Enhancing hydrophobicity, strength and UV shielding capacity of starch film via novel co-cross-linking in neutral conditions

Ni, Shuzhen; Ji, Liang; Zhang, Hui; Zhang, Yong‐Chao; Fang, Guigan; Xiao, Huining

doi:10.1098/rsos.181206

Cited by 21 publications

(6 citation statements)

References 36 publications

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“…Starch is considered one of the most promising green packaging materials [7,8]. However, pure starch film has the disadvantages of a high brittleness, low mechanical properties, and poor water blocking performance, which limit its further development [9,10]. In recent years, to improve the strength and barrier properties of Nanomaterials 2020, 10, 755 3 of 19…”

Section: Introductionmentioning

confidence: 99%

Preparation and Properties of Cassava Residue Cellulose Nanofibril/Cassava Starch Composite Films

Huang

Zhao

et al. 2020

Nanomaterials

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Because of its non-toxic, pollution-free, and low-cost advantages, environmentally-friendly packaging is receiving widespread attention. However, using simple technology to prepare environmentally-friendly packaging with excellent comprehensive performance is a difficult problem faced by the world. This paper reports a very simple and environmentally-friendly method. The hydroxyl groups of cellulose nanofibrils (CNFs) were modified by introducing malic acid and the silane coupling agent KH-550, and the modified CNF were added to cassava starch as a reinforcing agent to prepare film with excellent mechanical, hydrophobic, and barrier properties. In addition, due to the addition of malic acid and a silane coupling agent, the dispersibility and thermal stability of the modified CNFs became significantly better. By adjusting the order of adding the modifiers, the hydrophobicity of the CNFs and thermal stability were increased by 53.5% and 36.9% ± 2.7%, respectively. At the same time, the addition of modified CNFs increased the tensile strength, hydrophobicity, and water vapor transmission coefficient of the starch-based composite films by 1034%, 129.4%, and 35.95%, respectively. This material can be widely used in the packaging of food, cosmetics, pharmaceuticals, and medical consumables.Nanomaterials 2020, 10, 755 2 of 19 starch films, researchers have often added different types of enhancers to starch film to improve its strength [11][12][13][14]. Cellulose nanofibril (CNF) has become an ideal starch film enhancer due to its low cost, low density, renewability, recyclability, high surface area, chemical reactivity, strength, modulus, elasticity, transparency, tensile rigidity, light weight, low thermal expansion, and biodegradability (due to its nano-size characteristics) [15][16][17].Cellulose nanofibril comes from various sources of natural fibers, such as cotton, wood, corn cobs, sisal, wheat straw, flax, bamboo, rice husks, pea husks, coconut shells, bagasse, and cassava residues. However, CNF is hydrophilic and absorbs moisture when exposed [18]. Therefore, the surface hydrophobicity of CNF can be changed using various chemical modification techniques, thereby improving the compatibility and dispersibility of CNF in specific solvents [19]. Through phosphorylation, carboxymethylation, oxidation and sulfonation reactions, ionic charge can be introduced to the surface of cellulose [20-23]; esterification, silylation, amidation, urethanation, and etherification can make the cellulose surface hydrophobic [24][25][26]. In summary, no matter what surface chemistry is ultimately required, the modification technology depends almost entirely on the reaction of the hydroxyl groups on the surface of the CNF. The challenge for these chemical modification technologies is to change only the surface of the CNF, maintaining its original morphology and the complex structure of its internal hydroxyl groups.Wei et al. extracted CNF from oil palm waste by acid hydrolysis using natural lime juice as a cross-linking agent. The struc...

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Section: Introductionmentioning

confidence: 99%

Preparation and Properties of Cassava Residue Cellulose Nanofibril/Cassava Starch Composite Films

Huang

Zhao

et al. 2020

Nanomaterials

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“…[ 54 ] Hence, reducing the starch hydrophilicity helps a lot to use TPS in various biodegradable targets, particularly containers production. [ 55 ] Chemical modification of native starch via the reaction of its hydroxyl groups with functional groups of the reagent to reduce the OH groups of the chains can decrease the hydrophilicity of starch and as well as the starch crystallinity significantly. [ 56 ] In this work, we studied the impact of the chemical and physical modification agents on the hydrophobicity behavior of the modified starches via measuring its moisture absorption amount.…”

Section: Resultsmentioning

confidence: 99%

Thermal Characteristics, Kinetics and Thermodynamics of Thermal Degradation Reaction, and Hydrophobicity of Corn Starch Affected by Chemical and Physical Modifications

2022

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In this work, glacial‐acetic (A) and citric (C) acids from organic acids “family with one and three functional groups, respectively", oleic acid (O) from the fatty acids family and sodium acetate (S) are used for esterification of corn starch in solution in the absence and the presence of 15%wt glycerin as a physical modifier. Discoloration test using CIELAB and as well as thermal gravimetric analysis shows that the glacial‐acetic acid leads to lower reduction in thermal characteristics of the modified starch. The variations of thermal properties start from T > 112 °C, T>136 °C, T>100 °C, and T> 124 °C for the modified starches with C, A, O, and S reagents, respectively, and the changes are constant beyond the amount of 4%wt reagent. The evaluations of kinetics and thermodynamics of thermal degradation reaction for the modified starches via a Coats–Redfern (CR) model prove that the acetic acid causes more activation energy for degradation compared to other reagents. Also, acetic acid‐modified starch demonstrates the highest hydrophobicity among other modified starches – even native starch – in the moisture sorption examination at 75% relative humidity (RH). The results illustrate that glycerin has the worst effect on the thermal and hydrophobicity properties of the modified starches.

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“…[ 139 ]. Cassava bagasse also contains residual starch, fibers, 37% hemicellulose, and 38% cellulose and lignin [ 140 ]. Cassava peel and bagasse are being produced in huge quantities by the cassava starch industry.…”

Section: Cassava Fibermentioning

confidence: 99%

Recent Developments in Cassava (Manihot esculenta) Based Biocomposites and Their Potential Industrial Applications: A Comprehensive Review

et al. 2022

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The rapid use of petroleum resources coupled with increased awareness of global environmental problems associated with the use of petroleum-based plastics is a major driving force in the acceptance of natural fibers and biopolymers as green materials. Because of their environmentally friendly and sustainable nature, natural fibers and biopolymers have gained significant attention from scientists and industries. Cassava (Manihot esculenta) is a plant that has various purposes for use. It is the primary source of food in many countries and is also used in the production of biocomposites, biopolymers, and biofibers. Starch from cassava can be plasticized, reinforced with fibers, or blended with other polymers to strengthen their properties. Besides that, it is currently used as a raw material for bioethanol and renewable energy production. This comprehensive review paper explains the latest developments in bioethanol compounds from cassava and gives a detailed report on macro and nano-sized cassava fibers and starch, and their fabrication as blend polymers, biocomposites, and hybrid composites. The review also highlights the potential utilization of cassava fibers and biopolymers for industrial applications such as food, bioenergy, packaging, automotive, and others.

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Enhancing hydrophobicity, strength and UV shielding capacity of starch film via novel co-cross-linking in neutral conditions

Cited by 21 publications

References 36 publications

Preparation and Properties of Cassava Residue Cellulose Nanofibril/Cassava Starch Composite Films

Preparation and Properties of Cassava Residue Cellulose Nanofibril/Cassava Starch Composite Films

Thermal Characteristics, Kinetics and Thermodynamics of Thermal Degradation Reaction, and Hydrophobicity of Corn Starch Affected by Chemical and Physical Modifications

Recent Developments in Cassava (Manihot esculenta) Based Biocomposites and Their Potential Industrial Applications: A Comprehensive Review

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