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Effect of starch-meal chilling and reheating on postprandial glycaemia in overweight and obese individuals

Published online by Cambridge University Press:  05 October 2018

A. Alzaabi
Affiliation:
Department of Nutritional Sciences, Faculty of Health and Medical Sciences, University of Surrey, Guildford, GU2 7WG
B.A. Fielding
Affiliation:
Department of Nutritional Sciences, Faculty of Health and Medical Sciences, University of Surrey, Guildford, GU2 7WG
M.D. Robertson
Affiliation:
Department of Nutritional Sciences, Faculty of Health and Medical Sciences, University of Surrey, Guildford, GU2 7WG
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Abstract

Type
Abstract
Copyright
Copyright © The Authors 2018 

Both the amount and type of dietary carbohydrates contribute to glycaemia and insulinaemia. Normally, in healthy people, the secretion of insulin maintains plasma glucose levels within a narrow range. However, in insulin resistance, inefficient insulin action impairs fasting and postprandial glucose regulation(Reference Robertson1). Insulin resistance has been associated with the development of chronic metabolic diseases such as type 2 diabetes mellitus and CVD(Reference Johnston, Thomas, Bell, Frost and Robertson2). Several studies have demonstrated that replacing digestible carbohydrates with indigestible ones reduces postprandial glucose responses. A pilot study in our laboratory indicated that chilling and reheating a pasta meal significantly lowered the glycaemic response in healthy, normal weight adults compared to identical meals served freshly cooked, potentially due to the formation of type 5 resistant starch(3). Accordingly, the objective of this study was to determine whether domestic chilling and reheating would have a similar effect, of reducing postprandial glycaemia in overweight and obese individuals.

Ten overweight and obese participants (6 females) with mean BMI of 29·6 (SD 4·2) were recruited for the study. The study was conducted as a randomised cross-over single-meal study. The trial involved two different test meals; a freshly cooked meal (control) and a chilled and reheated meal (intervention) in the form of pasta, olive oil and tomato passata. These two meals were each consumed on a different occasion with a wash-out period of one week. Each meal consisted of 11 g fat, 75 g carbohydrate and 13·5 g protein, providing 1950 KJ. Postprandial capillary blood sampling for glucose and insulin was undertaken at baseline and then at 15, 30, 45, 60, 90 and 120 minutes after meal consumption.

In a post-hoc analysis, participants were considered in two groups; insulin sensitive (n = 5) and insulin resistant (n = 5) stratified by fasting insulin sensitivity (HOMA2 > or <1·0). In the insulin sensitive group, the mean glucose iAUCs were 134 (SD 90) v 167 (SD 91) mmol. l−1. 120 min for control v intervention meals respectively (t (4) = −8·902, p = 0·001). However, in contrast, there was no statistically significant difference found for the postprandial glucose response in the insulin resistant group (mean glucose iAUCs were 210·30 (SD 44·39) v 193·04 (SD 74·92) mmol. l−1. 120 min for control v intervention). There was no significant between group effect of the two meals. The mean postprandial insulin iAUCs were 2447 (SD 1584) v 2947 (SD 1614) μU. ml−1. 120 min for control v intervention in the insulin sensitive group (ns), and 6106 (SD 2006) v 5269 (SD 1905) μU. ml−1. 120 min for control v intervention in the insulin resistant group (ns). A statistically significant difference between group effect of the two meals for plasma insulin was noted (t (8) = 2·529, p= 0·035).

In conclusion, the analysis revealed a difference between the groups in the postprandial insulin response after ingestion of the treatment meals but no effect on plasma glucose. This positive response in insulin might be favourable in the management of hyperinsulinaemia for those who are insulin resistant. This study is continuing further recruitment to obtain more statistical robust results.

References

1.Robertson, MD. (2012) Dietary-resistant starch and glucose metabolism. Curr Opin Clin Nutr 15(4), 362–7.Google Scholar
2.Johnston, KL, Thomas, EL, Bell, JD, Frost, GS, Robertson, MD. (2010) Resistant starch improves insulin sensitivity in metabolic syndrome. Diabetic Med 27(4), 391–7.Google Scholar
3.BBC Website. Trust Me, I'm a Doctor - Can my leftovers be healthier than the original meal? [cited]. Available from: http://www.bbc.co.uk/programmes/articles/3LncBcDcCXKgtpFvrDZVnNQ/can-my-leftovers-be-healthier-than-the-original-meal.Google Scholar