| Electrical spinal cord stimulation must preserve proprioception to enable locomotion in humans with spinal cord injury E Formento, K Minassian, F Wagner, JB Mignardot, CG Le Goff-Mignardot, ... Nature neuroscience 21 (12), 1728-1741, 2018 | 303 | 2018 |
| Mechanisms underlying the neuromodulation of spinal circuits for correcting gait and balance deficits after spinal cord injury EM Moraud, M Capogrosso, E Formento, N Wenger, J DiGiovanna, ... Neuron 89 (4), 814-828, 2016 | 196 | 2016 |
| Shared human–robot proportional control of a dexterous myoelectric prosthesis KZ Zhuang, N Sommer, V Mendez, S Aryan, E Formento, E D’Anna, ... Nature Machine Intelligence 1 (9), 400-411, 2019 | 116 | 2019 |
| Closed-loop control of trunk posture improves locomotion through the regulation of leg proprioceptive feedback after spinal cord injury EM Moraud, J Von Zitzewitz, J Miehlbradt, S Wurth, E Formento, ... Scientific reports 8 (1), 76, 2018 | 46 | 2018 |
| A biomimetic electrical stimulation strategy to induce asynchronous stochastic neural activity E Formento, E D’Anna, S Gribi, SP Lacour, S Micera Journal of neural engineering 17 (4), 046019, 2020 | 35 | 2020 |
| Skilled independent control of individual motor units via a non-invasive neuromuscular–machine interface E Formento, P Botros, JM Carmena Journal of Neural Engineering 18 (6), 066019, 2021 | 28 | 2021 |
| Experimental and computational study on motor control and recovery after stroke: toward a constructive loop between experimental and virtual embodied neuroscience AL Allegra Mascaro, E Falotico, S Petkoski, M Pasquini, L Vannucci, ... Frontiers in systems neuroscience 14, 31, 2020 | 28 | 2020 |
| A non-invasive brain-machine interface via independent control of individual motor units E Formento, P Botros, JM Carmena bioRxiv, 2021.03. 22.436518, 2021 | 8 | 2021 |
| A sensory information compliant spinal cord stimulation system for the rehabilitation of motor functions E Formento, M Capogrosso, K Minassian, S Micera, C Gregoire EP Patent EP20160206606 20,161,223, 2016 | 2* | 2016 |
| A generic noninvasive neuromotor interface for human-computer interaction Ctrl-labs at Reality Labs, D Sussillo, P Kaifosh, T Reardon bioRxiv, 2024.02. 23.581779, 2024 | | 2024 |
| Peripheral brain-machine interface system via volitional control of individual motor units JM Carmena, E Formento, PA Botros, MM Maharbiz US Patent App. 17/691,994, 2022 | | 2022 |
| Role of Renshaw Cells in the Mammalian Locomotor Circuit: A Computational Study P Corsi, E Formento, M Capogrosso, S Micera Converging Clinical and Engineering Research on Neurorehabilitation III …, 2019 | | 2019 |
| A Computational Approach for the Design of Epidural Electrical Spinal Cord Stimulation Strategies to Enable Locomotion after Spinal Cord Injury E Formento EPFL, 2018 | | 2018 |
| Grasp smarter, not harder: Proportional control of an electromyographic prosthesis with a touch of automation K Zhuang, N Sommer, E Formento, E D'Anna, A Billard, S Micera Neuroscience 2017, Washington, USA, 2017 | | 2017 |
| Dimensions matter: Why do the spinal cords of humans and rodents respond differently to epidural electrical stimulation E Formento, M Capogrosso, K Minassian, F Wagner, JB Mignardot, ... Neuroscience 2017, Washington, USA, 2017 | | 2017 |
| A model of spinal sensorimotor circuits recruited by epidural stimulation of the spinal cord E Formento, M Capogrosso, EM Moraud, M Caban, G Courtine, S Micera Computational and Systems Neuroscience (Cosyne) 2015, 2015 | | 2015 |
| TNE F Artoni, MAG Badi-Dubois, TJR Barjavel, M Bonizzato, M Bouri, M Caban, ... | | |
Silvestro MiceraEcole Polytechnique Federale de Lausanne (EPFL), Scuola Superiore Sant'Anna (SSSA)Verified email at epfl.ch
