Frédéric Reymond scite author profile

A new protein fractionation technique based on off-gel isoelectric focusing (IEF) is presented, where the proteins are separated according to their isoelectric point (pI) in a multiwell device with the advantage to be directly recovered in solution for further analysis. The protein fractions obtained with this technique have then been characterized with polymer nanoelectrospray for mass spectrometry (MS) analyses or with Bioanalyzer for mass identification. This methodology shows the possibility of developing alternatives to the classical two-dimensional (2-D) gel electrophoresis. One species numerical simulation of the electric field distribution during off-gel separation is also presented in order to demonstrate the principle of the purification. Experiments with pI protein markers have been carried out in order to highlight the kinetics and the efficiency of the technique. Moreover, the resolution of the fractionation was shown to be 0.1 pH unit for the separation of beta-lactoglobulin A and B. In addition, the isoelectric fractionation of an Escherichia coli extract was performed in standard solubilization buffer to demonstrate the performances of the technique, notably for proteomics applications.

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Polymer microfluidic chips for electrochemical and biochemical analyses

Rossier

2002

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Our recent developments concerning the fabrication of polymer microchips and their applications for biochemical analyses are reviewed. We first describe two methods of fabrication of polymer microfluidic chips, namely UV-laser photoablation and plasma etching that are well suited for the prototyping and mass fabrication of microchannel networks with integrated microelectrodes. These microanalytical systems can be coupled with various detection means including mass spectrometry, and their applications in capillary electrophoresis are presented here. We also present how UV laser photoablation can be used for the patterning of biomolecules on polymer surfaces for generating two-dimensional arrays of microspots to carry out affinity assays. Finally, the use of the microchips for the development of fast affinity and immunological assays with electrochemical detection is presented, demonstrating the potential of these polymer microchips for medical diagnostics and drug discovery.

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Ionic Partition Diagrams: A Potential−pH Representation

et al. 1996

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A general method to predict and interpret the transfer mechanisms of ionizable compounds at the interface between two immiscible electrolyte solutions (ITIES) is presented. The approach is based on the construction of the ionic partition diagram of the solute. It consists in defining equiconcentration boundaries as a function of the Galvani potential difference and aqueous pH by taking into account the thermodynamic equilibria governing the distribution of the various acid/base forms of the molecules involved. The method defines the domains of predominance of each species either in the aqueous or in the organic phase. The application of ionic partition diagrams to quinidine offers a global and direct visualization of all the species and demonstrates the validity and efficiency of the method in helping to understand the transfer and partition mechanisms of ionizable drugs.

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