Process optimization for a 3D optical coupler and waveguide fabrication on a single substrate using buffer coat material

<div>As a case study, we consider a coupled enzyme assay of sequential enzyme reactions obeying the Michaelis--Menten reaction mechanism. The sequential reaction consists of a single-substrate, single-enzyme non-observable reaction followed by another single-substrate, single-enzyme observable reaction (indicator reaction). In this assay, the product of the non-observable reaction becomes the substrate of the indicator reaction. A mathematical analysis of the reaction kinetics is performed, and it is found that after an initial fast transient, the sequential reaction is described by a pair of interacting Michaelis--Menten equations. Timescales that approximate the respective lengths of the indicator and non-observable reactions, as well as conditions for the validity of the Michaelis--Menten equations are derived. The theory can be extended to deal with more complex sequences of enzyme catalyzed reactions.</div>

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A kinetic analysis of coupled sequential enzyme reactions

10.26434/chemrxiv.5746065.v1 ◽

2018 ◽

Author(s):

Justin Eilertsen ◽

Santiago Schnell

Keyword(s):

Enzyme Assay ◽

Sequential Reaction ◽

Enzyme Reactions ◽

Indicator Reaction ◽

Single Substrate ◽

Complex Sequences ◽

Catalyzed Reactions ◽

Enzyme Catalyzed Reactions ◽

Single Enzyme

<div>As a case study, we consider a coupled enzyme assay of sequential enzyme reactions obeying the Michaelis-Menten reaction mechanism. The sequential reaction consists of a single-substrate, single enzyme non-observable reaction followed by another single-substrate, single enzyme observable reaction (indicator reaction). In this assay, the product of the non-observable reaction becomes the substrate of the indicator reaction. A mathematical analysis of the reaction kinetics is performed, and it is found that after an initial fast transient, the sequential reaction is described by a pair of interacting Michaelis-Menten equations. Timescales that approximate the respective lengths of the indicator and non-observable reactions, as well as conditions for the validity of the Michaelis-Menten equations are derived. The theory can be extended to deal with more complex sequences of enzyme catalyzed reactions.</div>

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Process optimization: Ultrasonic welding of coextruded polymer film

10.31274/etd-180810-3309 ◽

2013 ◽

Author(s):

Jessica Ann Riedl

Keyword(s):

Polymer Film ◽

Process Optimization ◽

Ultrasonic Welding

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SIGN IN Welcome!Log into your account your username your password Forgot your password Privacy policy PASSWORD RECOVERY Recover your password your email Struktol Home New fast measuring method for process optimization of sucrose crystallization New fast measuring method for process optimization of sucrose crystallization

Sugar Industry ◽

10.36961/si23942 ◽

2020 ◽

pp. 49-52

Author(s):

Trine Aabo Andersen

Keyword(s):

Image Analysis ◽

Process Optimization ◽

Crystal Size ◽

Measuring Method ◽

Sieve Analysis ◽

Image Analysis System ◽

Line System ◽

Non Invasive ◽

Analysis System ◽

User Friendly

A new fast measuring method for process optimization of sucrose crystallization using image analysis based on high quality images and algorithms is introduced. With the mobile, non-invasive at-line system all steps of the sucrose crystallization can be measured to determine the crystal size distribution. The image analysis system is easy to operate and is as well an efficient laboratory solution with user-friendly and customized software. In comparison to sieve analysis, image analyses performed with the ParticleTech Solution have been proven to be reliable.

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