Visual space is represented by nonmatching topographies of distinct mouse retinal ganglion cell types A Bleckert, GW Schwartz, MH Turner, F Rieke, ROL Wong Current Biology 24 (3), 310-315, 2014 | 238 | 2014 |
The spatial structure of a nonlinear receptive field GW Schwartz, H Okawa, FA Dunn, JL Morgan, D Kerschensteiner, ... Nature neuroscience 15 (11), 1572-1580, 2012 | 210 | 2012 |
Synchronized firing among retinal ganglion cells signals motion reversal G Schwartz, S Taylor, C Fisher, R Harris, MJ Berry Neuron 55 (6), 958-969, 2007 | 130 | 2007 |
The synaptic and circuit mechanisms underlying a change in spatial encoding in the retina WN Grimes, GW Schwartz, F Rieke Neuron 82 (2), 460-473, 2014 | 126 | 2014 |
Detection and prediction of periodic patterns by the retina G Schwartz, R Harris, D Shrom, MJ Berry Nature neuroscience 10 (5), 552-554, 2007 | 122 | 2007 |
Shadows of the past: Temporal retrieval effects in recognition memory G Schwartz, MW Howard, B Jing, MJ Kahana Psychological Science 16 (11), 898-904, 2005 | 122 | 2005 |
Nonlinear spatiotemporal integration by electrical and chemical synapses in the retina SP Kuo, GW Schwartz, F Rieke Neuron 90 (2), 320-332, 2016 | 100 | 2016 |
Unified classification of mouse retinal ganglion cells using function, morphology, and gene expression J Goetz, ZF Jessen, A Jacobi, A Mani, S Cooler, D Greer, S Kadri, J Segal, ... Cell reports 40 (2), 2022 | 99 | 2022 |
Cardinal orientation selectivity is represented by two distinct ganglion cell types in mouse retina A Nath, GW Schwartz Journal of Neuroscience 36 (11), 3208-3221, 2016 | 86 | 2016 |
Three small-receptive-field ganglion cells in the mouse retina are distinctly tuned to size, speed, and object motion J Jacoby, GW Schwartz Journal of Neuroscience 37 (3), 610-625, 2017 | 82 | 2017 |
Sophisticated temporal pattern recognition in retinal ganglion cells G Schwartz, MJ Berry 2nd Journal of neurophysiology 99 (4), 1787-1798, 2008 | 74 | 2008 |
Nonlinear spatial encoding by retinal ganglion cells: when 1+ 1≠ 2 G Schwartz, F Rieke Journal of General Physiology 138 (3), 283-290, 2011 | 70 | 2011 |
The dynamic receptive fields of retinal ganglion cells S Wienbar, GW Schwartz Progress in retinal and eye research 67, 102-117, 2018 | 69 | 2018 |
Electrical synapses convey orientation selectivity in the mouse retina A Nath, GW Schwartz Nature communications 8 (1), 2025, 2017 | 69 | 2017 |
Receptive field center-surround interactions mediate context-dependent spatial contrast encoding in the retina MH Turner, GW Schwartz, F Rieke Elife 7, e38841, 2018 | 66 | 2018 |
An amacrine cell circuit for signaling steady illumination in the retina J Jacoby, Y Zhu, SH DeVries, GW Schwartz Cell reports 13 (12), 2663-2670, 2015 | 66 | 2015 |
Circuit mechanisms of a retinal ganglion cell with stimulus-dependent response latency and activation beyond its dendrites A Mani, GW Schwartz Current Biology 27 (4), 471-482, 2017 | 60 | 2017 |
Alert response to motion onset in the retina EY Chen, O Marre, C Fisher, G Schwartz, J Levy, RA da Silveira, MJ Berry Journal of Neuroscience 33 (1), 120-132, 2013 | 59 | 2013 |
Molecular signatures of retinal ganglion cells revealed through single cell profiling LA Laboissonniere, JJ Goetz, GM Martin, R Bi, TJS Lund, L Ellson, ... Scientific reports 9 (1), 15778, 2019 | 57 | 2019 |
A self-regulating gap junction network of amacrine cells controls nitric oxide release in the retina J Jacoby, A Nath, ZF Jessen, GW Schwartz Neuron 100 (5), 1149-1162. e5, 2018 | 51 | 2018 |