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烹饪和储存温度对印度常见小麦制品中抗性淀粉的影响及其对血糖水平的影响。

Effect of cooking and storage temperature on resistant starch in commonly consumed Indian wheat products and its effect upon blood glucose level.

作者信息

Kaur Prabhjot, Kaur Harpreet, Aggarwal Renuka, Bains Kiran, Mahal Amrit Kaur, Gupta O P, Singla Lachhman Das, Singh Kulvinder

机构信息

Department of Food and Nutrition, Punjab Agricultural University, Ludhiana, India.

Department of Mathematics, Statistics and Physics, Punjab Agricultural University, Ludhiana, India.

出版信息

Front Nutr. 2023 Nov 28;10:1284487. doi: 10.3389/fnut.2023.1284487. eCollection 2023.

DOI:10.3389/fnut.2023.1284487
PMID:38089929
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10713747/
Abstract

BACKGROUND/OBJECTIVES: The health benefits provided by resistant starch have been well documented; however, few studies are available on the resistant starch content of wheat products in India. Moreover, few studies have examined the efficacy of resistant starch in wheat products in improving glucose levels. This study was conducted to evaluate the effect of cooking and storage temperature on the formation of resistant starch in Indian wheat products and its effect on blood glucose levels in humans and rats.

METHODS

Wheat products were prepared by common cooking methods including roasting (), boiling (), Shallow frying (), and Deep frying (). They were then stored at different temperatures including freshly prepared within 1 h (T1), stored for 24 h at room temperature (20-22°C) (T2), kept at 4°C for 24 h (T3) and reheated after storing at 4°C for 24 h (T4). The products were then analyzed for proximate composition (moisture, crude protein, crude fat, ash crude fibre, and carbohydrates). The effect of different cooking methods and storage temperatures on Resistant, non-resistant and total starch, total dietary fibre (soluble and insoluble), starch digestion rate (rapidly and slowly digestible starch), amylose and amylopectin content were analysed using standard operating procedures. The effect of products found to have higher resistant starch was studied on the post prandial blood glucose response of 10 healthy individuals using change in by analysing their glycemic index and glycemic load of wheat products. Further, the effect of resistant starch rich on the blood glucose level of rats was also studied. Tukey's test in factorial CRD was used to assess the effect of cooking and temperature on various parameters.

RESULTS

The amount of resistant starch was found to be high in (boiling, 7.74%), followed by (shallow frying, 4.94%), (roasting, 2.77%) and (deep frying 2.47%). Under different storage temperatures, it was found high in products stored at 4°C (T3), followed by products stored at room temperature (T2), reheated products (T4) and lesser in freshly prepared products (T1). The glycemic index and glycemic load were found low in (43, 32.3) and (41.1, 28.6) stored at 4°C (T3) compared to others. The resistant starch content found in stored at T3 was found to be more effective at reducing blood glucose levels in rats from 291.0 mg/100 mL to 225.2 mg/100 mL in 28 days of study compared to freshly prepared (T1) and stored at room temperature (T2).

CONCLUSION

Cooking methods including boiling, roasting and shallow frying increased the amount of resistant starch in foods, but cooking methods such as deep frying decreased the amount of resistant starch in food. Products stored at 4°C and at room temperature for 24 h increased the amount of resistant starch whereas the products that were freshly cooked and reheated decreased the amount of resistant starch in foods. At 4°C the stored products have a high amount of insoluble dietary fibre, slowly digestible starch, high amylose and low glycemic index. They take time to digest, meaning that they slowly increase blood glucose levels. The effect of insoluble dietary fibre and resistant starch in the inhibition of glucose diffusion in the small intestine is suggested to be due to the absorption or inclusion of the smaller sugar molecules. research showed that fibre and resistant starch in the digestive system of rats acts as the main factors in slowing glucose absorption and reducing a rise in blood glucose levels by promoting glycogen synthesis and inhibition of gluconeogenesis.

摘要

背景/目的:抗性淀粉对健康有益,这一点已有充分文献记载;然而,关于印度小麦制品中抗性淀粉含量的研究却很少。此外,很少有研究探讨抗性淀粉在小麦制品中对改善血糖水平的功效。本研究旨在评估烹饪和储存温度对印度小麦制品中抗性淀粉形成的影响及其对人类和大鼠血糖水平的影响。

方法

采用常见烹饪方法制备小麦制品,包括烘焙()、煮沸()、浅炸()和深炸()。然后将它们储存在不同温度下,包括在1小时内新鲜制备(T1)、在室温(20 - 22°C)下储存24小时(T2)、在4°C下保存24小时(T3)以及在4°C下储存24小时后重新加热(T4)。随后分析产品的近似成分(水分、粗蛋白、粗脂肪、灰分、粗纤维和碳水化合物)。使用标准操作程序分析不同烹饪方法和储存温度对抗性淀粉、非抗性淀粉和总淀粉、总膳食纤维(可溶和不可溶)、淀粉消化率(快速和缓慢消化淀粉)、直链淀粉和支链淀粉含量的影响。通过分析10名健康个体食用小麦制品后的血糖指数和血糖负荷变化,研究发现抗性淀粉含量较高的产品对餐后血糖反应的影响。此外,还研究了富含抗性淀粉的产品对大鼠血糖水平的影响。采用析因完全随机区组设计中的Tukey检验来评估烹饪和温度对各种参数的影响。

结果

发现抗性淀粉含量在(煮沸,7.74%)中较高,其次是(浅炸,4.94%)、(烘焙,2.77%)和(深炸,2.47%)。在不同储存温度下,发现4°C储存的产品(T3)中抗性淀粉含量较高,其次是室温储存的产品(T2)、重新加热的产品(T4),新鲜制备的产品(T1)中含量较低。与其他产品相比,4°C(T3)储存的(43, 32.3)和(41.1, 28.6)的血糖指数和血糖负荷较低。在28天的研究中,发现T3储存的中抗性淀粉含量在降低大鼠血糖水平方面比新鲜制备的(T1)和室温储存的(T)更有效,大鼠血糖水平从291.0mg/100mL降至225.2mg/100mL。

结论

包括煮沸、烘焙和浅炸在内的烹饪方法增加了食品中抗性淀粉的含量,但深炸等烹饪方法降低了食品中抗性淀粉的含量。在4°C和室温下储存24小时的产品增加了抗性淀粉含量,而新鲜烹饪和重新加热的产品降低了食品中抗性淀粉的含量。在4°C下储存的产品含有大量不溶性膳食纤维、缓慢消化淀粉、高直链淀粉和低血糖指数。它们需要时间来消化,这意味着它们会缓慢升高血糖水平。不溶性膳食纤维和抗性淀粉在抑制小肠中葡萄糖扩散的作用被认为是由于吸收或包含了较小的糖分子。研究表明,大鼠消化系统中的膳食纤维和抗性淀粉是减缓葡萄糖吸收和通过促进糖原合成及抑制糖异生来降低血糖水平升高的主要因素。

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