Starch retrogradation in tuber : mechanisms and its implications on microstructure and glycaemic features of potatoes : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in School of Food and Advanced Technology at Massey University, Palmerston North, Manawatū, New Zealand
Loading...
Date
2020
DOI
Open Access Location
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Massey University
Rights
The Author
Abstract
An increase in the occurrence of diabetes mellitus, cardiovascular disease and obesity in recent years led to the project “Starch retrogradation in tuber: mechanisms and its implications on microstructure and glycaemic features of potatoes”. Potato products can play a role in mitigating these hyperglycaemic events, if starch in these processed products is slowly digested and/or starch-derived glucose is released into the circulation in a slower and more attenuated manner. Three stages were envisaged for the project with an aim to create slowly digestible starch in whole potato tuber (in tuber) through starch retrogradation.
Plant-based whole food systems, such as potato tubers encompass different cell compartments, (e.g. cell wall, vacuole, cytoplasm and intracellular spaces) within which starch gelatinisation and retrogradation occur, subject to local interactions of other cell components and water availability. Structural changes of potato starch during retrogradation in tuber and its resulting digestibility were studied. Different water pools in a cooked whole tuber were discerned by the low-field NMR (LF-NMR), having relaxation times T20 at <1 ms, T21 at 10-15 ms, T22 at 70–200ms, and T23 at > 400 ms. A significant reduction in eGI was observed after cooling and storage compared to freshly cooked tubers. Reheating of retrograded tuber restored some of the susceptibility to enzymatic hydrolysis and internal water mobility. Longer chilled storage (7 days) yet improved the stability of retrograded tuber against reheating effects (at 90 °C). Realignment of the gelatinised amylose and amylopectin changed the distribution of crystalline and amorphous regions during refrigerated storage and subsequent reheating, resulting in starch digestibility varying with treatment combination. Several, but not all, of time-temperature cycle processes were observed to induce stepwise nucleation and propagation, facilitating starch retrogradation in tuber more than did storage fixed at 4 °C. Sous vide processing (at 55 and 65°C), akin to annealing, combined with starch retrogradation in tuber, resulted in potatoes with intermediate eGI (40-72). After reheating at 60°C, the eGI of sous vide cooked-chill potatoes increased moderately, displaying a mixture of partially gelatinised starch and swollen granules. Food processing, i.e. optimum TTC process or sous vide process might facilitate the formation of retrograded starch in tuber, resulting in a reduced eGI (than freshly cooked tubers). To retain the resistance to digestive enzymes in retrograded starch in tuber, reheating at low temperatures (50-60°C) were needed.
Description
Figures are re-used under a Creative Commons Attribution 4.0 International (CC BY 4.0) licence, or with the publisher's permission.
Keywords
Potatoes, Starch, Digestion