UNDERSTANDING THE BRAIN THROUGH INNOVATIVE IMAGING TECHNOLOGIES
Rapidly apply insights gained from model organisms to human health
To better understand the normal brain, we are studying pathologies including stroke, psychiatric diseases, pain and epilepsy serving as models of brain circuit dysfunction. Our team seeks to accelerate the development of the breakthrough technologies to build versatile and costless tools to image brain activity and brain networks at both micro and macro-scales.
To address the challenges presented by neuroimaging, we develop a broad, interdisciplinary and translational science based on our own expertise and fruitfull collaborations with scientists, industries and citizens from all around the world.
These pages also aim at providing basic information on optogenetics, in vivo brain imaging and recording of electrical activity. Please use the top menu to navigate through the pages.
Our main research interests are summarized below:
Note that this website is under construction (some menu links are not yet available) and will be updated soon.
The best model for circuit neuroscience (marmoset) with the best modality for mesoscopic brain imaging (fUSi)? Welc… https://t.co/7K6bW9j8bn
Thanks again to Dr. David Kleinfeld for this inspiring seminar at the NERF: active sensing in behaving rodents. The… https://t.co/B7LSjvTzYi
NERF: New custom processing engine for real-time 3D functional ultrasound imaging already beating the NVIDIA DGX-1… https://t.co/yPv5M7L6sd
RT @brody_lab: A cognitive role for the superior colliculus (SC). New manuscript on flexible sensorimotor routing in the SC with recordings…
Thanks @imec_int, the world leader in micro-electronics for this amazing year of R&D and for your support. We have… https://t.co/SmlaR9TzoO
RT @ac_chenus: Visite de la salle blanche de l' #imec et du #nerf avec les étudiants de CPGE du lycée Ste Croix St Euverte ! @opto_brain_ima…
JCBFM - Functional UltraSound in a stroke model
Functional ultrasound imaging efficiently mapped the acute changes in relative cerebral blood volume during occlusion and following reperfusion with high spatial resolution (100 mm), notably documenting marked focal decreases during occlusion, and was able to chart the fine dynamics of tissue reperfusion in the individual rat.Read more →
Nature Methods - Functional UltraSound in freely moving rodents
Freely moving functional ultrasound (fm-fUS) imaging to image brain circuits in behaving rodents. fm-fUS can also efficiently decode brain activity in cortical and subcortical area during specific tasks.Read more →
NeuroImage - Functional UltraSound in chronic conditions
To overcome the limitation of the craniotomy, we developed a dedicated thinned skull surgery for chronic functional ultrasound imaging.Read more →
JMTM - Functional UltraSound in humans
Here we demonstrate how functional ultrasound can image brain capillaries in rodents and to visualize the cortical microvasculature in the human brain during neurosurgery.Read more →
Molecular Psychiatry - Interneurons Classification
In collaboration with the Allen Brain Institute, our study demonstrate that a specific class of parvalbumin expressing interneurons may be involved in brain plasticity.Read more →
A multidisciplinary team
Our team combines a set of unique expertise including neurobiology, brain imaging, physics/acoustics, computer-science, molecular biology, pharmacology and more for understanding brain function.
Open Source Technologies
We make all technologies freely available for the scientific community. As soon as results are published, we release all protocols, codes and hardware to allow everyone to use technologies from our lab.
Translational research helps turn early-stage innovations into new health products, advancing the innovation to the point where it becomes attractive for further development by the medical industry or healthcare agencies. See our last patents.
RESEARCH AND DEVELOPMENT
Our research is focused on research and development of innovative technologies to better understand neural circuits and brain physiology.
We are currently working on 2 breakthrough imaging modalities that have been designed to become a centerpiece in both preclinical and clinical studies as it can be used to diagnose metabolic diseases and lesions on a finer scale, for neurological and cognitive psychological research as well as brain-computer interfaces.
- Functional ultrasound imaging (fUSi) = Imaging of brain hemodynamic activity at mesoscopic scale in the entire depth of the brain
Structural images of brain vasculature and blood flow
Functional ultrasound (fUS) is a novel imaging modality able to measure cerebral blood volume (CBV), red blood cells velocity (RBC-V) and cerebral blood flow (CBF) that are key parameters to quantify hemodynamic variations observed during functional activation of the brain.
Brain activity in real-time during somatosensory stimuli
Alternate right/left forepaw/whiskers stimulations
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- Voltage Sensitive Dye imaging (VSDi) = Imaging of brain electrical activity locally at the surface of the brain
Optical imaging of neurons depolarizations at the ms time-scale
Cortical Spreading Depression
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Also known as potentiometric dyes, VSD are dyes which change their spectral properties in response to voltage changes. They are able to provide linear measurements of firing activity of single neurons, large neuronal populations or cardiomyocytes. Many others physiological processes are accompanied by changes in cell membrane potential which can be detected with VSD. Measurements may indicate the site of action potential origin, and measurements of action potential velocity and direction may be obtained.