Hydrolysis Optimization of Isoflavone Conversion in Soy Germ (Chiang Mai 60) Using Response Surface Methodology (RSM)

King Mongkut’s University of Technology North Bangkok International Journal of Applied Science and Technology Pub Date : 2015-02-19 DOI:10.14416/J.IJAST.2015.02.001

Sriwiang Tipkanon, R. Charoen, Wanticha Savedboworn, A. Abdallah

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引用次数: 1

Abstract

Response surface methodology (RSM) was employed to optimize the hydrolysis conditions of isoflavone conversion in soy germ by using central composite design (CCD) of three factors. A five-level, three variables design was adopted. The three independent variables investigated in this experiment were pH (X 1 ) 3 – 8; reaction temperature (X 2 ) 25 – 75 ° C; and reaction time (X 3 ) 2 – 12 h. Dependent variables were highly fitted to the regression equation for the both of total amount of isoflavone glucosides (Y 1 ) and total amount of isoflavone aglycones (Y 2 ). The high regression coefficient values indicated that the variables were highly fitted to the regression equation for the both of total isoflavone glucosides (R 2 = 0.937) and total isoflavone aglycones (R 2 = 0.956) concentration. Optimum hydrolysis conditions for maximizing the determination of total isoflavone aglycones content were: pH = 5.3, reaction temperature = 51 ° C and reaction time = 7.5 h.

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响应面法优化大豆胚芽(清迈60)异黄酮水解转化

采用响应面法(RSM)，采用三因素中心组合设计(CCD)优化大豆胚芽中异黄酮转化的水解条件。采用五水平、三变量设计。本实验考察的三个自变量为pH (x1) 3 - 8;反应温度(x2) 25 - 75℃;反应时间(x3) 2 ~ 12 h。异黄酮苷总含量(Y 1)和异黄酮苷元总含量(Y 2)的回归方程具有高度拟合的因变量。总异黄酮苷(r2 = 0.937)和总异黄酮苷元(r2 = 0.956)浓度的回归方程均具有较高的拟合系数。测定总异黄酮苷元含量的最佳水解条件为:pH = 5.3，反应温度= 51℃，反应时间= 7.5 h。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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King Mongkut’s University of Technology North Bangkok International Journal of Applied Science and Technology

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