Papers

1. Nudo, R. J. Recovery after brain injury: mechanisms and principles. Front. Hum. Neurosci. 7, 887 (2013).
2. Jones, T. A. et al. Motor System Plasticity in Stroke Models: Intrinsically Use-dependent, Unreliably Useful. Stroke 44, S104–S106 (2013).
3. Lemon, R. N. Descending pathways in motor control. Annu. Rev. Neurosci. 31, 195–218 (2008).
4. Rowe, Justin B., et al. "Robotic assistance for training finger movement using a Hebbian model: a randomized controlled trial." Neurorehabilitation and neural repair 31.8 (2017): 769-780.
5. Lo, Albert C., et al. "Robot-assisted therapy for long-term upper-limb impairment after stroke." New England Journal of Medicine 362.19 (2010): 1772-1783.
6. Beckers, N., & Marchal-Crespo, L. (2022). The Role of Haptic Interactions with Robots for Promoting Motor Learning. In *Neurorehabilitation Technology* (pp. 247–261).
7. Williams, Camille K., and Heather Carnahan. "Motor learning perspectives on haptic training for the upper extremities." IEEE Transactions on Haptics 7.2 (2014): 240-250.
8. Spampinato, Danny, and Pablo Celnik. "Multiple motor learning processes in humans: defining their neurophysiological bases." The Neuroscientist 27.3 (2021): 246-267.
9. Mazzoni, Pietro, Britne Shabbott, and Juan Camilo Cortés. "Motor control abnormalities in Parkinson’s disease." Cold Spring Harbor perspectives in medicine 2.6 (2012).

Books

1. Broken Movement by John Krakauer and Thomas Carmichaeil