All Publications
Listed reverse chronologically
Enhanced Aversive Signals During Classical Conditioning in Dopamine Axons in Medial Prefrontal Cortex
Abe K, Kambe Y, Majima K, Hu Z, Ohtake M, Momennezhad A, Izumi H, Tanaka T, Matunis A, Stacy E, Itokazu T, Sato TR, Sato TK. Enhanced Aversive Signals During Classical Conditioning in Dopamine Axons in Medial Prefrontal Cortex. bioRxiv. 2023 Aug 24;. doi: 10.1101/2023.08.23.554475
Activity of GABA neurons in the zona incerta and ventral lateral periaqueductal grey is biased towards sleep
Blanco-Centurion C, Vidal-Ortiz A, Sato T, Shiromani PJ. Activity of GABA neurons in the zona incerta and ventral lateral periaqueductal grey is biased towards sleep. Sleep. 2023 Mar 9;46(3). doi: 10.1093/sleep/zsac306.
A Canonical Scheme of Bottom-Up and Top-Down Information Flows in the Frontoparietal Network
Hwang EJ, Sato TR, Sato TK. (2021) A Canonical Scheme of Bottom-Up and Top-Down Information Flows in the Frontoparietal Network. Front Neural Circuits. 15:691314. doi: 10.3389/fncir.2021.691314.
Interhemispherically dynamic representation of an eye movement-related activity in mouse frontal cortex
Sato TR*, Itokazu T, Osaki H, Ohtake M, Yamamoto T, Sohya K, Maki T, Sato TK*. (2019) Interhemispherically dynamic representation of an eye movement-related activity in mouse frontal cortex. Elife 8, doi:10.7554/eLife.50855.
Streamlined sensory motor communication through cortical reciprocal connectivity in a visually guided eye movement task
Itokazu T, Hasegawa M, Kimura R, Osaki H, Albrecht UR, Sohya K, Chakrabarti S, Itoh H, Ito T, Sato TK*, Sato TR*. (2018) Streamlined sensory motor communication through cortical reciprocal connectivity in a visually guided eye movement task. Nature Communications 9(1):338.
Selective suppression of local circuits during movement preparation in mouse motor cortex
Hasegawa M, Majima K, Itokazu T, Maki T, Albrecht UR, Castner N, Izumo M, Sohya K, Sato TK, Kamitani Y, Sato TR*. (2017) Selective suppression of local circuits during movement preparation in mouse motor cortex. Cell Rep. 18(11): 2676-2686.
Sleep stage-specific regulation of cortical excitation and inhibition
Niethard N, Hasegawa M, Itokazu T, Oyanedel CN, Born J*, Sato TR*(2016) Sleep stage-specific regulation of cortical excitation and inhibition. Curr Biol. 26 (20):2739-49.
Differential effects of light and feeding on circadian organization of peripheral clocks in a forebrain Bmal1 mutant
Izumo M, Pejchal M, Schook AC, Lange RP, Walisser JA, Sato TR, Wang X, Bradfield CA, Takahashi JS. (2014). Differential effects of light and feeding on circadian organization of peripheral clocks in a forebrain Bmal1 mutant. Elife. 04167.
Characterization and adaptive optical correction of aberrations during in vivo imaging in the mouse cortex
Ji N, Sato TR, Betzig E. (2012). Characterization and adaptive optical correction of aberrations during in vivo imaging in the mouse cortex. Proc Natl Acad Sci U S A. 109(1):22-7.
The functional properties of barrel cortex neurons projecting to the primary motor cortex
Sato TR*, Svoboda K. (2010). The functional properties of barrel cortex neurons projecting to the primary motor cortex. Journal of Neuroscience 30(12): 4256-60
Learning-Related Fine-Scale Specificity Imaged in Motor Cortex Circuits of Behaving Mice
Komiyama K, Sato TR, O’Connor DH, Huber D, Hooks BM, Gabitto M, Svoboda K. (2010). Learning-Related Fine-Scale Specificity Imaged in Motor Cortex Circuits of Behaving Mice. Nature 464(7292): 1182-6
Subcellular dynamics of type II PKA in neurons
Zhong H, Sia GM, Sato TR, Gray NW, Mao T, Khuchua Z, Huganir RL, Svoboda K. (2009). Subcellular dynamics of type II PKA in neurons. Neuron 62(3): 363-74.
The functional microstructure of the mouse barrel cortex
Sato TR*, Gray NW, Mainen ZF, Svoboda K. (2007). The functional microstructure of the mouse barrel cortex. PLoS Biology 5(7):e189.
Quantitative analyses of circadian gene expression in mammalian cell cultures
Izumo M, Sato TR, Straume M, Johnson CH. (2006). Quantitative analyses of circadian gene expression in mammalian cell cultures. PLoS Computational Biology 2(10): e136.
Neuronal basis of covert spatial attention in the frontal eye field
Thompson KG, Bisco KL, Sato TR. (2005). Neuronal basis of covert spatial attention in the frontal eye field. Journal of Neuroscience 25(41): 9479-87.
Frontal eye field activity before visual search errors reveals the integration of bottom-up and top-down salience
Thompson KG, Bichot NP, Sato TR. (2005). Frontal eye field activity before visual search errors reveals the integration of bottom-up and top-down salience. Journal of Neurophysiology 93(1):337-51.
Effects of search efficiency on surround suppression during visual selection in frontal eye field
Schall JD, Sato TR, Thompson KG, Vaughn AA, Juan CH. (2004). Effects of search efficiency on surround suppression during visual selection in frontal eye field. Journal of Neurophysiology 91(6):2765-9.
Effect of target-distractor similarity on FEF visual selection in the absence of the target
Sato TR, Watanabe K, Thompson KG, Schall JD. (2003). Effect of target-distractor similarity on FEF visual selection in the absence of the target. Experimental Brain Research 151(3):356-63.
Effects of stimulus-response compatibility on neural selection in frontal eye field
Sato TR, Schall JD. (2003). Effects of stimulus-response compatibility on neural selection in frontal eye field. Neuron 38(4):637-48.
Perceived shifts of flashed stimuli by visible and invisible object motion
Watanabe K, Sato TR, Shimojo S. (2003). Perceived shifts of flashed stimuli by visible and invisible object motion. Perception 32(5):545-9.
Divergent movement of adjacent whiskers
Sachdev RN, Sato T, Ebner FF. (2002). Divergent movement of adjacent whiskers. Journal of Neurophysiology 87(3):1440-8.
Pre-excitatory pause in frontal eye field responses
Sato T, Schall JD. (2001). Pre-excitatory pause in frontal eye field responses. Experimental Brain Research 139(1):53-8.
Search efficiency but not response interference affects visual selection in frontal eye field
Sato T, Murthy A, Thompson KG, Schall JD. (2001). Search efficiency but not response interference affects visual selection in frontal eye field. Neuron 30(2):583-91.
Temporal and spatial dissociation of expression patterns between Zif268 and c-Fos in rat inferior olive during vestibular compensation
Sato T, Tokuyama W, Miyashita Y, Okuno H. (1997). Temporal and spatial dissociation of expression patterns between Zif268 and c-Fos in rat inferior olive during vestibular compensation. Neuroreport 8(8):1891-5.