| Dynamics and control at feedback vertex sets. II: A faithful monitor to determine the diversity of molecular activities in regulatory networks A Mochizuki, B Fiedler, G Kurosawa, D Saito Journal of theoretical biology 335, 130-146, 2013 | 181 | 2013 |
| Dynamics and control at feedback vertex sets. I: Informative and determining nodes in regulatory networks B Fiedler, A Mochizuki, G Kurosawa, D Saito Journal of Dynamics and Differential Equations 25, 563-604, 2013 | 158 | 2013 |
| Two Ck1δ transcripts regulated by m6A methylation code for two antagonistic kinases in the control of the circadian clock JM Fustin, R Kojima, K Itoh, HY Chang, S Ye, B Zhuang, A Oji, S Gibo, ... Proceedings of the National Academy of Sciences 115 (23), 5980-5985, 2018 | 100 | 2018 |
| Comparative study of circadian clock models, in search of processes promoting oscillation G Kurosawa, A Mochizuki, Y Iwasa Journal of theoretical biology 216 (2), 193-208, 2002 | 83 | 2002 |
| Temperature compensation in circadian clock models G Kurosawa, Y Iwasa Journal of theoretical biology 233 (4), 453-468, 2005 | 76 | 2005 |
| A model for the circadian rhythm of cyanobacteria that maintains oscillation without gene expression G Kurosawa, K Aihara, Y Iwasa Biophysical journal 91 (6), 2015-2023, 2006 | 75 | 2006 |
| Circadian regulation of food-anticipatory activity in molecular clock–deficient mice NN Takasu, G Kurosawa, IT Tokuda, A Mochizuki, T Todo, W Nakamura PLoS One 7 (11), e48892, 2012 | 58 | 2012 |
| Saturation of enzyme kinetics in circadian clock models G Kurosawa, Y Iwasa Journal of biological rhythms 17 (6), 568-577, 2002 | 56 | 2002 |
| Amplitude of circadian oscillations entrained by 24-h light–dark cycles G Kurosawa, A Goldbeter Journal of theoretical biology 242 (2), 478-488, 2006 | 53 | 2006 |
| A temperature-compensated model for circadian rhythms that can be entrained by temperature cycles T Takeuchi, T Hinohara, G Kurosawa, K Uchida Journal of theoretical biology 246 (1), 195-204, 2007 | 32 | 2007 |
| Temperature–amplitude coupling for stable biological rhythms at different temperatures G Kurosawa, A Fujioka, S Koinuma, A Mochizuki, Y Shigeyoshi PLoS computational biology 13 (6), e1005501, 2017 | 29 | 2017 |
| Na+/Ca2+ exchanger mediates cold Ca2+ signaling conserved for temperature-compensated circadian rhythms N Kon, H Wang, YS Kato, K Uemoto, N Kawamoto, K Kawasaki, R Enoki, ... Science Advances 7 (18), eabe8132, 2021 | 23 | 2021 |
| Time-lapse imaging of microRNA activity reveals the kinetics of microRNA activation in single living cells H Ando, M Hirose, G Kurosawa, S Impey, K Mikoshiba Scientific Reports 7 (1), 12642, 2017 | 21 | 2017 |
| Modeling light adaptation in circadian clock: Prediction of the response that stabilizes entrainment K Tsumoto, G Kurosawa, T Yoshinaga, K Aihara PLoS One 6 (6), e20880, 2011 | 19 | 2011 |
| Positive Autoregulation Delays the Expression Phase of Mammalian Clock Gene Per2 Y Ogawa, N Koike, G Kurosawa, T Soga, M Tomita, H Tei PLoS One 6 (4), e18663, 2011 | 19 | 2011 |
| Theoretical study on the regulation of circadian rhythms by RNA methylation S Gibo, G Kurosawa Journal of Theoretical Biology 490, 110140, 2020 | 5 | 2020 |
| Non-sinusoidal waveform in temperature-compensated circadian oscillations S Gibo, G Kurosawa Biophysical Journal 116 (4), 741-751, 2019 | 5 | 2019 |
| Frequency modulated timer regulates mammalian hibernation S Gibo, Y Yamaguchi, G Kurosawa bioRxiv, 2021.11. 12.468369, 2021 | 2 | 2021 |
| Frequency-modulated timer regulates torpor–arousal cycles during hibernation in distinct small mammalian hibernators S Gibo, Y Yamaguchi, EO Gracheva, SN Bagriantsev, IT Tokuda, ... npj Biological Timing and Sleep 1 (1), 3, 2024 | | 2024 |
| Effects of intrinsic noise in temperature-compensated models for circadian rhythms S Ichikawa, Y Ito, G Kurosawa, K Uchida 2009 ICCAS-SICE, 200-205, 2009 | | 2009 |
