Designing New Materials from Wheat Protein

Woerdeman, Dara L.; Veraverbeke, Wim S.; Parnas, Richard S.; Johnson, D.; Delcour, Jan A.; Verpoest, Ignaas; Plummer, C. J. G.

doi:10.1021/bm034530+

Cited by 89 publications

(113 citation statements)

References 27 publications

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“…Plastics can be produced from zein (the major corn protein; Lawton, 2002;Shukla and Cheryan, 2001), soy protein (Mohanty et al, 2005) and wheat gluten (Pallos et al, 2006;Woerdeman et al, 2004) by cross-linking with glutaraldehyde, formaldehyde or other chemicals. In 1950, about 2700 tonnes year )1 of zein plastic, a glossy, scuff-proof, grease-proof material for coatings, was produced along with 2200 tonnes year )1 of Vicara Ò , a fiber that is also based on zein.…”

Section: Protein Co-products Of Biofuelsmentioning

confidence: 99%

Production of renewable polymers from crop plants

Beilen

Poirier²

2008

The Plant Journal

140

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SummaryPlants produce a range of biopolymers for purposes such as maintenance of structural integrity, carbon storage, and defense against pathogens and desiccation. Several of these natural polymers are used by humans as food and materials, and increasingly as an energy carrier. In this review, we focus on plant biopolymers that are used as materials in bulk applications, such as plastics and elastomers, in the context of depleting resources and climate change, and consider technical and scientific bottlenecks in the production of novel or improved materials in transgenic or alternative crop plants. The biopolymers discussed are natural rubber and several polymers that are not naturally produced in plants, such as polyhydroxyalkanoates, fibrous proteins and poly-amino acids. In addition, monomers or precursors for the chemical synthesis of biopolymers, such as 4-hydroxybenzoate, itaconic acid, fructose and sorbitol, are discussed briefly.

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Section: Protein Co-products Of Biofuelsmentioning

confidence: 99%

Production of renewable polymers from crop plants

Beilen

Poirier²

2008

The Plant Journal

140

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“…Wheat gluten and PLA fibers were heated in water at 90°C for 60 min in various pH (3,5,7,9, and 11) conditions to test their stability. The hot water treated fibers were tested and compared to the untreated controls for the changes in tensile properties.…”

Section: Methodsmentioning

confidence: 99%

“…With a selling price of less than $0.50 per pound, and a worldwide availability of 500 000 tons every year, wheat gluten is a cheap, abundant, and renewable source for producing protein fibers. [1][2][3] In addition, wheat gluten has good stability to water and heat, excellent elasticity, and easy degradability, properties that are desirable for fibers. [3][4][5] The annual world fiber market is about 67 million tons including about 2.3 million tons of the two natural protein fibers, wool and silk.…”

Section: Introductionmentioning

confidence: 99%

Novel Protein Fibers from Wheat Gluten

Reddy

Yang

2007

Biomacromolecules

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Protein fibers with mechanical properties similar to those of wool and better than those of soyprotein and zein fibers have been produced from 100% wheat gluten. Wheat gluten is a low cost, abundantly available, and renewable resource suitable for fiber production. A simple production method has been developed to obtain high-quality wheat gluten fibers, and the structure and properties of the fibers have been studied. Wheat gluten fibers have breaking tenacity of about 115 MPa, breaking elongation of 23%, and a Young's modulus of 5 GPa, similar to those of wool. Wheat gluten fibers have better tensile properties than soyprotein-and casein-based biomaterials. In addition, the wheat gluten fibers have resistance similar to that of PLA fibers to water in weak alkaline and slightly lower resistance in weak acidic conditions at high temperatures.

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“…The need for environmentally friendly, renewable and biodegradable plastics is increasing due to pollution and long term health impacts of synthetic polymers (Zhang et al, 2010;Sun et al, 2008); possess suitable gas barrier properties and nutritional value (Lagrain et al, 2010;Cao et al, 2007); poor moisture barrier properties due to its hygroscopic nature; binds with water through hydrogen bridges modified by thermal and chemical treatments (Sun et al, 2008;Carvalho et al, 2008;Brauer et al, 2007;Dicharry et al, 2006;Gallstedt et al, 2004;Domenek et al, 2004;Woerdeman et al, 2004). The effect of processing on gluten network formation is determined by the SDS extractability which measures the degree of polymerization: the lower the extractability the higher the degree of polymerization (Sun et al 2008;Gallstedt et al, 2004;Domenek et al, 2004;Pommet et al, 2003;Micard et al, 2001;Cuq et al, 2000).…”

Section: Gluten Bioplastic Formationmentioning

confidence: 99%

“…The effect of processing on gluten network formation is determined by the SDS extractability which measures the degree of polymerization: the lower the extractability the higher the degree of polymerization (Sun et al 2008;Gallstedt et al, 2004;Domenek et al, 2004;Pommet et al, 2003;Micard et al, 2001;Cuq et al, 2000). Besides process conditions, the presence of additives influences extractability (Lagrain et al, 2010;Sun et al, 2007;Dicharry et al, 2006;Gallstedt et al, 2004;Woerdeman et al, 2004).…”

Section: Gluten Bioplastic Formationmentioning

confidence: 99%

The composition and extractability of thermo - molded wheat gluten bio-plastics

Fisseha¹

2016

Afr. J. Food Sci.

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The study was aimed to evaluate the effect of thermo-molding on gluten and gluten fractions composition and its extractability with 1.0 ml 0.05 M sodium phosphate buffer (pH 6.8) with 2.0% sodium dodecyl sulfate (SDS) at 130 and 150°C for 5 and 25 min. The gluten, gliadin and glutenin composition as affected by thermo-molding was analysed with reverse phase high performance liquid chromatography (RP-HPLC) and amino acid was analysed with acid hydrolysis using high-performance anion-exchange chromatography with integrated pulsed amperometric detection (HPAEC-IPAD). The extractability and composition were significantly affected. Gluten extracts were found in equivalent proportions; gliadin (51%) and glutenins (49%). Gluten, gliadin and glutenin subunits (GS) extracts were significantly affected and a reduction with increased molding condition explains the occurrence of polymerization reactions due to SH-disulfide interchange reactions. The glutenin fraction contains 15% gliadin while the gliadin fraction contains 2.5% glutenin after extraction with 60% ethanol. The extractability of the gliadin types and GS decreased with increasing molding time and temperature.

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Designing New Materials from Wheat Protein

Cited by 89 publications

References 27 publications

Production of renewable polymers from crop plants

Production of renewable polymers from crop plants

Novel Protein Fibers from Wheat Gluten

The composition and extractability of thermo - molded wheat gluten bio-plastics

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