Novel sensor implant radically improves significance of NMR brain scans

November 26, 2019, Nr. 105

Researchers of Max Planck Institute for Biological Cybernetics and University of Stuttgart present a new method that shows single neuron data
[Picture: whitehoune - stock.adobe.com, Max-Planck-Institut für biologische Kybernetik, Universität Stuttgart. Montage: Martin Vötsch, design-galaxie.de.]

A team of neuroscientists and electrical engineers from Germany and Switzerland developed a highly sensitive implant that enables to probe brain physiology with unparalleled spatial and temporal resolution. Now published in Nature Methods, they introduce an ultra-fine needle with an integrated chip that is capable of detecting and transmitting nuclear magnetic resonance (NMR) data from nanoliter volumes of brain oxygen metabolism. The breakthrough design will allow entirely new applications in the life sciences.

The group of researchers led by Klaus Scheffler from the Max Planck Institute for Biological Cybernetics and the University of Tübingen as well as by Jens Anders from the University of Stuttgart identified a technical bypass that bridges the electrophysical limits of contemporary brain scan methods. Their development of a capillary monolithic nuclear magnetic resonance (NMR) needle combines the versatility of brain imaging with the accuracy of a very localized and fast technique to analyze the specific neuronal activity of the brain.

“The integrated design of a nuclear magnetic resonance detector on a single chip supremely reduces the typical electromagnetic interference of magnetic resonance signals. This enables neuroscientists to gather precise data from minuscule areas of the brain and to combine them with information from spatial and temporal data of the brain´s physiology,” explains principal investigator Klaus Scheffler. “With this method, we can now better understand specific activity and functionalities in the brain.” 

 

Detailed view of the NMR needle

According to Scheffler and his group, their invention may unveil the possibility of discovering novel effects or typical fingerprints of neuronal activation, up to specific neuronal events in brain tissue.

“Our design setup will allow scalable solutions, meaning the possibility of expanding the collection of data from more than from a single area – but on the same device and the scalability of our approach will allow us to extend our platform by additional sensing modalities such as electrophysiological and optogenetic measurements,“ adds the second principal investigator Jens Anders.

The teams of Scheffler and Anders are very confident that their technical approach may help demerge the complex physiologic processes within the neural networks of the brain and that it may uncover additional benefits that can provide even deeper insights into the functionality of the brain.

With their primary goal to develop new techniques that are able to specifically probe the structural and biochemical composition of living brain tissue, their latest innovation paves the way for future highly specific and quantitative mapping techniques of neuronal activity and bioenergetic processes in the brain cells.

Text: Max Planck Institute for Biological Cybernetics

Expert Contact:

Prof. Dr. Jens Anders, University of Stuttgart, Institute of Smart Sensors Phone  +49 711 685 67250, E-Mail

Prof. Dr. Klaus Scheffler, Max Planck Institute for Biological Cybernetics, University of Tübingen, Phone +49 7071 601-701, E-Mail 

 

Original publication:

A CMOS NMR needle for probing brain physiology with high spatial and temporal resolution

Jonas Handwerker, Marlon Pérez-Rodas, Michael Beyerlein, Franck Vincent, Armin Beck, Nicolas Freytag, Xin Yu, Rolf Pohmann, Jens Anders & Klaus Scheffler, Nature Methods 2019 doi

 

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