishment decay and natural contamination [3].

Dynamic bundling could be an unused nourishment bundling pathway centering on a multifunctional framework to expand the nourishment shelf-life. Biopolymers can be an elective for manufactured polymer within the nourishment bundling industry. Biopolymers in nourishment packaging are classified as thermoplastic polymers and hydroplastic. Plants and Parasitic are the most source of dynamic auxiliary metabolites. The bioactive normal metabolites with plenteous highlights such as antibacterial, antioxidant, and plasticizer can impact nourishment bundling [4,5].

Conclusion

Biopolymers can be considered a substantial elective to engineered polymers within the nourishment bundling industry since their biodegradability, biocompatibility, simple renewability, and for the most part great mechanical properties, comparable with the ones of routine polymers. Natural auxiliary metabolites determined from plants and organisms have attracted much consideration within the nourishment bundling industry since of their both antimicrobial and antioxidant action and positive impact on biofilm mechanical exhibitions.

References

1. Shank FR, Carson K. The regulatory environment past and future-incentive or impediment to developments in food science and technology: A perspective from FDA. Crit Rev Food Sci Nutr. 1994;34(2):207-14.

Indexed at, Google Scholar, Cross Ref

2. Cha DS, Chinnan MS. Biopolymer-based antimicrobial packaging: a review. Crit Rev Food Sci Nutr. 2004;44(4):223-37.

Indexed at, Google Scholar, Cross Ref

3. Christensen CM. An enduring legacy: Dr. Alina Szczesniak's classification of food texture. J Texture Stud. 2018;49(2):146-149.

Indexed at, Google Scholar, Cross Ref

4. Xiong Z, Xie A, Sun DW. Applications of hyperspectral imaging in chicken meat safety and quality detection and evaluation: A review. Crit Rev Food Sci Nutr. 2015;55(9):1287-301.

Indexed at, Google Scholar, Cross Ref

5. ElMasry G, Barbin DF, Sun DW. Meat quality evaluation by hyperspectral imaging technique: an overview. Crit Rev Food Sci Nutr. 2012;52(8):689-711.

Indexed at, Google Scholar, Cross Ref