Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction

Russo M, Cesqui B, La Scaleia B, Ceccarelli F, Maselli A, Moscatelli A, Zago M, Lacquaniti F, d’Avella A (2017)
Journal of Neurophysiology 118(4): 2421-2434.

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Zeitschriftenaufsatz | Veröffentlicht | Englisch
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Journal of Neurophysiology
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2421-2434
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Russo M, Cesqui B, La Scaleia B, et al. Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction. Journal of Neurophysiology. 2017;118(4):2421-2434.
Russo, M., Cesqui, B., La Scaleia, B., Ceccarelli, F., Maselli, A., Moscatelli, A., Zago, M., et al. (2017). Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction. Journal of Neurophysiology, 118(4), 2421-2434. doi:10.1152/jn.00025.2017
Russo, M., Cesqui, B., La Scaleia, B., Ceccarelli, F., Maselli, A., Moscatelli, A., Zago, M., Lacquaniti, F., and d’Avella, A. (2017). Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction. Journal of Neurophysiology 118, 2421-2434.
Russo, M., et al., 2017. Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction. Journal of Neurophysiology, 118(4), p 2421-2434.
M. Russo, et al., “Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction”, Journal of Neurophysiology, vol. 118, 2017, pp. 2421-2434.
Russo, M., Cesqui, B., La Scaleia, B., Ceccarelli, F., Maselli, A., Moscatelli, A., Zago, M., Lacquaniti, F., d’Avella, A.: Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction. Journal of Neurophysiology. 118, 2421-2434 (2017).
Russo, Marta, Cesqui, Benedetta, La Scaleia, Barbara, Ceccarelli, Francesca, Maselli, Antonella, Moscatelli, Alessandro, Zago, Myrka, Lacquaniti, Francesco, and d’Avella, Andrea. “Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction”. Journal of Neurophysiology 118.4 (2017): 2421-2434.

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