Biodegradation of starch films: The roles of molecular and crystalline structure

Ming Li; Torsten Witt; Fengwei Xie; Frederick J. Warren; Peter J. Halley; Robert G. Gilbert

doi:10.1016/j.carbpol.2015.01.011

Biodegradation of starch films: The roles of molecular and crystalline structure

Ming Li, Torsten Witt, Fengwei Xie, Frederick J. Warren, Peter J. Halley, Robert G. Gilbert

Research output: Contribution to journal › Article › peer-review

66 Citations (SciVal)

Abstract

The influences of molecular, crystalline and granular structures on the biodegradability of compression-molded starch films were investigated. Fungal α-amylase was used as model degradation agent. The substrates comprised varied starch structures obtained by different degrees of acid hydrolysis, different granular sizes using size fractionation, and different degrees of crystallinity by aging for different times (up to 14 days). Two stages are identified for unretrograded films by fitting degradation data using first-order kinetics. Starch films containing larger molecules were degraded faster, but the rate coefficient was independent of the granule size. Retrograded films were degraded much slower than unretrograded ones, with a similar rate coefficient to that in the second stage of unretrograded films. Although initially the smaller molecules or the easily accessible starch chains on the amorphous film surface were degraded faster, the more ordered structure (resistant starch) formed from retrogradation, either before or during enzymatic degradation, strongly inhibits film biodegradation.

Original language	English
Pages (from-to)	115-122
Number of pages	8
Journal	Carbohydrate Polymers
Volume	122
DOIs	https://doi.org/10.1016/j.carbpol.2015.01.011
Publication status	Published - 20 May 2015

Bibliographical note

Publisher Copyright:
© 2015 Elsevier Ltd.

Funding

We thank Mr. Wei Zou, Mr. Soon Ket Chong, Miss Oiwan Mo, and Mr. Leif Sharkey for their kind help during the experiment, and thank Dr. Jovin Hasjim for proof reading. The authors would like to thank the staff in the Centre for Microscopy and Microanalysis at The University of Queensland, a node of the Australian Microscopy and Microanalysis Research Facility (AMMRF). Financial assistance from an Australian Research Council Discovery grant, DP130102461 , is appreciated, as is the support of the 1000-Talents Program of the Chinese Foreign Experts Bureau.

Funders	Funder number
1000-Talents Program of the Chinese Foreign Experts Bureau
Australian Research Council	DP130102461

Keywords

Bioplastic
Crystallinity
Enzymatic degradation
Molecular structure
Starch

ASJC Scopus subject areas

Organic Chemistry
Polymers and Plastics
Materials Chemistry

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10.1016/j.carbpol.2015.01.011

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abstract = "The influences of molecular, crystalline and granular structures on the biodegradability of compression-molded starch films were investigated. Fungal α-amylase was used as model degradation agent. The substrates comprised varied starch structures obtained by different degrees of acid hydrolysis, different granular sizes using size fractionation, and different degrees of crystallinity by aging for different times (up to 14 days). Two stages are identified for unretrograded films by fitting degradation data using first-order kinetics. Starch films containing larger molecules were degraded faster, but the rate coefficient was independent of the granule size. Retrograded films were degraded much slower than unretrograded ones, with a similar rate coefficient to that in the second stage of unretrograded films. Although initially the smaller molecules or the easily accessible starch chains on the amorphous film surface were degraded faster, the more ordered structure (resistant starch) formed from retrogradation, either before or during enzymatic degradation, strongly inhibits film biodegradation.",

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AU - Li, Ming

AU - Witt, Torsten

AU - Xie, Fengwei

AU - Warren, Frederick J.

AU - Halley, Peter J.

AU - Gilbert, Robert G.

PY - 2015/5/20

Y1 - 2015/5/20

N2 - The influences of molecular, crystalline and granular structures on the biodegradability of compression-molded starch films were investigated. Fungal α-amylase was used as model degradation agent. The substrates comprised varied starch structures obtained by different degrees of acid hydrolysis, different granular sizes using size fractionation, and different degrees of crystallinity by aging for different times (up to 14 days). Two stages are identified for unretrograded films by fitting degradation data using first-order kinetics. Starch films containing larger molecules were degraded faster, but the rate coefficient was independent of the granule size. Retrograded films were degraded much slower than unretrograded ones, with a similar rate coefficient to that in the second stage of unretrograded films. Although initially the smaller molecules or the easily accessible starch chains on the amorphous film surface were degraded faster, the more ordered structure (resistant starch) formed from retrogradation, either before or during enzymatic degradation, strongly inhibits film biodegradation.

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KW - Crystallinity

KW - Enzymatic degradation

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ER -

Biodegradation of starch films: The roles of molecular and crystalline structure

Abstract

Bibliographical note

Funding

Keywords

ASJC Scopus subject areas

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