Separators electrophoresis

Boyd, BM Prausnitz, JM Blanch, HW, High-Frequency Altemating-Cross-Field Gel Electrophoresis with Neutral or Shghtly Charged Interpenetrating Networks to Improve DNA Separation, Electrophoresis 19, 3137, 1998. 

Rossier, IS Schwarz, A Reymond, F Ferrigno, R Bianchi, F Girault, HH, MicroChannel Networks for Electrophoretic Separations, Electrophoresis 20, 727, 1999. 

Zhu, Y. Lubman, D. M. Narrow-band fractionation of proteins from whole cell lysates using isoelectric membrane focusing and nonporous reversed-phase separations. Electrophoresis 2004, 25, 949-958. 

Chen, J., Lee, C.S., Shen, Y., Smith, R.D., Baehrecke, E.H. (2002). Integration of capillary isoelectric focusing with capillary reversed-phase liquid chromatography for two-dimensional proteomics separation. Electrophoresis 23, 3143-3148. 

Check transfer efficiency by staining the gel after transfer, or by staining a second blot with a total protein stain, such as coomassie blue or ponceau red. Alternatively, use commercially available prestained protein standards that are run along the samples of interest and that are visible during both the separation electrophoresis and on the membrane after transfer... 

Perrin, C., Fabre, H., Massart, D. L., and Vander Heyden, Y. (2003). Influence of peak measurement parameters on the quality of chiral electrophoretic separations. Electrophoresis 24, 2469—2480. 

B Chankvetadze, N Burjanadze, D Bergenthal, G Blaschke. Potential of flow-counterbalanced capillary electrophoresis for analytical and micropreparative separations. Electrophoresis 20 2680-2685, 1999. 

Any book must leave something out, and this one has left out a good deal it does not cover membranes used in packaging materials, sensors, ion-selective electrodes, fuel cells, battery separators, electrophoresis and thermal diffusion. In this final chapter, five processes that come under the general title of other are covered briefly. 

Berger, M., Castelino, J., Huang, R., Shah, M., Austin, R.H., Design of a micro-fabricated magnetic cell separator Electrophoresis 2001, 22, 3883-3892. 

J.S. Rossier, A. Schwarz, F. Reymond, R. Ferrigno, F. Bianchi and H.H. Girault, MicroChannel networks for electrophoretic separations. Electrophoresis, 20 (1999) 727-731. 

Chankvetadze B, Endresz G, Blaschke G. About some aspects of the use of charged cyclodextrins for capillary electrophoresis enantio-separation. Electrophoresis 1994 15(6) 804-807. 

On the other hand, the intervening media used in electrophoresis have much lower conductivity, and an equivalent circuit for an electrophoresis cell includes a resistor between the capacitors at the electrode-solution interfaces. Across the support medium, potential is now (usually) a linear function of distance, and the electric field thus generated is responsible for driving the electrophoretic separation. Electrophoresis occurs at the electrodes used in electrophoresis, to maintain the... 

Shen Y, Smith RD. Proteomics based on high-efficiency capillary separations. Electrophoresis 2002 23 ... 

Detailed chemical investigation of the parvalbumins began with the demonstration that the low molecular weight myogens of carp white muscle were composed of three components, designated as 2, 3 and 5, which could be separated electrophoresis (102). These proteins were not present in red muscle of cod (102), demonstrating a protein difference between the two types of muscle. The three cod parvalbumins have been crystallized (103) and their amino acid composition has been determined. The three proteins have only small differences in amino acid composition, molecular weight and other physical properties. 

Fig. 6.S. Diagrammatic representation of cutting the paper sheet for two dimensional separation electrophoresis and chromatography.

AUen, D. and El Rassi, Z., Sflica-based monohths for capillary electrochromatography Methods of fabrication and their applications in analytical separations. Electrophoresis, 24, 3962, 2003. 

Shen, Y. and Smith, R. D. Proteomics based on high-efficiency capiUary separations. Electrophoresis, 23, 3106, 2002. 

Zhao, S., Xie, C., Lu, X., Song, Y, and Liu, Y. M., A facile and sensitive chemiluminescence detection of amino acids in biological samples after capillary electrophoretic separation. Electrophoresis, 26, 1745,2005. 

Kirby, B.J. and Hasselbrink, E.F., Zeta potential of microfluidic substrates 1. Theory, experimental techniques, and effects on separations. Electrophoresis, 2004, 25 187-202. 

Boer, T. Mol, R. Zeeuw, R.A. Jong, G.J. Sherrington, D.C. Cormack, P.A.G. Ensing, K. Spherical molecularly imprinted polymer particles a promising tool for molecular recognition in capillary electrokinetic separations. Electrophoresis 2002, 23, 1296-1300. 

Long D, Ajdari A (1996) Electrophoretic mobility of composite objects in fee solution application to DNA separation. Electrophoresis 17 1161-1166... 

Faure K, Albert M, Dugas V, CretiCT G, Ferrigno R, Morin P, Rocca JL (2008) Development of an acrylate monolith in a cyclo-olefin copolymer microfluidic device for chip electrochromatography separation. Electrophoresis 29 4948-4955... 

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