Optimization on Na and Ca bentonite activation using response surface method for increasing selectivity of stevioside in stevia extract

Ayu Saraswati, E. Noor, T. Sunarti
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Abstract

The demand for stevia extract consumption as an alternative sweetener that contains stevioside with zero-calorie is increasing. However, dark color and high tannin content from stevia leaf extract causes a disturbing aftertaste and reduces interest in consumption. Therefore, the purification process is a mandatory step to be done. Several studies on purification methods show the best approach by adsorption using bentonite. However, natural bentonite has limited adsorption capacity and low selectivity. An activation with acid and high temperature is expected to increase the adsorption capacity of color and its selectivity on maintaining the stevioside at the extract. This study aimed to obtain the optimum acid concentration and temperature for the activation using the Response Surface Method (RSM) experimental design and its application to the purification of stevia leaf extract. Based on the parameter of methylene blue number, the most optimum concentration of H2SO4 used for activation was 0.17 N for both natural bentonite. The heating temperature was 358°C for Na-bentonite and 481°C for Ca bentonite. The maximum adsorption capacities of activated Na and Ca-bentonite were increased from 15.65 and 38.23 mg g-1 to 197.72 and 169.52 mg g-1, respectively. The best adsorbent used for purification is Ca-activated, which increased extract clarification up to 81.37% at 655 nm and 86.64% at 410 nm compared to natural Ca bentonite. It also reduced tannin up to 97.46% and was more selective to recover 50.64% stevia content in the solution, which was higher than other previously reported studies.
响应面法优化Na、Ca膨润土活化,提高甜叶菊提取物中甜菊苷的选择性
甜叶菊提取物作为一种含有零卡路里甜叶菊苷的替代甜味剂的消费需求正在增加。然而,甜菊叶提取物的深色和高单宁含量会引起令人不安的余味,降低消费的兴趣。因此,净化过程是必须要做的步骤。对几种净化方法的研究表明,膨润土吸附法是最佳的净化方法。但天然膨润土的吸附能力有限,选择性低。通过酸和高温活化可以提高颜色的吸附能力和保持甜菊苷在提取物中的选择性。本研究旨在通过响应面法(RSM)实验设计获得最佳的酸浓度和温度,并将其应用于甜菊叶提取物的纯化。以亚甲基蓝数为参数,两种天然膨润土的最佳活化浓度均为0.17 N。钠基膨润土加热温度为358℃,钙基膨润土加热温度为481℃。活化钠和钙膨润土的最大吸附量分别从15.65和38.23 mg g-1提高到197.72和169.52 mg g-1。在655 nm和410 nm处,钙活化的吸附剂比天然钙膨润土的澄清率分别提高了81.37%和86.64%。单宁还原率达97.46%,对甜叶菊含量的回收率为50.64%,高于其他文献报道。
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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