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http://dx.doi.org/10.14478/ace.2018.1027

Optimization of Total Flavonoids Extraction Process from Wheat Sprout using Central Composite Design Model  

Lee, Seung Bum (Department of Chemical Engineering, Dankook University)
Wang, Xiaozheng (Department of Chemical Engineering, Dankook University)
Yoo, Bong-Ho (College of Engineering, Dankook University)
Publication Information
Applied Chemistry for Engineering / v.29, no.4, 2018 , pp. 446-451 More about this Journal
Abstract
Effective ingredients were extracted using wheat sprout with high levels of flavonoids, and the extraction process was optimized with a central composite design model. The response value of the central composite design model establishes the extraction yield and the content of the flavonoids. The main and interactive effects were then analyzed depending on independent variables such as the extraction time, the volume ratio of alcohol to ultrapure water, and the extraction temperature. The extraction time and temperature were relatively large for the extraction yield. For the total flavonoids, the extraction time was most significantly affected. Considering both the extraction yield and the content of the total flavonoids, optimal extraction conditions were as follows: the extraction time (2.44 h), volume ratio of alcohol to ultrapure water (50.00 vol%), extraction temperature ($54.41^{\circ}C$). Under these condition, the extraction yield was 30.14 wt% and the content of the total flavonoids was $35.37{\mu}g\;QE/mL\;dw$. From the actual experimental result, the extraction yield under this condition was 29.92 wt% and the content of the total flavonoids was $35.32{\mu}g\;QE/mL\;dw$, which had an error rate of 0.39% and 0.74%, respectively. This is a multi-analysis comprehensive analysis that analyzes two simultaneous values of responses, but is considered to be highly accurate and also provides an excellent reliability of the optimization process in this study.
Keywords
total flavonoids; wheat sprout; central composite design; extraction yield;
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