Novel Protein Fibers from Wheat Gluten

2010

J Polym Environ

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For the first time, gliadin films with excellent strength and water stability have been developed without using any crosslinking agents. So far, it has not been possible to obtain water stable gliadin films even after crosslinking. In this research, a novel method of using aqueous urea and ethanol has been developed to obtain highly water stable gliadin films without using crosslinking chemicals. The effects of concentrations of gliadin, urea and ethanol on the strength of the films and the stability of the films in water at high temperatures and various pH conditions has been studied. Gliadin films developed in this research have strength of about 30 MPa similar to the strength of previously reported gliadin films crosslinked with aldehydes and cysteine. Gliadin films obtained in this research were stable in pH 7.2 water at 50 °C for 20 days. The gliadin films did not dissolve in 70% ethanol which readily dissolves gliadin powder.

Section: Effect Of Urea Concentrationmentioning

confidence: 99%

“…In addition to films, plant proteins have also been used to develop regenerated protein fibers for various applications [6][7][8][9]. However, films and fibers made from plant proteins have relatively poor mechanical properties and stability in water compared to similar materials made from synthetic polymers.…”

Section: Introductionmentioning

confidence: 99%

Developing Water Stable Gliadin Films Without Using Crosslinking Agents

Reddy

2010

J Polym Environ

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“…Therefore, efforts have been made since 1930s to produce regenerated protein fibers using various protein sources. Soyproteins, wheat gluten and gliadin, zein, keratin in feathers are some of the sources used to develop regenerated protein fibers [4][5][6]. Our group has demonstrated that byproducts such as soyprotein, zein, and wheat gluten obtained during processing of food grains for food and biofuels can be used to develop high quality regenerated protein fibers [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

“…Soyproteins, wheat gluten and gliadin, zein, keratin in feathers are some of the sources used to develop regenerated protein fibers [4][5][6]. Our group has demonstrated that byproducts such as soyprotein, zein, and wheat gluten obtained during processing of food grains for food and biofuels can be used to develop high quality regenerated protein fibers [4][5][6]. The regenerated protein fibers developed from wheat gluten and soyproteins were crosslinked with carboxylic acids and reported to have properties similar to wool and suitable for textile and medical applications [7,8].…”

Section: Introductionmentioning

confidence: 99%

Structure and properties of cocoons and silk fibers produced by Hyalophora cecropia

Reddy

2010

J Mater Sci

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This paper shows that silk fibers produced by cecropia (Hyalophora cecropia) have similar tensile properties but different amino acid composition than that of mulberry (Bombyx mori) silk. The cecropia fibers are also much finer and have better strength and modulus than tasar silk, the most common non-mulberry silk. Cecropia is one of the largest silk producing moths and has similar lifecycle to that of mulberry silk but is easier to grow and produces larger cocoons than mulberry silk. In this study, we have characterized the composition, morphology, physical and tensile properties, and thermal behavior of the cecropia silk. Cecropia cocoons have a three tier structure and are larger (750 mg) than the cocoons produced by B. mori (650 mg). Fibers in the three layers in cecropia cocoons have tensile properties similar to that of B. mori silk but are finer (1.7-2 denier) and have higher strength (3.8-4.3 g/denier) and modulus (68-92 g/denier) than tasar silk.

“…Although wheat based proteins, mainly gluten and gliadin, have been used for industrial applications such as fibers and films similar to soyproteins and zein, very few studies have been conducted on understanding the suitability of wheat proteins for medical applications [7][8][9][10][11][12][13]. Gliadin films were made into soft capsules and chewable gums for controlled drug release and it was reported that gliadin proteins showed high promise to be bioacceptable proteins with controlled release potency [14].…”

Section: Introductionmentioning

confidence: 99%

Self-crosslinked gliadin fibers with high strength and water stability for potential medical applications

Reddy¹,

2007

J Mater Sci: Mater Med

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For the first time, protein fibers with excellent mechanical properties and water stability have been produced from gliadin for potential use in tissue culture and other medical applications. Biomaterials developed from plant proteins such as zein and soyproteins are preferred for several medical applications over synthetic polymers such as polylactic acid. However, the plant protein based biomaterials developed so far have poor mechanical properties and hydrolytic stability even after crosslinking. This study aims to develop biomaterials from gliadin with excellent mechanical properties and water stability without using any crosslinking agents. A novel gliadin fiber production method was used to self crosslink the fibers and obtain high strength and water stability. Gliadin fibers have high strength (120 MPa) and elongation (25%) compared to similar collagen fibers that were crosslinked with glutaraldehyde (strength of about 44 MPa and elongation of 14%). The fibers show 100% strength retention after being in pH 7 water at 50 °C for 40 days and also have better water stability than PLA in acidic conditions at high temperatures. Gliadin fibers are suitable for cell growth and promote the attachment and proliferation of bovine turbinate fibroblasts.