The upcoming 3D-printing revolution in microfluidics N Bhattacharjee, A Urrios, S Kang, A Folch Lab on a Chip 16 (10), 1720-1742, 2016 | 1147 | 2016 |
3D-printed microfluidic automation AK Au, N Bhattacharjee, LF Horowitz, TC Chang, A Folch Lab on a Chip 15 (8), 1934-1941, 2015 | 357 | 2015 |
Desktop‐stereolithography 3D‐printing of a poly (dimethylsiloxane)‐based material with sylgard‐184 properties N Bhattacharjee, C Parra‐Cabrera, YT Kim, AP Kuo, A Folch Advanced materials 30 (22), 1800001, 2018 | 302 | 2018 |
3D-printing of transparent bio-microfluidic devices in PEG-DA A Urrios, C Parra-Cabrera, N Bhattacharjee, AM Gonzalez-Suarez, ... Lab on a Chip 16 (12), 2287-2294, 2016 | 287 | 2016 |
3D-printed Quake-style microvalves and micropumps YS Lee, N Bhattacharjee, A Folch Lab on a Chip 18 (8), 1207-1214, 2018 | 165 | 2018 |
High‐precision stereolithography of biomicrofluidic devices AP Kuo, N Bhattacharjee, YS Lee, K Castro, YT Kim, A Folch Advanced materials technologies 4 (6), 1800395, 2019 | 115 | 2019 |
A neuron-benign microfluidic gradient generator for studying the response of mammalian neurons towards axon guidance factors N Bhattacharjee, N Li, TM Keenan, A Folch Integrative Biology 2 (11-12), 669-679, 2010 | 110 | 2010 |
Digital manufacturing for microfluidics A Naderi, N Bhattacharjee, A Folch Annual review of biomedical engineering 21 (1), 325-364, 2019 | 98 | 2019 |
A microfluidic platform for functional testing of cancer drugs on intact tumor slices AD Rodriguez, LF Horowitz, K Castro, H Kenerson, N Bhattacharjee, ... Lab on a Chip 20 (9), 1658-1675, 2020 | 64 | 2020 |
Microfluidic transwell inserts for generation of tissue culture-friendly gradients in well plates CG Sip, N Bhattacharjee, A Folch Lab on a Chip 14 (2), 302-314, 2014 | 63 | 2014 |
Electrochemically programmed release of biomolecules and nanoparticles P Mali, N Bhattacharjee, PC Searson Nano letters 6 (6), 1250-1253, 2006 | 59 | 2006 |
Utilization of extracellular information before ligand-receptor binding reaches equilibrium expands and shifts the input dynamic range AC Ventura, A Bush, G Vasen, MA Goldín, B Burkinshaw, N Bhattacharjee, ... Proceedings of the National Academy of Sciences 111 (37), E3860-E3869, 2014 | 48 | 2014 |
Digital manufacturing of selective porous barriers in microchannels using multi-material stereolithography YT Kim, K Castro, N Bhattacharjee, A Folch Micromachines 9 (3), 125, 2018 | 44 | 2018 |
Large-scale microfluidic gradient arrays reveal axon guidance behaviors in hippocampal neurons N Bhattacharjee, A Folch Microsystems & Nanoengineering 3 (1), 1-14, 2017 | 43 | 2017 |
Partitioning of hydrogels in 3D-printed microchannels YT Kim, S Bohjanen, N Bhattacharjee, A Folch Lab on a Chip 19 (18), 3086-3093, 2019 | 36 | 2019 |
A modular cell culture device for generating arrays of gradients using stacked microfluidic flows CG Sip, N Bhattacharjee, A Folch Biomicrofluidics 5 (2), 2011 | 29 | 2011 |
Continuous-flow multi-pulse electroporation at low DC voltages by microfluidic flipping of the voltage space topology N Bhattacharjee, LF Horowitz, A Folch Applied Physics Letters 109 (16), 2016 | 20 | 2016 |
Method and device for controlled release of biomolecules and nanoparticles P Searson, N Bhatacharjee, P Mali US Patent App. 11/804,964, 2008 | 10 | 2008 |
An open-chamber flow-focusing device for focal stimulation of micropatterned cells JW Cheng, TC Chang, N Bhattacharjee, A Folch Biomicrofluidics 10 (2), 2016 | 6 | 2016 |
Study of axon-guidance interactions in controlled microfluidic environments S Moorjani, S Huh, N Bhattacharjee, A Folch Proceed MicroTAS, 401-403, 2012 | 4 | 2012 |