| Targeted neurotechnology restores walking in humans with spinal cord injury FB Wagner, JB Mignardot, CG Le Goff-Mignardot, R Demesmaeker, ... Nature 563 (7729), 65-71, 2018 | 922 | 2018 |
| 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 | 331 | 2018 |
| Activity-dependent spinal cord neuromodulation rapidly restores trunk and leg motor functions after complete paralysis A Rowald, S Komi, R Demesmaeker, E Baaklini, SD Hernandez-Charpak, ... Nature medicine 28 (2), 260-271, 2022 | 285 | 2022 |
| The neurons that restore walking after paralysis C Kathe, MA Skinnider, TH Hutson, N Regazzi, M Gautier, ... Nature 611 (7936), 540-547, 2022 | 141 | 2022 |
| Neuroprosthetic baroreflex controls haemodynamics after spinal cord injury JW Squair, M Gautier, L Mahe, JE Soriano, A Rowald, A Bichat, N Cho, ... Nature 590 (7845), 308-314, 2021 | 123 | 2021 |
| Soft, implantable bioelectronic interfaces for translational research G Schiavone, F Fallegger, X Kang, B Barra, N Vachicouras, E Roussinova, ... Advanced Materials 32 (17), 1906512, 2020 | 100 | 2020 |
| Wireless closed-loop optogenetics across the entire dorsoventral spinal cord in mice C Kathe, F Michoud, P Schönle, A Rowald, N Brun, J Ravier, I Furfaro, ... Nature biotechnology 40 (2), 198-208, 2022 | 88 | 2022 |
| Efficient homogeneous illumination and optical sectioning for quantitative single-molecule localization microscopy J Deschamps, A Rowald, J Ries Optics express 24 (24), 28080-28090, 2016 | 76 | 2016 |
| The coming decade of digital brain research-A vision for neuroscience at the intersection of technology and computing K Amunts, A Rowald, S Petkoski, MV Sanchez-Vives, M Axer, G De Bonis, ... Computational and Systems Neuroscience, 2022 | 19 | 2022 |
| A computational roadmap to electronic drugs A Rowald, O Amft Frontiers in Neurorobotics 16, 983072, 2022 | 6 | 2022 |
| Bioelectronic Interfaces: Soft, Implantable Bioelectronic Interfaces for Translational Research (Adv. Mater. 17/2020) G Schiavone, F Fallegger, X Kang, B Barra, N Vachicouras, E Roussinova, ... Advanced Materials 32 (17), 2070133, 2020 | 5 | 2020 |
| Large field-of-view high resolution 3D imaging of the thoracolumbar nerve roots inside the spinal canal S Mandija, M Froeling, A van der Kolk, F Visser, A Rowald, ... ISMRM 2019 Abstracts. p 2883, 2019 | 2 | 2019 |
| The implantable system that restores hemodynamic stability after spinal cord injury AA Phillips, AP Gandhi, N Hankov, SD Hernandez-Charpak, J Rimok, ... medRxiv, 2024.05. 10.24306826, 2024 | 1 | 2024 |
| Devices and systems for electrical stimulation and methods of use D Ganty, E Paoles, J Bloch, G Courtine, L Asboth, R Demesmaeker, ... US Patent 11,911,621, 2024 | 1 | 2024 |
| Fundamental limitations of kilohertz-frequency carriers in afferent fiber recruitment with transcutaneous spinal cord stimulation I Seáñez, R Keesey, U Hofstoetter, Z Hu, L Lombardi, R Hawthorn, ... | | 2024 |
| Fundamental limitations of kilohertz-frequency carriers in afferent fiber recruitment with transcutaneous spinal cord stimulation R Keesey, U Hofstoetter, Z Hu, L Lombardi, R Hawthorn, NK Bryson, ... bioRxiv, 2024.07. 26.603982, 2024 | | 2024 |
| Recent progress in the field of Artificial Organs A Rowald, S Komi, R Demesmaeker, E Baaklini, SD Hernandez-Charpak, ... Artificial Organs 46, 541-542, 2022 | | 2022 |
| Personalizable computational models of electrical spinal cord stimulation to restore function after neurological disorders A Rowald EPFL, 2021 | | 2021 |
| Computational models steering the personalization of targeted spinal cord stimulation to restore motor function in humans with spinal cord injury A Rowald, E Neufeld, E Paoles, S Mandija, H Montanaro, A Alaia, ... Neuroscience 2018 Abstracts, 491-492, 2018 | | 2018 |
