Grégoire Courtine
Full Professor
gregoire.courtine@epfl.ch +41 21 693 83 43 http://courtine-lab.epfl.ch
Citizenship: French
EPFL SV BMI UPCOURTINE
B3 3 186.134 (Campus Biotech bâtiment B3)
Ch. des Mines 9
1202 Genève
+41 21 693 83 43
Office:
B3 3 186.134
EPFL
>
SV
>
INX-SV
>
UPCOURTINE
Web site: Web site: https://courtine-lab.epfl.ch
EPFL Comité Campus Genève
Campus Biotech B1
Chemin des Mines 9
1202 Genève
+41 21 693 83 43
EPFL
>
STI
>
INX-STI
>
INX-STI-GE
+41 21 693 83 43
EPFL
>
STI
>
STI-DEC
>
STI-DIR
Biography
Grégoire Courtine was originally trained in Mathematics and Physics, but received his PhD degree in Experimental Medicine from the University of Pavia, Italy, and the INSERM Plasticity and Motricity, in France, in 2003. From 2004-2007, he held a Post-doctoral Fellow position at the Brain Research Institute, University of California at Los Angeles (UCLA) under the supervision of Dr. Reggie Edgerton, and was a research associate for the Christopher and Dana Reeve Foundation (CDRF). In 2008, he became Assistant Professor at the faculty of Medicine of the University of Zurich where he established his own research laboratory. In 2012, he was nominated Associate Professor at the Swiss Federal Institute of Technology Lausanne (EPFL) where he holds the International paraplegic foundation (IRP) chair in spinal cord repair at the Center for Neuroprosthetics and the Brain Mind Institute. He published several articles proposing radically new approaches for restoring function after spinal cord injury, which were discussed in national and international press extensively. He received numerous honors and awards such as the 2007 UCLA Chancellors award for excellence in post-doctoral research and the 2009 Schellenberg Prize for his innovative research in spinal cord injury awarded by the International Foundation of Research in Paraplegia.Research
Mission
Our mission is to design innovative interventions to restore sensorimotor functions after CNS disorders, especially spinal cord injury, and to translate our findings into effective clinical applications capable of improving the quality of life of people with neuromotor impairments.To achieve this goal
We are developing multifaceted neuroprosthetic systems, robotic interfaces, and advanced neurorehabilitation procedures that we combine with neuroregenerative interventions. Using genetically modified mice, optogenetics, and novel viral tools, we also seek to uncover the neural mechanisms underlying the control of locomotion in intact animals, as well as the processes that reestablish motor functions after neuromotor disordersTeaching & PhD
Teaching
Life Sciences Engineering