| Self-contained microelectrochemical immunoassay for small volumes using mouse IgG as a model system ZP Aguilar, WR Vandaveer, I Fritsch Analytical Chemistry 74 (14), 3321-3329, 2002 | 158 | 2002 |
| Self-contained microelectrochemical bioassay platforms and methods I Fritsch, R Beitle Jr, Z Aguilar US Patent 7,348,183, 2008 | 128 | 2008 |
| Magnetic fields for fluid motion MC Weston, MD Gerner, I Fritsch Analytical chemistry 82 (9), 3411-3418, 2010 | 122 | 2010 |
| Fabrication and characterization of sputtered-carbon microelectrode arrays G Sreenivas, SS Ang, I Fritsch, WD Brown, GA Gerhardt, DJ Woodward Analytical chemistry 68 (11), 1858-1864, 1996 | 114 | 1996 |
| Potential-dependent stability of self-assembled organothiols on gold electrodes in methylene chloride WR Everett, TL Welch, L Reed, I Fritsch-Faules Analytical Chemistry 67 (2), 292-298, 1995 | 103 | 1995 |
| Laser desorption fourier transform mass spectrometry exchange studies of air-oxidized alkanethiol self-assembled monolayers on gold JR Scott, LS Baker, WR Everett, CL Wilkins, I Fritsch Analytical Chemistry 69 (14), 2636-2639, 1997 | 100 | 1997 |
| Microfabricated recessed microdisk electrodes: characterization in static and convective solutions CS Henry, I Fritsch Analytical chemistry 71 (3), 550-556, 1999 | 84 | 1999 |
| Factors that influence the stability of self-assembled organothiols on gold under electrochemical conditions WR Everett, I Fritsch-Faules Analytica chimica acta 307 (2-3), 253-268, 1995 | 81 | 1995 |
| Microvolume immunoabsorbant assays with amplified electrochemical detection I Fritsch, R Beittle Jr US Patent 6,887,714, 2005 | 72 | 2005 |
| Individually addressable, submicrometer band electrode arrays. 1. Fabrication from multilayered materials MP Nagale, I Fritsch Analytical Chemistry 70 (14), 2902-2907, 1998 | 70 | 1998 |
| Immobilized Enzyme-Linked DNA-Hybridization Assay with Electrochemical Detection for Cryptosporidium parvum hsp70 mRNA ZP Aguilar, I Fritsch Analytical chemistry 75 (15), 3890-3897, 2003 | 69 | 2003 |
| Microcavities containing individually addressable recessed microdisk and tubular nanoband electrodes CS Henry, I Fritsch Journal of the Electrochemical Society 146 (9), 3367, 1999 | 67 | 1999 |
| A microscopic model for diffusion of electrons by successive hopping among redox centers in networks I Fritsch-Faules, LR Faulkner Journal of electroanalytical chemistry and interfacial electrochemistry 263 …, 1989 | 65 | 1989 |
| Feedback-independent Pt nanoelectrodes for shear force-based constant-distance mode scanning electrochemical microscopy M Etienne, EC Anderson, SR Evans, W Schuhmann, I Fritsch Analytical chemistry 78 (20), 7317-7324, 2006 | 64 | 2006 |
| Microfluidic device utilizing magnetohydrodynamics and method for fabrication thereof ESO Fakunle, PU Arumugam, I Fritsch, JE Mincy, FD Barlow III, G Wang US Patent 7,467,928, 2008 | 59 | 2008 |
| Redox cycling measurements of a model compound and dopamine in ultrasmall volumes with a self-contained microcavity device WR Vandaveer IV, DJ Woodward, I Fritsch Electrochimica acta 48 (20-22), 3341-3348, 2003 | 59 | 2003 |
| Individually addressable, submicrometer band electrode arrays. 2. Electrochemical characterization MP Nagale, I Fritsch Analytical Chemistry 70 (14), 2908-2913, 1998 | 57 | 1998 |
| Microfabricated recessed disk microelectrodes: characterization in static and convective solutions I Fritsch, CS Henry, BP Bowen, W Vandaveer, N Bratcher US Patent 7,169,272, 2007 | 52 | 2007 |
| Signal amplification in a microchannel from redox cycling with varied electroactive configurations of an individually addressable microband electrode array PM Lewis, LB Sheridan, RE Gawley, I Fritsch Analytical chemistry 82 (5), 1659-1668, 2010 | 48 | 2010 |
| Study of magnetohydrodynamic driven flow through LTCC channel with self-contained electrodes ZP Aguilar, P Arumugam, I Fritsch Journal of Electroanalytical Chemistry 591 (2), 201-209, 2006 | 45 | 2006 |
