Jose Carmena
Jose Carmena
Professor of Electrical Engineering and Neuroscience, University of California, Berkeley
Verified email at - Homepage
Cited by
Cited by
Learning to control a brain–machine interface for reaching and grasping by primates
JM Carmena, MA Lebedev, RE Crist, JE O'Doherty, DM Santucci, ...
PLoS biology 1 (2), e42, 2003
Wearable robots: biomechatronic exoskeletons
JL Pons
John Wiley & Sons, 2008
Chronic, multisite, multielectrode recordings in macaque monkeys
MAL Nicolelis, D Dimitrov, JM Carmena, R Crist, G Lehew, JD Kralik, ...
Proceedings of the National Academy of Sciences 100 (19), 11041-11046, 2003
Emergence of a stable cortical map for neuroprosthetic control
K Ganguly, JM Carmena
PLoS biology 7 (7), e1000153, 2009
Wireless recording in the peripheral nervous system with ultrasonic neural dust
D Seo, RM Neely, K Shen, U Singhal, E Alon, JM Rabaey, JM Carmena, ...
Neuron 91 (3), 529-539, 2016
Four ethical priorities for neurotechnologies and AI
R Yuste, S Goering, BA Arcas, G Bi, JM Carmena, A Carter, JJ Fins, ...
Nature 551 (7679), 159-163, 2017
Corticostriatal plasticity is necessary for learning intentional neuroprosthetic skills
AC Koralek, X Jin, JD Long II, RM Costa, JM Carmena
Nature 483 (7389), 331-335, 2012
Cortical ensemble adaptation to represent velocity of an artificial actuator controlled by a brain-machine interface
MA Lebedev, JM Carmena, JE O'Doherty, M Zacksenhouse, ...
Journal of Neuroscience 25 (19), 4681-4693, 2005
A minimally invasive 64-channel wireless μECoG implant
R Muller, HP Le, W Li, P Ledochowitsch, S Gambini, T Bjorninen, ...
IEEE Journal of Solid-State Circuits 50 (1), 344-359, 2014
Oscillatory phase coupling coordinates anatomically dispersed functional cell assemblies
RT Canolty, K Ganguly, SW Kennerley, CF Cadieu, K Koepsell, JD Wallis, ...
Proceedings of the National Academy of Sciences 107 (40), 17356-17361, 2010
In vitro and in vivo evaluation of PEDOT microelectrodes for neural stimulation and recording
S Venkatraman, J Hendricks, ZA King, AJ Sereno, S Richardson-Burns, ...
IEEE Transactions on Neural Systems and Rehabilitation Engineering 19 (3…, 2011
A wireless millimetre-scale implantable neural stimulator with ultrasonically powered bidirectional communication
DK Piech, BC Johnson, K Shen, MM Ghanbari, KY Li, RM Neely, JE Kay, ...
Nature biomedical engineering 4 (2), 207-222, 2020
Microstimulation activates a handful of muscle synergies
SA Overduin, A d’Avella, JM Carmena, E Bizzi
Neuron 76 (6), 1071-1077, 2012
Physical principles for scalable neural recording
AH Marblestone, BM Zamft, YG Maguire, MG Shapiro, TR Cybulski, ...
Frontiers in computational neuroscience 7, 137, 2013
Reversible large-scale modification of cortical networks during neuroprosthetic control
K Ganguly, DF Dimitrov, JD Wallis, JM Carmena
Nature neuroscience 14 (5), 662-667, 2011
Closed-loop decoder adaptation shapes neural plasticity for skillful neuroprosthetic control
AL Orsborn, HG Moorman, SA Overduin, MM Shanechi, DF Dimitrov, ...
Neuron 82 (6), 1380-1393, 2014
Neural dust: An ultrasonic, low power solution for chronic brain-machine interfaces
D Seo, JM Carmena, JM Rabaey, E Alon, MM Maharbiz
arXiv preprint arXiv:1307.2196, 2013
A Fully-Integrated, Miniaturized (0.125 mm) 10.5 W Wireless Neural Sensor
W Biederman, DJ Yeager, N Narevsky, AC Koralek, JM Carmena, E Alon, ...
IEEE Journal of Solid-State Circuits 48 (4), 960-970, 2013
Model validation of untethered, ultrasonic neural dust motes for cortical recording
D Seo, JM Carmena, JM Rabaey, MM Maharbiz, E Alon
Journal of neuroscience methods 244, 114-122, 2015
A wireless and artefact-free 128-channel neuromodulation device for closed-loop stimulation and recording in non-human primates
A Zhou, SR Santacruz, BC Johnson, G Alexandrov, A Moin, FL Burghardt, ...
Nature biomedical engineering 3 (1), 15-26, 2019
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