With the FeMEA project – Ferroelectric Microelectrodes for Biomedical Applications – Hahn-Schickard is setting a pioneering course in bioelectronics research. The aim of the project is to develop novel microelectrode arrays in which ferroelectric materials are used as functional interfaces in CMOS chips for the first time.

Researchers from the Cluster of Excellence CIBSS have demonstrated that an actin scaffold stabilizes the cell nucleus upon mechanical stress. This protective mechanism helps cancer cells to avoid dying during their migration in the body. In the long term, targeted interventions in this mechanism could help to prevent metastases.

The groninger Group has acquired Reinraumtechnik Ulm GmbH (RTU). With this strategic move, the family-owned company headquartered in Crailsheim not only expands its technological portfolio but also strengthens its expertise in a field that is crucial to the pharmaceutical industry: cleanroom and isolator technology.

An imaging technique developed by Freiburg researchers provides insights into cardiac arrhythmias that can cause sudden cardiac death in animal models. The changes discovered could explain why even seemingly healthy people are sometimes affected.

Using nanostructures to fight bacteria - 09/10/2025

Inspired by insect wings: antibacterial surfaces for implants

What do dragonfly wings and dental implants have in common? Nothing yet but that could soon change. The Karlsruhe-based start-up nanoshape has developed a process for coating medical implants with nanostructures similar to those found on insect wings. The coating makes surfaces bacteria-repellent and is aimed at reducing the risk of post-surgical inflammation. The first product could be on the market as early as next year.

Tumors are not a comfortable place to live: oxygen deficiency, nutrient scarcity, and the accumulation of sometimes harmful metabolic products constantly stress cancer cells. A research team from the DKFZ and the IMP in Vienna has now discovered that the acidic pH value in tumor tissue is a decisive factor in how pancreatic cancer cells adapt their energy metabolism in order to survive under these adverse conditions.

Until today, the aggressiveness of prostate cancer has been assessed primarily using the Gleason grading system—an analysis of cancer tissue in a pathology laboratory that is highly subjective. An international research team led by the German Cancer Research Center (DKFZ) has now developed a novel, explainable AI model that aims to make the diagnosis of prostate cancer more transparent and less susceptible to error.