降级(电信)
化学
乳酸
聚合物
变性(裂变材料)
低聚物
米氏-门汀动力学
反应速率常数
酶
反应速率
单体
化学工程
动力学
高分子化学
色谱法
催化作用
有机化学
酶分析
核化学
细菌
电信
遗传学
物理
量子力学
计算机科学
生物
工程类
作者
Lu Cui,Xinjie Wang,Györgyi Szarka,Nóra Hegyesi,Yating Wang,Xiaofeng Sui,Béla Pukánszky
标识
DOI:10.1016/j.ijbiomac.2022.04.121
摘要
The enzymatic degradation of poly(lactic acid) was catalyzed with Proteinase K and the effect of various factors on the rate of degradation was analyzed quantitatively with the help of appropriate kinetic models. The Michaelis-Menten model was modified for the purpose by considering the heterogeneous nature of the reaction and the denaturation of the enzyme. The results proved that Proteinase K degrades the polymer very efficiently. The rate of degradation increases considerably up to 0.1 mg/ml enzyme concentration, but remains constant at larger values. Temperature has an optimum at around 50 °C that is somewhat higher than the 37 °C extensively used in the literature as the most advantageous temperature. If degradation occurs in the same medium throughout the process, the formation of lactic acid results in the rapid decrease of pH and finally in the denaturation of the enzyme. The dropping of pH below 5 slows down and finally stops degradation completely. The daily change of the medium results in degradation with a constant rate and the entire amount of the polymer can be decomposed mainly into monomer or smaller oligomer fragments. Degradation rate decreases slightly with increasing molecular weight and increasing d-lactide content. The use of appropriate kinetic models allows quantitative analysis and the prediction of the rate of enzymatic degradation of PLA.
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