University of Freiburg’s Early Career Research Group Secures Carl Zeiss Foundation Support for Biohybrid Neuroimplants

Controlling prostheses with thoughts or making letters appear on a screen: neuroimplants are brain-computer interfaces – the tiny electrodes can read brain activity and thus help people with paralysis and neurological disorders, for example. Dr Simon Binder studied electrical engineering and information technology at the Technical University of Darmstadt and the Dresden University of Technology. After completing his doctorate, he worked for several years as a postdoc at the University of Utah. He chose the University of Freiburg as the research location for the early career research group. The project starts in February 2025 and will be funded for five years.

“We are very pleased to welcome Simon Binder to the University of Freiburg and to have him establish a new interdisciplinary research group that is dedicated to the development of neuroimplants with biohybrid electrodes,” says Prof. Dr.Thomas Stieglitz, Professor of Biomedical Microtechnology and co-spokesperson for BrainLinks-BrainTools at the University of Freiburg. The early career research group particularly benefits from the scientific environment as it is linked to the research facilities BrainLinks-BrainTools, the Freiburg Centre for Interactive Materials and Bioinspired Technologies (FIT) and the Faculty of Engineering at the University of Freiburg.

Improved biocompatibility through a better design of neuroimplants

“We expect that biohybrid electrodes will enable a higher resolution of the measured brain activity. In the long term, this could contribute to a better understanding of how the brain works.”

Dr. Simon Binder

The researchers are developing an innovative connection between the brain and electronic devices by incorporating specially cultured cells into the neuroimplant. These cells are designed to help the implant integrate seamlessly with the brain tissue. An important aspect of the research is the development of a new design for electrodes based on soft, gel-like materials. These materials are very similar to natural tissue, which can improve the compatibility and functionality of the implants. “With the biohybrid approach and the use of soft materials, we hope to achieve better biocompatibility of the implants and reduce the rejection reactions in the body,” explains Binder. “We also expect that biohybrid electrodes will enable a higher resolution of the measured brain activity. In the long term, this could contribute to a better understanding of how the brain works.”