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Better understanding communication between neurons in the brain

Researchers at the University of Freiburg develop a new method for controlled interrogation and recording of neuronal activity

Better understanding communication between neurons in the brain

Scheme of the new Fused Fiber Light Emission and eXtracellular Recording (FFLEXR). Photo: Research group Ilka Diester

In the field of optogenetics, scientists investigate the activity of neurons in the brain using light. A team led by Prof. Dr. Ilka Diester and Dr. David Eriksson from the Optophysiology Laboratory at the University of Freiburg has developed a new method to simultaneously conduct laminar recordings, multifiber stimulations, 3D optogenetic stimulation, connectivity inference, and behavioral quantification on brains. Their results are presented in Nature Communications. "Our work paves the way for large-scale photo-recording and controlled interrogation of fast neural communication in any combination of brain areas," Diester explains. "This can help us unravel the rapid and multilayered dialogues between neurons that maintain brain function."

The research group, in collaboration with Dr. Patrick Ruther of the Department of Microsystems Engineering (IMTEK) at the University of Freiburg, is developing a new method for the controlled interrogation and recording of neuronal activity in the brain. To do this, the team is taking advantage of thin, cell-sized optical fibers for minimally invasive optogenetic implantation. "We combine side-emitting fibers with silicon probes to achieve high-quality recordings and ultrafast, multichannel optogenetic control." They call the system Fused Fiber Light Emission and eXtracellular Recording, or FFLEXR. In addition to optical fibers that can be attached to any silicon probe, the team uses linear depth-resolved stimulation, a lightweight fiber matrix connector, a flexible multifiber ribbon cable, an optical commutator for efficient multichannel stimulation, a general-purpose patch cable, and an algorithm to manage the photovoltaic response. "Our alternative approach maintains the flexibility to apply any desired wavelength via an external interchangeable light source and enable optogenetic stimulation at different depths of brain tissue," Diester says.

Ilka Diester heads a research group at the Institute of Biology III and research center IMBIT/BrainLinks-BrainTools at the University of Freiburg that uses optophysiology, i.e. novel optical tools, to investigate the functioning of neuronal circuits. The scientists are investigating the neuronal basis of motor and cognitive control as well as interactions between the prefrontal and motor cortex, both of which are part of the cerebral cortex.

Video on Ilka Diester's research on neuronal motion signals: "Making thinking visible"

 

Original publication:
Eriksson, D., Schneider, A., Thirumalai, A., Alyahyay, M., de la Crompe, B., Sharma, K., Ruther, P., Diester, I. (2022): Multichannel optogenetics combined with laminar recordings for ultra-controlled neuronal interrogation. In: Nature Communications. DOI: 10.1038/s41467-022-28629-6

 

Pressphoto for Download
Photo: Research group Ilka Diester

 

Contact:
Prof. Dr. Ilka Diester
Institute of Biology III
University of Freiburg
Phone: +49(0)761/203-8440
E-Mail: 

Franziska Becker
Office of University and Science Communications
University of Freiburg
Phone: +49(0)761/203-54271
E-Mail: 

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