Structure and properties of compression-molded thermoplastic starch materials from normal and high-amylose maize starches

Soest, J.J.G. van; Borger, D. B.

doi:10.1002/(sici)1097-4628(19970425)64:4<631::aid-app2>3.0.co;2-o

Cited by 85 publications

(58 citation statements)

References 14 publications

(22 reference statements)

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“…For the thermogram of non-cross-linked starch, the melting peak was lost in broad decomposition peak. 31 The results were in accordance with the results reported by Liu et al 32 and Kumar et al 33 On the other hand, after cross-linking, the much higher decomposition temperature could be due to the more compact molecular structure and stronger intermolecular forces attributed to additional intraand intermolecular bonds formed due to cross-linking. Stability in Water.…”

Section: ■ Results and Discussionsupporting

confidence: 90%

Robust and Flexible Films from 100% Starch Cross-Linked by Biobased Disaccharide Derivative

Canısağ

et al. 2015

ACS Sustainable Chem. Eng.

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In this research, oxidized sucrose, a novel aldehyde-based green cross-linker, endowed starch films with substantial improvement in both tensile strength and elongation, whereas many other cross-linkers did not. Starch films are usually weak, brittle, and highly moisture sensitive, and thus have restricted industrial applications. Cross-linking is one of the most common methods to tackle these problems. However, most of the available cross-linkers are either toxic, expensive, or with low cross-linking efficiencies. Oxidized sucrose is a green cross-linker with multiple aldehyde groups per molecule to cross-link starch molecules via forming hemiacetals/acetals. The starch films cross-linked with oxidized sucrose had tensile strength and breaking elongation of 23 MPa and 60%, respectively, exceeding the cross-linking results of many other cross-linkers. Oxidized sucrose cross-linking also substantially increased the stability of starch films in both water and formic acid. With activation energy as low as 33.22 kJ mol −1 , the cross-linking, a pseudo-first-order reaction, could occur readily. Mild cross-linking using oxidized sucrose might provide an alternative to promote industrialization of starch-based products.

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Section: ■ Results and Discussionsupporting

confidence: 90%

Robust and Flexible Films from 100% Starch Cross-Linked by Biobased Disaccharide Derivative

Canısağ

et al. 2015

ACS Sustainable Chem. Eng.

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“…In this regard, the past decade has witnessed development and restructuring to convert starch into a thermoplastic material (Kirby and others 1993;Lourdin and others 1995;Spence and others 1995;Van Soest and Borger 1997;Sen and Bhattacharya 2000;Gomes and others 2001). Plastic formulations comprising corn-based starch (6% to 50%), to enhance the susceptibility of plastic products to biological degradation, have also been reported others 1980, 1987).…”

Section: Irradiation In the Development Of Starch-based Packagingmentioning

confidence: 99%

Impact of Radiation Processing on Starch

Bhat

Karim

2009

Comp Rev Food Sci Food Safe

140

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It is envisaged that there will be a considerable demand in the near future for modified starches. To meet the demand, the chemical modification of starch, including cross-linking, has been widely used to obtain desirable traits that are suitable for various food applications. Radiation processing, being a physical process, is an environmentally friendly alternative to chemical modification. It is economically viable, safe, and possesses several advantages over other conventional methods employed for modification and cross-linking. Irradiation of starch leads to the attainment of such desired functional attributes as reduction of viscosity, high water solubility, and others. This review provides insight into the impact of gamma, electron beam, and ultraviolet irradiation on the physicochemical and functional properties of starch. It also highlights the importance and the exciting new opportunities afforded by radiation treatments as a physical means for the modification of starch.

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“…It has been reported that long linear glucans, like amylose molecules, tend to form more entanglements compared to highly branched amylopectin molecules. 15 Therefore, the long chained amylopectin starch used in the present study should act as a linear chain and have an influence on the chain entanglements development during extrusion. For bio-based materials it is of interest, from a techno-functional point of view, to explore a potato starch with amylopectin of longer chains length and decreased degree of branching as a good potential raw material for improved packaging materials.…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2015

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In the present study, we were able to produce composites of wheat gluten (WG) protein and a novel genetically modified potato starch (MPS) with attractive mechanical and gas barrier properties using extrusion. Characterization of the MPS revealed an altered chain length distribution of the amylopectin fraction and slightly increased amylose content compared to wild type potato starch. WG and MPS of different ratios plasticized with either glycerol or glycerol and water were extruded at 110 and 130°C. The nano morphology of the composites showed the MPS having semi-crystalline structure of a characteristic lamellar arrangement with an approximately 100 Å period observed by SAXS and a B-type crystal structure observed by WAXS. WG has a structure resembling the hexagonal macromolecular arrangement as reported previously in WG films. A larger amount of β-sheets was observed in the samples 70/30 and 30/70 WG-MPS processed at 130°C with 45% glycerol. Highly polymerized WG protein was found in the samples processed at 130°C vs. 110°C. Also, greater amounts of WG protein in the blend resulted in greater extensibility (110°C), and a decrease in both E-modulus and maximum stress at 110 and 130°C, respectively. Under ambient conditions the WG-MPS composite (70/30) with 45% glycerol showed excellent gas barrier properties to be further explored in multilayer film packaging applications.

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Structure and properties of compression-molded thermoplastic starch materials from normal and high-amylose maize starches

Cited by 85 publications

References 14 publications

Robust and Flexible Films from 100% Starch Cross-Linked by Biobased Disaccharide Derivative

Robust and Flexible Films from 100% Starch Cross-Linked by Biobased Disaccharide Derivative

Impact of Radiation Processing on Starch

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

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