Mechanical and Thermal Behavior of Canola Protein Isolate Films As Improved by Cellulose Nanocrystals

Osorio-Ruiz, Alex; Avena‐Bustillos, Roberto J.; Chiou, Bor‐Sen; Rodríguez-González, Francisco; Martínez-Ayala, Alma-Leticia

doi:10.1021/acsomega.9b02460

Cited by 16 publications

(15 citation statements)

References 31 publications

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“…All the films exhibited a three-step weight loss profile similar to other proteins. , The initial weight loss from 30 to about 150 °C was due to the evaporation of moisture. The weight loss in the second stage in the range 150–250 °C was attributed to mainly the loss of a glycerol plasticizer (the boiling point of glycerol is ∼290 °C), and the third stage weight loss from 250–400 °C was due to the degradation of the residual material, rich in protein. , There is a slightly enhanced thermal stability in the films pressed at higher temperature, and for a longer time, it is more clearly visible in the first-derivative plot (Figure ). This appeared because the weight loss of glycerol shifted to higher temperature, suggesting the formation of intermolecular interactions between glycerol and amino acid groups at elevated temperatures and longer pressing time.…”

Section: Results and Discussionmentioning

confidence: 75%

“…The weight loss in the second stage in the range 150−250 °C was attributed to mainly the loss of a glycerol plasticizer (the boiling point of glycerol is ∼290 °C), and the third stage weight loss from 250−400 °C was due to the degradation of the residual material, rich in protein. 39,40 There is a slightly enhanced thermal stability in the films pressed at higher temperature, and for a longer time, it is more clearly visible in the first-derivative plot (Figure 4). This appeared because the weight loss of glycerol shifted to higher temperature, suggesting the formation of intermolecular interactions between glycerol and amino acid groups at elevated temperatures and longer pressing time.…”

Section: Resultsmentioning

confidence: 95%

“…All the films exhibited a three-step weight loss profile similar to other proteins. 39,40 The initial weight loss from 30 to about 150 °C was due to the evaporation of moisture. The weight loss in the second stage in the range 150−250 °C was attributed to mainly the loss of a glycerol plasticizer (the boiling point of glycerol is ∼290 °C), and the third stage weight loss from 250−400 °C was due to the degradation of the residual material, rich in protein.…”

Section: Resultsmentioning

confidence: 99%

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Novel Bioplastic from Single Cell Protein as a Potential Packaging Material

Singha

Mahmutovic

Zamalloa

et al. 2021

ACS Sustainable Chem. Eng.

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Microbial treatment of biodegradable wastes not only ensures neutralization of harmful substances such as volatile organic compounds but also enables valorization and biocircularity within the society. Single cell protein (SCP) is a value-added product that can be obtained from biodegradable waste materials such as food waste via microbial fermentation. In this article, SCP derived from potato starch waste was demonstrated as a viable alternative to existing plant/animal proteins used in the production of films, for example, packaging applications. Flexible glycerol-plasticized SCP films were prepared through compression molding, and tensile tests revealed strength and stiffness similar to other plasticized protein films. The oxygen barrier properties were significantly better compared to the common polyethylene packaging material, but as with other highly polar materials, the SCP material must be shielded from moisture if used in, for example, food packaging. The biodegradation test revealed a similar degradation pattern as observed for a household compostable bag. The results showed that SCP-based bioplastic films can be considered as potential alternative to the existing plant/animal protein films and certain synthetic polymers. An important advantage with these protein materials is that they do not cause problems similar to microplastics.

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Section: Results and Discussionmentioning

confidence: 75%

Section: Resultsmentioning

confidence: 95%

Section: Resultsmentioning

confidence: 99%

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Novel Bioplastic from Single Cell Protein as a Potential Packaging Material

Singha

Mahmutovic

Zamalloa

et al. 2021

ACS Sustainable Chem. Eng.

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“…Water could interact with the hydroxyl groups of cellulose via hydrogen bonds. The second stage of mass loss occurred between 300 to 350 • C. This weight loss was the main degradation and was related to the degradation of cellulose [54]. In the case of the glycerol-mixed SBG films, three degradation stages were observed.…”

Section: Thermal Stabilitymentioning

confidence: 96%

Valorization of Cellulose-Based Materials from Agricultural Waste: Comparison between Sugarcane Bagasse and Rice Straw

2023

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Sugarcane bagasse and rice straw are major agricultural byproducts often discarded or burned as waste after cultivation, leaving their untapped potential for utilization. In this work, cellulose fibers were extracted from sugarcane bagasse and rice straw using a simple procedure: alkaline treatment with sodium hydroxide, bleaching with sodium hypochlorite, and acid hydrolysis. The obtained cellulosic materials were successfully prepared into milky white and transparent films, of which the transparency slightly decreased with the addition of glycerol. The surface of all the films appeared homogeneous with a random orientation of fibers. The rice-straw (RS) film had a more fragile texture than the sugarcane-bagasse (SBG) film. The FTIR analysis clearly indicated the functional groups of cellulose, as well as glycerol for the films mixed with glycerol. Thermal analysis showed that the native SBG film decomposed at 346 °C, higher than the native RS film (339 °C). The presence of glycerol in the films resulted in slightly lower maximum decomposition temperature (Td,max) values as well as mechanical properties. Regarding water susceptibility, the RS film had a higher percentage than the native SBG and glycerol-mixed SBG films. The extracted cellulose from both sources could form almost spherical-shaped cellulose particles. Thus, through the simple extraction method, sugarcane bagasse and rice straw could serve as excellent sources of cellulose materials for preparing cellulose films and particles, which would be advantageous to the development of cellulose-based materials.

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“…Plant-based proteins derived from peas, beans, kernels, legumes and agro-waste have been used for preparing membranes and 89 Enhanced Low Enhanced Not reported Food packaging Canola 90 Enhanced Not reported Enhanced Not reported Food packaging Sunflower 91 Enhanced Low Not reported Enhanced Fresh fruit packaging Flax seed 92 Enhanced Low Enhanced Not reported Antimicrobial food packaging film Rape seed 93 Enhanced Not reported Not reported Not reported Edible food coating Castor bean 94 Review Materials Advances coatings. 67,[72][73][74] The presence of various amino acids and active binding sites in proteins helps to form molecular networks, providing desired elasticity or plasticity for preparing biopolymer membranes.…”

Section: Plant-based Sources For Biomaterialsmentioning

confidence: 99%