Molecular size and charge characterization by rheophoresis I. Theory and gel calibration

Henrik Waldmann‐Meyer; Per Amstrup Pedersen

doi:10.1002/elps.1150050103

Molecular size and charge characterization by rheophoresis I. Theory and gel calibration

Henrik Waldmann‐Meyer^*, Per Amstrup Pedersen

^*Corresponding author for this work

Cell Biology and Physiology

2 Citations (Scopus)

Abstract

Rheophoresis, i.e. thin‐layer electrophoresis in particulate gels with controlled evaporation, combines in one experiment the chromatographic and the electrophoretic characteristics of macromlecules in such a way that they can be determined independently of each other. In this paper theory and experimental corroboration for molecular size determination are presented. We describe the migration velocity of any molecule as the sum of an electrophoretic, an electroosmotic and a rheophoretic component. The latter is the velocity originating from the liquid flow produced by evaporation. It is a function of the position along the gel axis and the cross‐section available to the molecule, but totally independent of the molecular charge. As a result of the position dependence, the rheophoretic component can be isolated from the two others and the available cross‐section determined by means of a simple plot. Thus, the chromatographic partition coefficient is readily calculated and the effective hydrodynamic radius of the molecule obtained.

Original language	English
Journal	Electrophoresis
Volume	5
Issue number	1
Pages (from-to)	18-21
Number of pages	4
ISSN	0173-0835
DOIs	https://doi.org/10.1002/elps.1150050103
Publication status	Published - 1 Jan 1984

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10.1002/elps.1150050103

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abstract = "Rheophoresis, i.e. thin‐layer electrophoresis in particulate gels with controlled evaporation, combines in one experiment the chromatographic and the electrophoretic characteristics of macromlecules in such a way that they can be determined independently of each other. In this paper theory and experimental corroboration for molecular size determination are presented. We describe the migration velocity of any molecule as the sum of an electrophoretic, an electroosmotic and a rheophoretic component. The latter is the velocity originating from the liquid flow produced by evaporation. It is a function of the position along the gel axis and the cross‐section available to the molecule, but totally independent of the molecular charge. As a result of the position dependence, the rheophoretic component can be isolated from the two others and the available cross‐section determined by means of a simple plot. Thus, the chromatographic partition coefficient is readily calculated and the effective hydrodynamic radius of the molecule obtained.",

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T1 - Molecular size and charge characterization by rheophoresis I. Theory and gel calibration

AU - Waldmann‐Meyer, Henrik

AU - Pedersen, Per Amstrup

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N2 - Rheophoresis, i.e. thin‐layer electrophoresis in particulate gels with controlled evaporation, combines in one experiment the chromatographic and the electrophoretic characteristics of macromlecules in such a way that they can be determined independently of each other. In this paper theory and experimental corroboration for molecular size determination are presented. We describe the migration velocity of any molecule as the sum of an electrophoretic, an electroosmotic and a rheophoretic component. The latter is the velocity originating from the liquid flow produced by evaporation. It is a function of the position along the gel axis and the cross‐section available to the molecule, but totally independent of the molecular charge. As a result of the position dependence, the rheophoretic component can be isolated from the two others and the available cross‐section determined by means of a simple plot. Thus, the chromatographic partition coefficient is readily calculated and the effective hydrodynamic radius of the molecule obtained.

AB - Rheophoresis, i.e. thin‐layer electrophoresis in particulate gels with controlled evaporation, combines in one experiment the chromatographic and the electrophoretic characteristics of macromlecules in such a way that they can be determined independently of each other. In this paper theory and experimental corroboration for molecular size determination are presented. We describe the migration velocity of any molecule as the sum of an electrophoretic, an electroosmotic and a rheophoretic component. The latter is the velocity originating from the liquid flow produced by evaporation. It is a function of the position along the gel axis and the cross‐section available to the molecule, but totally independent of the molecular charge. As a result of the position dependence, the rheophoretic component can be isolated from the two others and the available cross‐section determined by means of a simple plot. Thus, the chromatographic partition coefficient is readily calculated and the effective hydrodynamic radius of the molecule obtained.

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Molecular size and charge characterization by rheophoresis I. Theory and gel calibration

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