Differential effects of EGF gradient profiles on MDA-MB-231 breast cancer cell chemotaxis SJ Wang, W Saadi, F Lin, CMC Nguyen, NL Jeon Experimental cell research 300 (1), 180-189, 2004 | 270 | 2004 |
Generation of dynamic temporal and spatial concentration gradients using microfluidic devices F Lin, W Saadi, SW Rhee, SJ Wang, S Mittal, NL Jeon Lab on a Chip 4 (3), 164-167, 2004 | 233 | 2004 |
A parallel-gradient microfluidic chamber for quantitative analysis of breast cancer cell chemotaxis W Saadi, SJ Wang, F Lin, NL Jeon Biomedical microdevices 8 (2), 109-118, 2006 | 212 | 2006 |
Generation of stable concentration gradients in 2D and 3D environments using a microfluidic ladder chamber W Saadi, SW Rhee, F Lin, B Vahidi, BG Chung, NL Jeon Biomedical microdevices 9 (5), 627-635, 2007 | 197 | 2007 |
T cell chemotaxis in a simple microfluidic device F Lin, EC Butcher Lab on a Chip 6 (11), 1462-1469, 2006 | 188 | 2006 |
Effective neutrophil chemotaxis is strongly influenced by mean IL-8 concentration F Lin, CMC Nguyen, SJ Wang, W Saadi, SP Gross, NL Jeon Biochemical and biophysical research communications 319 (2), 576-581, 2004 | 172 | 2004 |
Microfluidics for food, agriculture and biosystems industries S Neethirajan, I Kobayashi, M Nakajima, D Wu, S Nandagopal, F Lin Lab on a Chip 11 (9), 1574-1586, 2011 | 144 | 2011 |
Recent developments in microfluidics-based chemotaxis studies J Wu, X Wu, F Lin Lab on a Chip 13 (13), 2484-2499, 2013 | 121 | 2013 |
Neutrophil migration in opposing chemoattractant gradients using microfluidic chemotaxis devices F Lin, CMC Nguyen, SJ Wang, W Saadi, SP Gross, NL Jeon Annals of biomedical engineering 33 (4), 475-482, 2005 | 116 | 2005 |
A microfluidic multi-injector for gradient generation BG Chung, F Lin, NL Jeon Lab on a Chip 6 (6), 764-768, 2006 | 113 | 2006 |
Microfluidic devices for studying chemotaxis and electrotaxis J Li, F Lin Trends in cell biology 21 (8), 489-497, 2011 | 111 | 2011 |
Lymphocyte electrotaxis in vitro and in vivo F Lin, F Baldessari, CC Gyenge, T Sato, RD Chambers, JG Santiago, ... The Journal of Immunology 181 (4), 2465-2471, 2008 | 110 | 2008 |
E-cadherin plays an essential role in collective directional migration of large epithelial sheets L Li, R Hartley, B Reiss, Y Sun, J Pu, D Wu, F Lin, T Hoang, S Yamada, ... Cellular and Molecular Life Sciences 69 (16), 2779-2789, 2012 | 99 | 2012 |
Novel developments in mobile sensing based on the integration of microfluidic devices and smartphones K Yang, H Peretz-Soroka, Y Liu, F Lin Lab on a Chip 16 (6), 943-958, 2016 | 96 | 2016 |
Intracellular actin-based transport: how far you go depends on how often you switch J Snider, F Lin, N Zahedi, V Rodionov, CY Clare, SP Gross Proceedings of the National Academy of Sciences 101 (36), 13204-13209, 2004 | 90 | 2004 |
Activated T lymphocytes migrate toward the cathode of DC electric fields in microfluidic devices J Li, S Nandagopal, D Wu, SF Romanuik, K Paul, DJ Thomson, F Lin Lab on a Chip 11 (7), 1298-1304, 2011 | 64 | 2011 |
Combinatorial guidance by CCR7 ligands for T lymphocytes migration in co-existing chemokine fields S Nandagopal, D Wu, F Lin PloS one 6 (3), e18183, 2011 | 60 | 2011 |
Microfluidic device for studying cell migration in single or co-existing chemical gradients and electric fields J Li, L Zhu, M Zhang, F Lin Biomicrofluidics 6 (2), 024121, 2012 | 59 | 2012 |
The physiology of bioelectricity in development, tissue regeneration and cancer CE Pullar CRC Press, 2016 | 52 | 2016 |
DC electric fields direct breast cancer cell migration, induce EGFR polarization, and increase the intracellular level of calcium ions D Wu, X Ma, F Lin Cell biochemistry and biophysics 67 (3), 1115-1125, 2013 | 43 | 2013 |