Studies on modelling and simulation of lactose hydrolysis by free and immobilized β-galactosidase from Aspergillus niger

The Chemical Engineering Journal Pub Date : 1993-08-01 DOI:10.1016/0300-9467(93)80044-O

N. Papayannakos, G. Markas, D. Kekos

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引用次数: 41

Abstract

β-Galactosidase from Aspergillus niger was immobilized effectively on a porous ceramic monolith by adsorption and intermolecular cross-linking. The binding efficiency reached 80% and no enzyme leaching was observed even under vigorous mechanical agitation. Immobilization did not change the pH optimum of lactose hydrolysis. The enzyme decay followed first-order kinetics and the thermal stability of the immobilized lactase was considerably enhanced. At 50 °C and pH 3.6 the half-life of the immobilized lactase was 180 days and that of the free enzyme 24 days. The kinetics of lactose hydrolysis by both free and immobilized lactase were studied in a batch reactor system in the absence of any mass transfer limitations. In both cases the totally competitive galactose inhibition kinetic model predicted the experimental data. Simulation of the performance of a laboratory continuous flow immobilized lactase reactor system showed that experimental results could be predicted by the ideal plug flow model when an apparent effectiveness factor n_f=0.65 is used to take into account the external mass transfer limitations.

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游离和固定化黑曲霉β-半乳糖苷酶水解乳糖的建模与模拟研究

通过吸附和分子间交联，将黑曲霉β-半乳糖苷酶有效地固定在多孔陶瓷单体上。结合效率达80%，即使在剧烈的机械搅拌下也未发生酶浸。固定化不改变乳糖水解的pH值。酶的衰变符合一级动力学，固定化乳糖酶的热稳定性显著提高。在50℃、pH 3.6条件下，固定化乳糖酶的半衰期为180 d，游离酶的半衰期为24 d。在没有任何传质限制的间歇反应器系统中，研究了游离和固定化乳糖酶水解乳糖的动力学。在这两种情况下，完全竞争半乳糖抑制动力学模型预测了实验数据。对实验室连续流动固定化乳糖酶反应器系统的性能进行了仿真，结果表明，考虑外部传质限制，当表观有效因子nf=0.65时，理想塞流模型可以预测实验结果。

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The Chemical Engineering Journal

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