葡甘露聚糖部分酶解及其数学模型

Q3 Engineering

International Journal of Engineering - Transactions C: Aspects Pub Date : 2023-01-01 DOI:10.5829/ije.2023.36.12c.11

D. H. Wardhani, H. Cahyono, H. N. Ulya, A. C. Kumoro, N. Aryant

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引用次数: 0

摘要

目前，酶解葡甘露聚糖(GM)的研究仅限于获得低分子量葡甘露聚糖，并没有专门研究用于喷雾干燥饲料的应用。本研究旨在探讨酶解GM的酶解浓度和酶解时间对水解葡甘露聚糖(HGM)特性的影响。此外，还研究了葡甘露聚糖酶解过程中粘度降低的动力学模型。为了达到这个目的，用不同浓度的酶(5 ~ 20 mg/l)水解转基因玉米300分钟，观察其粘度、平均分子量(Mw)、聚合度和抗氧化活性的变化。采用一级动力学、二级模型和Mahammad阶模型对黏度降低动力学进行了建模。20 mg/l (1% GM溶液)的酶浓度最快达到喷雾干燥饲料所需的粘度。当R2 = 0.9935时，n阶模型最适合于粘度降低，因此常数k = 1.1842 (Pa。得到S n-1 (t)-1和n = 0.6328。随着酶浓度的增加，水解提高了HGM的抗氧化活性。这一抗氧化结果突出了使用HGM涂层和包封活性化合物的优势，同时也提供了氧化保护。

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Partial Enzymatic Hydrolysis of Glucomannan and Its Mathematical Model

The study of enzymatic hydrolysis of glucomannan (GM) was currently limited to obtain low molecular weight glucomannan, and was not specifically studied for spray drying feed applications. This research aimed to investigate the effect of enzyme concentration and duration of enzymatic hydrolysis of GM on the characteristics of hydrolyzed glucomannan (HGM). Moreover, the kinetic models of viscosity reduction in enzymatic hydrolysis of glucomannan were also studied. To achieve the goal, the GM was hydrolyzed using various enzyme concentrations (5 to 20 mg/l) for 300 min. Profiles of viscosity, average molecular weight (Mw), degree of polymerization, and antioxidant activity of HGM were observed. The kinetics of viscosity reduction was modeled with 1st-order kinetics, 2nd-order model, and Mahammad's order. An enzyme concentration of 20 mg/l (1% GM solution) was the fastest to reach the desired viscosity for spray drying feed purposes. The model of nth-order was the best fitted to the viscosity reduction with R2 equal to 0.9935, so the constants k = 1.1842 (Pa.s n-1.t)-1 and n = 0.6328 are obtained. The hydrolysis improved the antioxidant activity of HGM as the enzyme concentration increases. This antioxidant result highlighted the advantage of using HGM for coating and encapsulating the active compound which also offers oxidation protection.

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来源期刊

International Journal of Engineering - Transactions C: Aspects Engineering-Engineering (all)

CiteScore

3.10

自引率

0.00%

发文量