| - - - |
Particle electrophoresis
Bauer J |
| 1957 - 1972 |
Separation and characterization of sub-mu m- and mu m-sized particles by capillary zone electrophoresis
Radko SP, Chrambach A |
| 1973 - 1983 |
Particle separation by dielectrophoresis
Gascoyne PRC, Vykoukal J |
| 1984 - 1994 |
Electrophoresis of cells and the biological relevance of surface charge
Mehrishi JN, Bauer J |
| 1995 - 2000 |
Electrophoretic mobility of a charged spherical colloidal particle covered with an uncharged polymer layer
Ohshima H |
| 2001 - 2006 |
Electrophoretic behavior of cerebellar granule neurons
Hsu JP, Huang SW, Hsieh TS, Young TH, Hu WW |
| 2007 - 2011 |
Softness of the bacterial cell wall of Streptococcus mitis as probed by microelectrophoresis
Rodriguez VV, Busscher HJ, Norde W, van der Mei HC |
| 2012 - 2022 |
Electrophoresis of solid particles at large Peclet numbers
Mishchuk NA, Dukhin SS |
| 2023 - 2028 |
Electrophoresis of randomly charged particles
Velegol D |
| 2029 - 2034 |
Immunoelectrophoresis of red blood cells performed on microcapillary chips
Ichiki T, Ujiie T, Shinbashi S, Okuda T, Horiike Y |
| 2035 - 2039 |
Estimation of electrophoretic mobilities of red blood cells in 1-G and microgravity using a miniature capillary electrophoresis unit
Tsuda T, Kitagawa S, Yamamoto Y |
| 2040 - 2047 |
Determination of individual microsphere properties by capillary electrophoresis with laser-induced fluorescence detection
Duffy CF, McEathron AA, Arriaga EA |
| 2048 - 2056 |
Monitoring the migration behavior of living microorganisms in capillary electrophoresis using laser-induced fluorescence detection with a charge-coupled device imaging system
Girod M, Armstrong DW |
| 2057 - 2063 |
Dielectrophoretic studies of the activation of human T lymphocytes using a newly developed cell profiling system
Pethig R, Bressler V, Carswell-Crumpton C, Chen Y, Foster-Haje L, Garcia-Ojeda ME, Lee RS, Lock GM, Talary MS, Tate KM |
| 2064 - 2073 |
Multistage electrophoresis II: Treatment of a kinetic separation as a pseudoequilibrium process
Sengupta S, Todd P, Thomas N |
| 2074 - 2079 |
Application of intracellular microelectrophoresis to analysis of the influence of the low-level microwave radiation on electrokinetic properties of nuclei in human epithelial cells
Shckorbatov YG, Shakhbazov VG, Navrotskaya VV, Grabina VA, Sirenko SP, Fisun AI, Gorobets NN, Kiyko VI |
| 2080 - 2086 |
Probing cell surface charge by scanning electrode potential
Svetlicic V, Hozic A |
| 2087 - 2095 |
Cell adhesion and the negative cell surface charges in embryonic cells of the starfish Asterina pectinifera
Masui M, Takata H, Kominami T |
| 2096 - 2102 |
Characterization of the early stages of programmed cell death in maize root cells by using comet assay and the combination of cell electrophoresis with annexin binding
Ning SB, Song YC, van Damme P |
| 2103 - 2109 |
Particle electrophoresis as a tool to understand the aggregation behavior of red blood cells
Baskurt OK, Tugral E, Neu B, Meiselman HJ |
| 2110 - 2116 |
Electrophoretic behavior of individual nuclear species as determined by capillary electrophoresis with laser-induced fluorescence detection
Gunasekera N, Musier-Forsyth K, Arriaga E |
| 2117 - 2129 |
Different temperature sensitivity of endosomes involved in transport to lysosomes and transcytosis in rat hepatocytes: Analysis by free-flow electrophoresis
Ellinger I, Klapper H, Courtoy PJ, Vaerman JP, Fuchs R |
| 2130 - 2137 |
Isolation of peroxisomal subpopulations from mouse liver by immune free-flow electrophoresis
Mohr H, Volkl A |
| 2138 - 2143 |
Electrokinetic and light scattering properties of pea and Chlamydomonas reinhardtii thylakoid membranes: Effect of phytohemagglutinin
Doltchinkova VR, Lambreva MD |
