The characteristics of the reaction kinetics of enzyme catalysis in organic solvents were outlined.
对有机相酶促反应动力学进行了概括性的论述。
In certain cases, conformational entropy appears to play a role in cooperative binding and enzyme catalysis.
在某些情况下,似乎象熵中发挥作用的合作具有约束力和酶催化。
It is well known that mimic enzyme catalysis is a novel challenging field in bioorganic chemistry with rapid progress.
众所周知,仿酶催化是生物有机化学领域的挑战性课题,近年来研究进展十分迅速。
Based on MEMS technology and electrochemical detecting principle of bio-enzyme catalysis, one biochip has been developed.
基于生物酶催化的电化学电流检测原理对人体血液生化参数进行测试。
The experiment not only expanded the field of enzyme catalysis, but also have a certain significance to the evolution of enzyme.
本次实验不仅扩大了酶的催化领域,而且对酶的进化具有一定的意义。
Synthetic and functional metal-organic macrocycles are important models to realize the process of enzyme catalysis and recognition.
金属-有机大环结构是一类人工合成的,旨在模拟和学习酶催化及识别过程的重要模型。
Of course, she needs to know the basic principles, but she's also talking about it an enzyme, so she needs to know about enzyme catalysis.
她需要知道这表上的许多东西,当然她需要知道到这些基本原理,她研究的是一种酶。
The property research of surfactant in non-aqueous solution can provide theoretical basis for the research of micelle enzyme catalysis of cellulase.
非水溶液中表面活性剂性质的研究可以为进一步研究纤维素酶的胶束酶催化奠定理论基础。
Specific enzyme catalysis provides a novel synthetic route for useful polyesters, many of which are difficult to be synthesized by conventional methodologies.
尤其是特种酶的应用,为传统方法难以合成的聚酯,开辟了一条新的合成途径。
Factors which affect the efficiency of enzyme catalysis in organic media were discussed. In all of the factors. water activity and solvent are the two important factors.
总结了有机相酶催化的优点与影响因素,其中水活度与溶剂为众多因素中最为引人注目的两大因素。
The technology of ultra-microparticle by SCF, enzyme catalysis in supercritical fluid and supercritical water oxidation were introduced, their applications were also elaborated.
结果已在生物工程领域应用的超临界流体技术有 超临界流体酶催化、 超临界流体发酵、超临界流体灭菌和细胞破碎技术等。
In this thesis, we use sol-gel method to prepare a new kind of multifunctional fiber optic biosensing materials that have the performance of enzyme catalysis and photo-sensitive synchronously.
本文使用溶胶—凝胶技术制备一种新型的同时具有酶催化性能和光敏感性能的多功能光纤生物传感材料。
The immobilization methods of enzyme catalyst and the applications in catalysis reaction were introduced in this paper.
本文对酶催化剂的固定化方法以及在有机催化反应中的应用作了部分简述。
A mechanism in which the active site of the enzyme does not change shape during catalysis.
一种在催化反应中酶活性位点形状不发生改变的机理。
Polymers prepared by molecular imprinting have received much attention in recent years for separations, analysis, immunoassays, catalysis, enzyme mimics and biosensor.
近年来,分子印迹法制得的聚合物在分离、分析、免疫测定、催化、模拟酶及生物传感器等方面的应用引起人们的广泛关注。
Molecularly imprinted polymers will possess promising application future in the separation and analysis, biomimetic sensors and enzyme mimics catalysis.
分子印迹聚合物在分离分析、仿生传感器和模拟酶催化等领域将具有重要的应用前景。
They are widely used in pharmaceutical science, catalysis, separation technology, enzyme models and other areas.
它在合成制药、催化、分离技术以及人造酶应用也越来越广泛。
Some irreversible inhibitors even become covalently bound to amino acids in the active site of the enzyme as they are brought through the early chemical steps of catalysis.
一些不可逆抑制剂,甚至成为共价结合的酶的活性部位的氨基酸,因为他们带来的是通过早期的催化化学步骤。
Because the enzyme-catalyzed reaction is efficient, economical and environmental friendly, it aroused general interest in the research of catalysis today.
酶催化反应是当今催化研究领域的热点,由于酶有着高效,经济,环保等优点而备受亲睐。
A new trend in organic catalyzing synthesis is to utilize these two strategies simultaneously, which is called microwave irradiation-enzyme coupling catalysis (MIECC).
目前一种新的研究动向是将两者结合起来用于催化合成反应,这种新型催化方法可以被称作微波辐射-酶耦合催化(MIECC)。
In this paper, its structure, catalysis characteristics, the main enzyme-producing microorganisms and its potential application in different area are reviewed.
本文介绍了阿魏酸酯酶的结构特征、酶学特性、产酶微生物及其在食品、饲料和造纸工业中应用的前景。
The hybrid enzyme techniques have been used to modify enzyme's non-catalysis characters, create novel enzymes, study the relationship between function and structure of protein.
将杂交酶的应用分为以下几个主要的方面:改变酶的非催化特性;创造新活性的酶;研究蛋白质的结构和功能的关系等。
The catalysis of enzyme improved by nanoparticles is discussed. The influence of different conditions is analyzed.
探讨纳米颗粒效应在固定化酶中所起的作用,并分析不同条件对酶电极响应灵敏度的影响。
The catalysis of enzyme improved by nanoparticles is discussed. The influence of different conditions is analyzed.
探讨纳米颗粒效应在固定化酶中所起的作用,并分析不同条件对酶电极响应灵敏度的影响。
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