武井 智彦未来を予測して身体運動の時間遅れを克服する神経メカニズムCLINICAL NEUROSCIENCE 41(8) p.1036-1039 2023 Link 

Yamaguchi R, Ueno S, Kawasaki T, Chao ZC, Mitsuhashi M, Isa K, Takei T, Kobayashi K, Takahashi J, Onoe H, Isa T (2023) Global disinhibition and corticospinal plasticity for drastic recovery after spinal cord injury. bioRxiv, doi:

Song Y, Hirashima M, Takei T* (2022) Neural Network Models for Spinal Implementation of Muscle Synergies. Frontiers Syst Neurosci 16:800628. 

井澤 淳, 武井 智彦「確率論的最適フィードバック制御の脳内機構」計測と制御 61(4) p.309-315 2022年 Link 

Saito T, Ogihara N, Takei T, Seki K (2021) Musculoskeletal Modeling and Inverse Dynamic Analysis of Precision Grip in the Japanese Macaque. Frontiers Syst Neurosci 15:774596.

Eberle H, Hayashi Y*, Kurazume R, Takei T*, An Qi* (2021) Modeling of hyper-adaptability: from motor coordination to rehabilitation. Adv Robotics:1–16.

Takei T*, Lomber SG, Cook DJ, Scott SH (2021) Transient deactivation of dorsal premotor cortex or parietal area 5 impairs feedback control of the limb in macaques. Curr Biol:1–18. #Featured as a "DISPATCHES" in Current Biology

武井智彦「動作の遅れを克服する予測のしくみ」体育の科学 71(7) 2021年 Link

Yaron A, Kowalski D, Yaguchi H, Takei T, Seki K (2020) Forelimb force direction and magnitude independently controlled by spinal modules in the macaque. Proc Natl Acad Sci USA 117:27655–27666.

Oya T#, Takei T#, Seki K (2020) Distinct sensorimotor feedback loops for dynamic and static control of primate precision grip. Communications Biology 3:156–13. (# TO and TT equally contributed)

Heming EA, Cross KP, Takei T, Cook DJ, Scott SH (2019) Independent representations of ipsilateral and contralateral limbs in primary motor cortex. eLife 8.

Cross KP, Cluff T, Takei T, Scott SH (2019) Visual Feedback Processing of the Limb Involves Two Distinct Phases. J Neurosci 39, 6751–6765.

Takei T, Crevecoeur F, Herter TM, Cross KP, Scott SH (2018) Correlations Between Primary Motor Cortex Activity with Recent Past and Future Limb Motion During Unperturbed Reaching. J Neurosci 38, 7787–7799.

Takei T*, Confais J, Tomatsu S, Oya T, Seki K (2017) Neural basis for hand muscle synergies in the primate spinal cord. Proc Natl Acad Sci USA 114, 8643–8648.

Confais J, Kim G, Tomatsu S, Takei T, Seki K (2017) Nerve-Specific Input Modulation to Spinal Neurons during a Motor Task in the Monkey. J Neurosci 37, 2612–2626.

Yamada H, Yaguchi H, Tomatsu S, Takei T, Oya T, Seki K (2016) Representation of Afferent Signals from Forearm Muscle and Cutaneous Nerves in the Primary Somatosensory Cortex of the Macaque Monkey. PLoS ONE 11, e0163948.

Scott SH, Cluff T, Lowrey CR, Takei T (2015) Feedback control during voluntary motor actions. Curr Opin Neurobiol 33, 85–94.

Furusawa Y, Hanakawa T, Mukai Y, Aihara Y, Taminato T, Iawata Y, Takei T, Sakamoto T, Murata M (2015) Mechanism of camptocormia in Parkinson's disease analyzed by tilt table-EMG recording. Parkinsonism Relat Disord 21, 765–770.

Yaguchi H, Takei T, Kowalski D, Suzuki T, Mabuchi K, Seki K (2015) Modulation of spinal motor output by initial arm postures in anesthetized monkeys. J Neurosci 35, 6937–6945.

Herter TM, Takei T, Munoz DP, Scott SH (2015) Neurons in red nucleus and primary motor cortex exhibit similar responses to mechanical perturbations applied to the upper-limb during posture. Front Integr Neurosci 9, 29.

Takei T, Seki K (2013a) Spinal premotor interneurons mediate dynamic and static motor commands for precision grip in monkeys. J Neurosci 33, 8850–8860.

Takei T*, Seki K (2013b) Synaptic and functional linkages between spinal premotor interneurons and hand-muscle activity during precision grip. Front Comput Neurosci 7, 40.

Takei T, Seki K (2010) Spinal interneurons facilitate coactivation of hand muscles during a precision grip task in monkeys. J Neurosci 30, 17041–17050. #Selected as a "Recommended Article" in Faculty 1000

Takei T, Seki K (2008) Spinomuscular coherence in monkeys performing a precision grip task. J Neurophysiol 99, 2012–2020.

Hagura N, Takei T, Hirose S, Aramaki Y, Matsumura M, Sadato N, Naito E (2007) Activity in the posterior parietal cortex mediates visual dominance over kinesthesia. J Neurosci 27, 7047–7053.

Takei T, Hashimoto T, Hagura N, Matsumura M, Naito E (2005) Reduction of cortico-spinal excitability by transcranial magnetic stimulation at predictable timing. Jpn J Physiol 55, 93–99.

(* corresponding author)


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自由自在な動きをつくりだす多機能な神経細胞群の発見 ~運動の方向と大きさを同時にコントロールする神経メカニズムの解明~(2020年1013日)Link

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運動生理学シリーズ7 運動と高次神経機能―運動の脳内機能を探検する―杏林書院 2005年 ISBN: 978-4-7644-1073-2

「脳百話―動きの仕組みを解き明かす」市村出版 2003年 ISBN: 978-4902109023


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