Thermo-responsive super porous p(NIPAM) cryogels affords enhanced thermal stability and activity for ɑ-Glucosidase enzyme by entrapping in situ

The Canadian Journal of Chemical Engineering Pub Date : 2021-01-30 DOI:10.22541/AU.161199917.74971044/V1

Sahin Demirci, N. Sahiner

{"title":"Thermo-responsive super porous p(NIPAM) cryogels affords enhanced thermal stability and activity for ɑ-Glucosidase enzyme by entrapping in situ","authors":"Sahin Demirci, N. Sahiner","doi":"10.22541/AU.161199917.74971044/V1","DOIUrl":null,"url":null,"abstract":"The concept of using a thermo-responsive p(NIPAM) polymer matrix for\nenzyme immobilization with lower critical solution temperature (LCST)\nvalue is rationalized by availability of the compartmental milieu to\nenzymes to operate within super porous 3-D matrix with special\nenvironmental conditions. Therefore, the enzyme immobilization within a\nsupport material will be carried out under the storage conditions of\nenzymes, generally ~-20 oC to afford unnecessarily loss\nof enzyme functionality in comparison to the other enzyme entrapment\nmethods. Thus, here ɑ-Glucosidase as a model enzyme was entrapped within\nthermo-responsive super porous p(NIPAM) cryogels (ɑ-Glu@p(NIPAM) during\nthe synthesis that uses cryogenic condition, ~-20 oC.\nThe LSCT value for the prepared p(NIPAM) based cryogels were determined\nas 34.6±1.2 oC. The immobilization yield, immobilization efficiency, and\nactivity recovery% values were calculated as 89.4±3.1, 66.2±3.3, and\n74.0±3.3%, respectively at pH 6.8 and 37 oC for ɑ-Glu@p(NIPAM) cryogel\nsystem. Interestingly, the optimum working conditions were achieved as\n25 oC and pH 6.8 with higher activity, 98.4±0.2% for the prepared\nɑ-Glu@p(NIPAM) cryogel system. The operational and storage stability\nstudies revealed that the prepared ɑ-Glu@p(NIPAM) cryogel system\npossessed much better operational and storage stability than free ɑ-Glu\nenzyme e.g., more than 50% activity after 10th usage and 10-day room\ntemperature storage time. Moreover, the kinetic parameters such as Km\nand Vmax of free-Glu enzyme and ɑ-Glu@p(NIPAM) cryogel system were\ncalculated by non-linear Michaelis-Menten equation.","PeriodicalId":276433,"journal":{"name":"The Canadian Journal of Chemical Engineering","volume":"33 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2021-01-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"The Canadian Journal of Chemical Engineering","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.22541/AU.161199917.74971044/V1","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 1

Abstract

The concept of using a thermo-responsive p(NIPAM) polymer matrix for enzyme immobilization with lower critical solution temperature (LCST) value is rationalized by availability of the compartmental milieu to enzymes to operate within super porous 3-D matrix with special environmental conditions. Therefore, the enzyme immobilization within a support material will be carried out under the storage conditions of enzymes, generally ~-20 oC to afford unnecessarily loss of enzyme functionality in comparison to the other enzyme entrapment methods. Thus, here ɑ-Glucosidase as a model enzyme was entrapped within thermo-responsive super porous p(NIPAM) cryogels (ɑ-Glu@p(NIPAM) during the synthesis that uses cryogenic condition, ~-20 oC. The LSCT value for the prepared p(NIPAM) based cryogels were determined as 34.6±1.2 oC. The immobilization yield, immobilization efficiency, and activity recovery% values were calculated as 89.4±3.1, 66.2±3.3, and 74.0±3.3%, respectively at pH 6.8 and 37 oC for ɑ-Glu@p(NIPAM) cryogel system. Interestingly, the optimum working conditions were achieved as 25 oC and pH 6.8 with higher activity, 98.4±0.2% for the prepared ɑ-Glu@p(NIPAM) cryogel system. The operational and storage stability studies revealed that the prepared ɑ-Glu@p(NIPAM) cryogel system possessed much better operational and storage stability than free ɑ-Glu enzyme e.g., more than 50% activity after 10th usage and 10-day room temperature storage time. Moreover, the kinetic parameters such as Km and Vmax of free-Glu enzyme and ɑ-Glu@p(NIPAM) cryogel system were calculated by non-linear Michaelis-Menten equation.

查看原文本刊更多论文

热响应性超多孔p(NIPAM)低温保温层通过原位包埋的方式增强了w -葡萄糖苷酶的热稳定性和活性

使用具有较低临界溶液温度(LCST)值的热响应性p(NIPAM)聚合物基质酶固定化的概念是合理的，因为酶可以在具有特殊环境条件的超多孔三维基质中工作。因此，在载体材料内的酶固定将在酶的储存条件下进行，通常为~-20℃，与其他酶包埋方法相比，可以避免不必要的酶功能损失。因此，在低温条件下，~-20℃的合成过程中，作为模型酶的_ -葡萄糖苷酶被包裹在热响应的超多孔p(NIPAM)低温冰箱(_ -Glu@p(NIPAM)中。制备的p(NIPAM)基冷冻液的LSCT值为34.6±1.2℃。在pH 6.8和37 oC条件下，固定化产率、固定化效率和活性回收率分别为89.4±3.1、66.2±3.3和74.0±3.3%。有趣的是，制备的nieam (-Glu@p)低温凝胶体系的最佳工作条件为25℃和pH 6.8，活性较高，为98.4±0.2%。操作稳定性和储存稳定性研究表明，制备的nieam冷冻凝胶体系比游离的nieam -Gluenzyme具有更好的操作和储存稳定性，例如，在第10次使用和10 d的室温储存时间后，其活性超过50%。利用非线性Michaelis-Menten方程重新计算了游离谷氨酸酶的kmax、Vmax等动力学参数和nieam (NIPAM)低温凝胶体系的动力学参数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

The Canadian Journal of Chemical Engineering

自引率

0.00%

发文量