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α-Amylase action on starch in chickpea flour following hydrothermal processing and different drying, cooling and storage conditions

Cathrina H. Edwards, Amalia S. Veerabahu, A. James Mason, Peter Butterworth, Peter R. Ellis

2021Carbohydrate Polymers29 citationsDOIOpen Access PDF

Abstract

Starch is present in many prepared ‘ready-meals’ that have undergone processing and/or storage in frozen or chilled state. Hydrothermal processing greatly increases starch digestibility and postprandial glycaemia. Effects of different heating/drying and cooling regimes on amylolysis have received little attention. Hence, we examined the effects of different processing treatments on in vitro digestibility of starch in chickpea flour. Solid-state 13C NMR was used to estimate ordered double-helical structure in the starch. Native starch with 25 % double-helical content was the most resistant to digestion but hydrothermal processing (gelatinisation) resulted in >95 % loss of order and a large increase in starch digestibility. Air-drying of pre-treated flour produced slowly-digestible starch (C∞, 55.9 %). Refrigeration of gelatinised samples decreased ease of amylolysis coincident with increase in double-helical content. Freezing maintained the same degree of digestibility as freshly gelatinised material and produced negligible retrogradation. Chilling may be exploited to produce ready-meals with a lower glycaemic response.

Topics & Concepts

StarchFood scienceChemistryResistant starchHydrothermal circulationRetrogradation (starch)AmylaseDigestion (alchemy)Starch gelatinizationWheat flourChemical engineeringBiochemistryAmyloseChromatographyEnzymeEngineeringFood composition and propertiesMicrobial Metabolites in Food BiotechnologyPhytoestrogen effects and research