Nanostructural Morphology of Plasticized Wheat Gluten and Modified Potato Starch Composites: Relationship to Mechanical and Barrier Properties

Muneer, Faraz; Andersson, Mariette; Koch, Kristine; Menzel, Carolin; Hedenqvist, Mikael S.; Gällstedt, Mikael; Plivelic, Tomás S.; Kuktaite, Ramune

doi:10.1021/bm5017496

Cited by 30 publications

(40 citation statements)

References 43 publications

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“…As shown in previous studies [5,10,12,31,32,33], the non-modified WG powder showed relatively low amounts of β-sheets, as indicated by a flat shoulder in the amide I region (1620–1625 cm −1 ), while peaks at 1660, 1650 and 1641 cm −1 verified the presence of α-helices, α-helices and random coils, and unordered structures, respectively (Figure 3a). Chemical modification of the WG protein (MWG sample) resulted in a slight decrease in the intensity of peaks in the region 1640–1660 cm −1 , indicating that some of either α-helices, α-helices and random coils, or unordered structures became involved in formation of strong hydrogen bonded β-sheets (Figure 3a).…”

Section: Resultssupporting

confidence: 71%

Impact of pH Modification on Protein Polymerization and Structure–Function Relationships in Potato Protein and Wheat Gluten Composites

Muneer

Johansson

Hedenqvist

et al. 2018

IJMS

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Wheat gluten (WG) and potato protein (PP) were modified to a basic pH by NaOH to impact macromolecular and structural properties. Films were processed by compression molding (at 130 and 150 °C) of WG, PP, their chemically modified versions (MWG, MPP) and of their blends in different ratios to study the impact of chemical modification on structure, processing and tensile properties. The modification changed the molecular and secondary structure of both protein powders, through unfolding and re-polymerization, resulting in less cross-linked proteins. The β-sheet formation due to NaOH modification increased for WG and decreased for PP. Processing resulted in cross-linking of the proteins, shown by a decrease in extractability; to a higher degree for WG than for PP, despite higher β-sheet content in PP. Compression molding of MPP resulted in an increase in protein cross-linking and improved maximum stress and extensibility as compared to PP at 130 °C. The highest degree of cross-linking with improved maximum stress and extensibility was found for WG/MPP blends compared to WG/PP and MWG/MPP at 130 °C. To conclude, chemical modification of PP changed the protein structures produced under harsh industrial conditions and made the protein more reactive and attractive for use in bio-based materials processing, no such positive gains were seen for WG.

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Section: Resultssupporting

confidence: 71%

Impact of pH Modification on Protein Polymerization and Structure–Function Relationships in Potato Protein and Wheat Gluten Composites

Muneer

Johansson

Hedenqvist

et al. 2018

IJMS

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“…The peak appeared at 2 θ = 16.86° was found to vanish in the composites (curve 1b–1e) which might be due to crosslinking effect of citric acid with wood, MMA‐ g ‐SG and glycerol. The peak intensity corresponding to cellulose became broad due to high protein concentration in starch gluten blend . The high protein concentration increased the cross‐linking reaction between citric acid and the amine groups of gluten protein and thus decreased the crystallinity .…”

Section: Resultsmentioning

confidence: 99%

“…Besides this, gluten finds it use in the composite due to its good adhesive properties . The use of higher percentage of gluten in the preparation of the composites has some negative effect like decrease in the mechanical properties .…”

Section: Introductionmentioning

confidence: 99%

Biodegradability, flammability, dimensional stability, and UV resistance study of green wood starch gluten nanocomposites

2017

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Biodegradable and UV resistant wood starch gluten nanocomposites (WSGNC) were prepared successfully from the natural polymers like starch and gluten, natural crosslinker and natural solvent via a green route using solution blending technique followed by compression molding. In this procedure, the starch gluten (50/50) blend was grafted with methyl methacrylate (MMA-g-SG) and citric acid was used to crosslink the MMA-g-SG with wood flour from Ipomoea carnea using water as a solvent. Later, Nano TiO 2 was added in the composites to improve the properties like UV stability and flammability. The effects of TiO 2 nanoparticles on biodegradability and UV stability of the composites were thoroughly investigated. The bacterial growth on the samples was analyzed by UV spectrophotometry and morphological features of the bacterial degraded samples was investigated by SEM study. The UV-degraded samples were analyzed by FTIR and SEM study. It was observed that the incorporation of 3 phr TiO 2 in the composites significantly improved the UV stability and hardness values of the composites. The flammability and dimensional stability of the nanocomposite were also improved with 3 phr nano TiO 2 loading compared to TiO 2 -untreated composites. POLYM.

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“…Starch is among the most promising natural polymers because of its renewability, biodegradability, abundance, low cost, film‐forming properties, and ease of modification . Nevertheless, native starch without modification is not suitable for most polymer applications.…”

Section: Introductionmentioning

confidence: 99%

Hydrophobic and Melt Processable Starch‐Laurate Esters: Synthesis, Structure–Property Correlations

Ojogbo

Blanchard

Mekonnen

2018

J. Polym. Sci. Part A: Polym. Chem.

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A controlled esterification of starch to replace the OH moieties with bio-derived medium chain fatty acids, and the changes in the polymer structure and properties for material applications is investigated in this research. The esterification is conducted via a homogeneous esterification process using an activated lauric acid (C 12 ) in the presence of a base catalyst. The degree of esterification through the replacement of hydroxyl groups of starch was estimated using elemental analysis (EA) and proton NMR. The effect of the modification on the structural and material properties of the modified starch polymer is elucidated by evaluating the changes in morphology, network thermal stability, hydrophobicity, solubility profile, and thermal transition events. Scanning electron microscopy imaging reveals structural changes ranging from surface roughness to complete disruption depending on the degree of substitution. This is confirmed by XRD. Because of the esterification of starch, the resulting polymers become melt processable thermoplastic that forms a transparent film with an elastic storage modulus of up to 226 MPa at room temperature. This shows that the starch-fatty acid polymer can be used for various industrial and advanced material applications without any other plasticizers or modifiers. The final material is completely bio-based, and is expected to be biodegradable in the environment.Among the various modifications, thermoplastic starch has attracted the most attention because of the ease and low cost of the process. However, leaching out of external plasticizers, water sensitivity, premature aging caused by re-crystallization, brittleness, and too fast biodegradation 9-11 have limited Additional supporting information may be found in the online version of this article.

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Nanostructural Morphology of Plasticized Wheat Gluten and Modified Potato Starch Composites: Relationship to Mechanical and Barrier Properties

Cited by 30 publications

References 43 publications

Impact of pH Modification on Protein Polymerization and Structure–Function Relationships in Potato Protein and Wheat Gluten Composites

Impact of pH Modification on Protein Polymerization and Structure–Function Relationships in Potato Protein and Wheat Gluten Composites

Biodegradability, flammability, dimensional stability, and UV resistance study of green wood starch gluten nanocomposites

Hydrophobic and Melt Processable Starch‐Laurate Esters: Synthesis, Structure–Property Correlations

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