| 2613 - 2613 |
Instrumentation for Capillary and Microchip Electrophoresis
Carrilho E, Garcia CD |
| 2614 - 2623 |
Instrumentation design for hydrodynamic sample injection in microchip electrophoresis: A review
Saito RM, Coltro WKT, de Jesus DP |
| 2624 - 2638 |
Microchip capillary electrophoresis instrumentation for in situ analysis in the search for extraterrestrial life
Mora MF, Stockton AM, Willis PA |
| 2639 - 2649 |
Microfabricated devices for biomolecule encapsulation
Desmarais SM, Haagsman HP, Barron AE |
| 2650 - 2659 |
Unmanned platform for long-range remote analysis of volatile compounds in air samples
da Costa ET, Neves CA, Hotta GM, Vidal DTR, Barros MF, Ayon AA, Garcia CD, do Lago CL |
| 2660 - 2667 |
Polyester-toner electrophoresis microchips with improved analytical performance and extended lifetime
Gabriel EFM, Duarte GF, Garcia PD, de Jesus DP, Coltro WKT |
| 2668 - 2673 |
Fluid mixing using AC electrothermal flow on meandering electrodes in a microchannel
Sasaki N, Kitamori T, Kim HB |
| 2674 - 2681 |
Thermally responsive phospholipid preparations for fluid steering and separation in microfluidics
Wu XW, Langan TJ, Durney BC, Holland LA |
| 2682 - 2688 |
Electrowetting on dielectric actuation of droplets with capillary electrophoretic zones for MALDI mass spectrometric analysis
Gorbatsova J, Borissova M, Kaljurand M |
| 2689 - 2694 |
Development and characterization of a novel semiautomated arrangement for electrochemically assisted injection in combination with capillary electrophoresis time-of-flight mass spectrometry
Palatzky P, Matysik FM |
| 2695 - 2702 |
Electrokinetic injection across supported liquid membranes: New sample pretreatment technique for online coupling to capillary electrophoresis. Direct analysis of perchlorate in biological samples
Kuban P, Kiplagat IK, Bocek P |
| 2703 - 2710 |
Micellar affinity gradient focusing in a microfluidic chip with integrated bilinear temperature gradients
Shameli SM, Glawdel T, Fernand VE, Ren CL |
| 2711 - 2717 |
Implementation of a genetically tuned neural platform in optimizing fluorescence from receptor-ligand binding interactions on microchips
Alvarado J, Hanrahan G, Nguyen HTH, Gomez FA |
| 2718 - 2724 |
High electric field strength two-dimensional peptide separations using a microfluidic device
Henley WH, Ramsey JM |
| 2725 - 2732 |
A parallel dual-electrode detector for capillary electrophoresis
Dorris MK, Crick EW, Lunte CE |
| 2733 - 2742 |
Smart portable electrophoresis instrument based on multipurpose microfluidic chips with electrochemical detection
Fernandez-la-Villa A, Sanchez-Barragan D, Pozo-Ayuso DF, Castano-Alvarez M |
| 2743 - 2747 |
Sheath-flow electrochemical detection of amino acids with a copper wire electrode in capillary electrophoresis
Inoue J, Kaneta T, Imasaka T |
| 2748 - 2751 |
Desktop near-field thermal-lens microscope for thermo-optical detection in microfluidics
Smirnova A, Proskurnin MA, Mawatari K, Kitamori T |
| 2752 - 2758 |
Light-emitting diode induced fluorescence (LED-IF) detection design for a pen-shaped cartridge based single capillary electrophoresis system
Kerekgyarto M, Kerekes T, Tsai E, Amirkhanian VD, Guttman A |
| 2759 - 2768 |
In situ particle zeta potential evaluation in electroosmotic flows from time-resolved microPIV measurements
Sureda M, Miller A, Diez FJ |
| 2769 - 2776 |
Comparative microRNA detection from precursor-microRNA-transfected hepatocellular carcinoma cells by capillary electrophoresis with dual-color laser-induced fluorescence
Yang TH, Ou DL, Hsu C, Huang SH, Chang PL |
| 2777 - 2782 |
Development and validation of a capillary electrophoresis method with capacitively coupled contactless conductivity detection (CE-C4D) for the analysis of amikacin and its related substances
El-Attug MN, Adams E, Van Schepdael A |
| 2783 - 2789 |
Selection of bovine catalase aptamers using non-SELEX
Ashley J, Ji KL, Li SFY |
| 2790 - 2797 |
Qualitative and quantitative evaluation of Simon (TM), a new CE-based automated Western blot system as applied to vaccine development
Rustandi RR, Loughney JW, Hamm M, Hamm C, Lancaster C, Mach A, Ha S |
