Encapsulation of Amyloglucosidase in Chitosan-SDS Coacervates as a Means to Control Starch Hydrolysis in Plant-Based Beverages

IF 3 Q2 FOOD SCIENCE & TECHNOLOGY Beverages Pub Date : 2023-10-08 DOI:10.3390/beverages9040083
Marcella Chalella Mazzocato, Jean-Christophe Jacquier
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Abstract

Starch enzymatic hydrolysis is a key technology for preparing plant-based dairy alternative beverages, preferred for its low energy consumption, high product yield, and quality. However, the high-temperature requirement to terminate reactions and challenges in continuous operations hinder enzyme applicability. Therefore, encapsulation techniques have been explored to address these limitations, enhancing the enzyme’s stability and facilitating process control. This study developed a novel amyloglucosidase encapsulation system based on chitosan-SDS hydrogel capsules produced by simple coacervation. The enzymatic activity of free and immobilised amyloglucosidase was assessed using corn starch and maltose as substrates. The encapsulation process successfully yielded self-supporting structured and spherical capsules, achieving an immobilisation yield of 71% and an enzyme efficiency of 83%. The residual enzymatic activity after 28 days of storage remained at 76%. A feedback inhibition investigation was performed by varying the concentration of corn starch, and favourable applicability of encapsulated amyloglucosidase for continuous processes was found. The encapsulation process offered several advantages, such as a straightforward separation step to halt enzymatic reactions and no need for high temperatures that may affect food product attributes. Lastly, the amyloglucosidase-chitosan-SDS coacervates show promise in improving enzyme stability, facilitating hydrolysis control, and expanding enzyme utilisation in dairy alternative plant beverage manufacture.
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壳聚糖- sds凝聚体包封淀粉糖苷酶控制植物性饮料中淀粉水解的研究
淀粉酶解是制备植物性乳制品替代饮料的关键技术,因其低能耗、高产品收率和高质量而备受青睐。然而,终止反应的高温要求和连续操作的挑战阻碍了酶的适用性。因此,研究人员探索了包封技术来解决这些限制,提高酶的稳定性并促进过程控制。本研究以壳聚糖- sds水凝胶胶囊为原料,采用简单凝聚法制备了一种新型的淀粉糖苷酶包封体系。以玉米淀粉和麦芽糖为底物,对游离和固定化淀粉葡糖苷酶的酶活性进行了评价。包封过程成功地获得了自支撑结构和球形胶囊,实现了71%的固定化产率和83%的酶效率。贮藏28天后,酶活性保持在76%。通过改变玉米淀粉的浓度进行反馈抑制研究,发现包封淀粉葡糖苷酶在连续过程中具有良好的适用性。封装过程有几个优点,比如直接分离步骤,停止酶的反应,不需要高温,可能会影响食品的属性。最后,淀粉葡糖苷-壳聚糖- sds浓缩物在提高酶稳定性、促进水解控制和扩大酶在乳制品替代植物饮料生产中的利用方面显示出前景。
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来源期刊
Beverages
Beverages FOOD SCIENCE & TECHNOLOGY-
CiteScore
6.10
自引率
8.60%
发文量
68
审稿时长
11 weeks
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