Journal article
Steady‐state protein focusing in carrier ampholyte based isoelectric focusing: Part I—Analytical solution
Electrophoresis, Vol.38(5), pp.659-666
03/2017
Handle:
https://hdl.handle.net/2376/109042
PMID: 27874208
Abstract
The determination of an analytical solution to find the steady‐state protein concentration distribution in IEF is very challenging due to the nonlinear coupling between mass and charge conservation equations. In this study, approximate analytical solutions are obtained for steady‐state protein distribution in carrier ampholyte based IEF. Similar to the work of Svensson, the final concentration profile for proteins is assumed to be Gaussian, but appropriate expressions are presented in order to obtain the effective electric field and pH gradient in the focused protein band region. Analytical results are found from iterative solutions of a system of coupled algebraic equations using only several iterations for IEF separation of three plasma proteins: albumin, cardiac troponin I, and hemoglobin. The analytical results are compared with numerically predicted results for IEF, showing excellent agreement. Analytically obtained electric field and ionic conductivity distributions show significant deviation from their nominal values, which is essential in finding the protein focusing behavior at isoelectric points. These analytical solutions can be used to determine steady‐state protein concentration distribution for experiment design of IEF considering any number of proteins and ampholytes. Moreover, the model presented herein can be used to find the conductivity, electric field, and pH field.
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Details
- Title
- Steady‐state protein focusing in carrier ampholyte based isoelectric focusing: Part I—Analytical solution
- Creators
- Jaesool Shim - Yeungnam UniversityKisoo Yoo - Yeungnam UniversityPrashanta Dutta - Washington State University
- Publication Details
- Electrophoresis, Vol.38(5), pp.659-666
- Academic Unit
- Mechanical and Materials Engineering, School of
- Number of pages
- 8
- Grant note
- U.S. National Science Foundation Yeungnam University Research Grant DMS (1317671)
- Identifiers
- 99900547233801842
- Language
- English
- Resource Type
- Journal article