Emerging Food Packaging Applications of Cellulose Nanocomposites: A Review

Li, Jingwen; Zhang, Feifan; Zhong, Yaqi; Zhao, Yadong; Gao, Pingping; Tian, Fang; Zhang, Xianhui; Zhou, Rusen; Cullen, Patrick J.

doi:10.3390/polym14194025

Cited by 45 publications

(16 citation statements)

References 174 publications

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“…Regarding the progress of cellulose and its derivatives in the food industry, especially packaging, the following should be mentioned [89,90]:…”

Section: Innovations Of the Cellulosic Application In The Food Industrymentioning

confidence: 99%

Perspective Chapter: Cellulose in Food Production – Principles and Innovations

Sabbaghi¹

2023

Cellulose - Fundamentals and Conversion Into Biofuel and Useful Chemicals

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For several decades, cellulose and its derivatives have been used in various fields of food processing and their applications have become increasingly important. Nutritionally, cellulose is known as dietary fiber and is used as a functional food component. Many new technological needs were recognized since developing of industrial products and, therefore, cellulose modifications (chemically or physically) also have been considered. The various important properties for using these compounds include organic solubility, gel and film formation ability, make mucoadhesive system, high swelling, hydrophilic and hydrophobic features, act as viscosifying agent, and thermoplastic effects in food systems. Thus, the most typical technological role of these cellulose’s characteristics can be mentioned as edible coating (in fruits and fried products), edible film, emulsification, stabilizing agent, rheology control, suspending agent, diffusion barrier, encapsulation, extrusion, molding, and foam stabilizer in food industry. The new innovations can be mentioned as the production of bacterial cellulose, developing the smart packaging, and the preparation of nanocellulose with environmentally friendly processes. Finally, with the expansion of the usage of cellulosic materials, a reevaluation of their food safety has been carried out. Also, the legal guidelines related to the use of these compounds as raw materials have been provided for manufacturers.

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“…Regarding the progress of cellulose and its derivatives in the food industry, especially packaging, the following should be mentioned [89,90]:…”

Section: Innovations Of the Cellulosic Application In The Food Industrymentioning

confidence: 99%

Perspective Chapter: Cellulose in Food Production – Principles and Innovations

Sabbaghi¹

2023

Cellulose - Fundamentals and Conversion Into Biofuel and Useful Chemicals

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“…Cellulose is the most abundant natural biomass polymer, mainly found in cotton, wood, flax, and grass cell walls. , Based on its eco-friendly, nontoxic, inexpensive, renewable, biodegradable, and biocompatible characteristics, cellulose provides a practical solution to the environmental problems associated with the consumption of petroleum-based raw materials (e.g., difficult to degrade, greenhouse gas emissions, difficult to recycle) and can be used in the processing and preparation of antimicrobial polymers. , Due to the presence of a large number of active hydroxyl groups on the chain segments of cellulose molecules, , nonionic antimicrobial polymers with effective antimicrobial functions can be produced by covalently cross-linking small antimicrobial molecules commonly found in nature (curcumin, limonene, aspirin, and indole derivatives) , to the main chain of cellulose molecules. Unlike traditional ionic antimicrobial agents, nonionic antimicrobial agents interact with bacterial cell films through hydrogen-bonding and hydrophobic or dipole–dipole interactions to achieve the inhibition of bacterial population sensing behavior and sustained bactericidal activity. , Indole derivatives are small, nonionic molecules of plant origin that are abundant in nature and household waste.…”

Section: Introductionmentioning

confidence: 99%

Eco-Friendly Cellulose-Based Nonionic Antimicrobial Polymers with Excellent Biocompatibility, Nonleachability, and Polymer Miscibility

Dang,

Yu,

Wang

et al. 2023

ACS Appl. Mater. Interfaces

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This study aims to prepare natural biomass-based nonionic antimicrobial polymers with excellent biocompatibility, nonleachability, antimicrobial activity, and polymer miscibility. Two new cellulose-based nonionic antimicrobial polymers (MIPA and MICA) containing many terminal indole groups were synthesized using a sustainable one-pot method. The structures and properties of the nonionic antimicrobial polymers were characterized using nuclear magnetic resonance hydrogen spectroscopy ( 1 H NMR), infrared spectroscopy (FTIR), wide-angle X-ray diffractometry (XRD), thermogravimetric analysis (TGA), differential scanning calorimetry (DSC), scanning electron microscopy (SEM), gel chromatography (GPC), and other analytical techniques. The results showed that microcrystalline cellulose (MCC) molecules combined with indole derivatives through an esterification reaction to produce MICA and MIPA. The crystallinity of the prepared MICA and MIPA molecules decreased after MCC modification; their morphological structure changed from short fibrous to granular and showed better thermal stability and solubility. The paper diffusion method showed that both nonionic polymers had good bactericidal effects against the two common pathogenic bacteria Escherichia coli (E. coli, inhibition zone diameters >22 mm) and Staphylococcus aureus (S. aureus, inhibition zone diameters >38 mm). Moreover, MICA and MIPA showed good miscibility with biodegradable poly(vinyl alcohol) (PVA), and the miscible cellulose-based composite films (PVA-MICA and PVA-MIPA) showed good phase compatibility, light transmission, thermal stability (maximum thermal decomposition temperature >300 °C), biocompatibility, biological cell activity (no cytotoxicity), nonleachability, antimicrobial activity, and mechanical properties (maximum fracture elongation at >390%).

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“…The prepared nanofiber membrane has excellent properties such as high specific surface area, porosity, permeability, good biocompatibility, and degradability [ 9 ]. At the same time, electrospinning technology is a non-thermal processing technology, which has broad application prospects in food [ 10 ]. However, it is restricted by the viscoelasticity, surface tension, conductivity, and other properties of the raw materials.…”

Section: Introductionmentioning

confidence: 99%

Preparation, Properties and Application in Electrospinning of Tremella Polysaccharide–Protein Complex

Zhao

Wang

Liu

et al. 2023

Foods

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In this paper, the effects of different proteins (soybean protein isolate, wheat protein hydrolysate, tremella protein) on the activity of tremella polysaccharide under different conditions were studied. The optimal protein–polysaccharide complex was determined by grafting degree and activity screening, and the microstructure and rheological properties were studied. The results showed that when the ratio of soybean protein isolate to tremella polysaccharide was 2:1 and the solution pH was 7, the optimal complex was obtained by heating at 90 °C for 4 h, and its grafting degree and antioxidant activity were the best. Studies have shown that tremella polysaccharide and soybean protein isolate complex (TFP-SPI) solution is pseudoplastic fluids. At the same time, tremella polysaccharide (TFP) and TFP-SPI were used for electrospinning to observe its spinnability. When the ratio of PVA/TFP-SPI/PL was 8:1:1, nanofibers with uniform diameter and good morphology were obtained. This paper provides a theoretical basis for the comprehensive utilization of tremella polysaccharide and its electrospun fiber can be used as active film for food packaging.

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Emerging Food Packaging Applications of Cellulose Nanocomposites: A Review

Cited by 45 publications

References 174 publications

Perspective Chapter: Cellulose in Food Production – Principles and Innovations

Perspective Chapter: Cellulose in Food Production – Principles and Innovations

Eco-Friendly Cellulose-Based Nonionic Antimicrobial Polymers with Excellent Biocompatibility, Nonleachability, and Polymer Miscibility

Preparation, Properties and Application in Electrospinning of Tremella Polysaccharide–Protein Complex

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