A detailed predictive model of the mammalian circadian clock DB Forger, CS Peskin Proceedings of the National Academy of Sciences 100 (25), 14806-14811, 2003 | 440 | 2003 |
A global quantification of “normal” sleep schedules using smartphone data OJ Walch, A Cochran, DB Forger Science advances 2 (5), e1501705, 2016 | 275 | 2016 |
A mechanism for robust circadian timekeeping via stoichiometric balance JK Kim, DB Forger Molecular systems biology 8 (1), 630, 2012 | 260 | 2012 |
Quantifying human circadian pacemaker response to brief, extended, and repeated light stimuli over the phototopic range RE Kronauer, DB Forger, ME Jewett Journal of biological rhythms 14 (6), 501-516, 1999 | 251 | 1999 |
Emergence of noise-induced oscillations in the central circadian pacemaker CH Ko, YR Yamada, DK Welsh, ED Buhr, AC Liu, EE Zhang, MR Ralph, ... PLoS biology 8 (10), e1000513, 2010 | 248 | 2010 |
Guidelines for genome-scale analysis of biological rhythms ME Hughes, KC Abruzzi, R Allada, R Anafi, AB Arpat, G Asher, P Baldi, ... Journal of biological rhythms 32 (5), 380-393, 2017 | 246 | 2017 |
Sleep stage prediction with raw acceleration and photoplethysmography heart rate data derived from a consumer wearable device O Walch, Y Huang, D Forger, C Goldstein Sleep 42 (12), zsz180, 2019 | 231 | 2019 |
Daily electrical silencing in the mammalian circadian clock MDC Belle, CO Diekman, DB Forger, HD Piggins Science 326 (5950), 281-284, 2009 | 216 | 2009 |
An opposite role for tau in circadian rhythms revealed by mathematical modeling M Gallego, EJ Eide, MF Woolf, DM Virshup, DB Forger Proceedings of the National Academy of Sciences 103 (28), 10618-10623, 2006 | 208 | 2006 |
Stochastic simulation of the mammalian circadian clock DB Forger, CS Peskin Proceedings of the National Academy of Sciences 102 (2), 321-324, 2005 | 204 | 2005 |
GABA-mediated repulsive coupling between circadian clock neurons in the SCN encodes seasonal time J Myung, S Hong, D DeWoskin, E De Schutter, DB Forger, T Takumi Proceedings of the National Academy of Sciences 112 (29), E3920-E3929, 2015 | 189 | 2015 |
Revised limit cycle oscillator model of human circadian pacemaker ME Jewett, DB Forger, RE Kronauer Journal of biological rhythms 14 (6), 493-500, 1999 | 188 | 1999 |
Wearable technologies for developing sleep and circadian biomarkers: a summary of workshop discussions CM Depner, PC Cheng, JK Devine, S Khosla, M De Zambotti, R Robillard, ... sleep 43 (2), zsz254, 2020 | 185 | 2020 |
A Period2 phosphoswitch regulates and temperature compensates circadian period M Zhou, JK Kim, GWL Eng, DB Forger, DM Virshup Molecular cell 60 (1), 77-88, 2015 | 184 | 2015 |
A simpler model of the human circadian pacemaker DB Forger, ME Jewett, RE Kronauer Journal of biological rhythms 14 (6), 533-538, 1999 | 180 | 1999 |
Distinct roles for GABA across multiple timescales in mammalian circadian timekeeping D DeWoskin, J Myung, MDC Belle, HD Piggins, T Takumi, DB Forger Proceedings of the National Academy of Sciences 112 (29), E3911-E3919, 2015 | 168 | 2015 |
A novel protein, CHRONO, functions as a core component of the mammalian circadian clock A Goriki, F Hatanaka, J Myung, JK Kim, T Yoritaka, S Tanoue, T Abe, ... PLoS biology 12 (4), e1001839, 2014 | 159 | 2014 |
CK1δ/ε protein kinase primes the PER2 circadian phosphoswitch R Narasimamurthy, SR Hunt, Y Lu, JM Fustin, H Okamura, CL Partch, ... Proceedings of the National Academy of Sciences 115 (23), 5986-5991, 2018 | 152 | 2018 |
Noisy inputs and the induction of on–off switching behavior in a neuronal pacemaker D Paydarfar, DB Forger, JR Clay Journal of neurophysiology 96 (6), 3338-3348, 2006 | 126 | 2006 |
Reversible protein phosphorylation regulates circadian rhythms DM Virshup, EJ Eide, DB Forger, M Gallego, EV Harnish Cold Spring Harbor symposia on quantitative biology 72, 413-420, 2007 | 121 | 2007 |