A novel biomimetic tissue substitute combines precisely tunable mechanical properties with biological functionality and is now ready for applications in medical technology. The material was developed in the »PolyKARD« project by Fraunhofer IAP and the NMI Natural and Medical Sciences Institute. From 20.-24.04, 2026, the material will be presented together with further developments at the Hannover Messe, Fraunhofer joint booth.

How can you charge electric cars without plugging them into the power grid for hours on end? How can industrial robots be “refueled” during operation? And how does wireless energy transfer improve medical technology? These questions have occupied Prof. Nejila Parspour, Director of the Institute of Electrical Energy Conversion (IEW) at the University of Stuttgart, for more than twenty years.

Computer simulations and Artificial Intelligence are the main pillars of the “SIMPLAIX” collaboration, initiated by the Heidelberg Institute for Theoretical Studies (HITS). Together with colleagues from Heidelberg University and Karlsruhe Institute of Technology, HITS researchers are addressing challenges in the simulation of biomolecules and molecular materials by pooling their expertise in multiscale computer simulation and machine learning.

Computer simulations and Artificial Intelligence are the main pillars of the “SIMPLAIX” collaboration, initiated by the Heidelberg Institute for Theoretical Studies (HITS). Together with colleagues from Heidelberg University and Karlsruhe Institute of Technology, HITS researchers are addressing challenges in the simulation of biomolecules and molecular materials by pooling their expertise in multiscale computer simulation and machine learning.

The Volkswagen Foundation is supporting the Ulm scientist Professor Walter Karlen with more than 940,000 euros from the funding initiative "Momentum - funding for first-time researchers". The engineer has headed the Institute of Biomedical Engineering at Ulm University since 2021. Karlen conducts research in the field of mobile health on so-called Medicine Wearables, i.e. portable technology for recording health data.

Proof-of-concept study of organoid technology - 26/03/2026

Can organoids improve the treatment of pancreatic cancer?

A clinical trial called UNITEPANC is exploring whether organoid-based approaches can improve the treatment of pancreatic cancer. BIOPRO Baden-Württemberg spoke with the study’s principal investigator and pancreatic cancer specialist, Prof. Dr. Thomas Seufferlein of University Hospital Ulm, to discuss the disease more broadly along with the specific aims of the trial. The interview was conducted by Walter Pytlik on behalf of BIOPRO.

The powerhouse of the cells, known as mitochondria, appear to be able to influence the number of lipid droplets in the cell. Research into this previously unknown mechanism was conducted using baker’s yeast. This is shown by a recent study by the University of Freiburg, the University of Bonn and the University Hospital Bonn and the University of Freiburg. The results have now been published in the journal Nature Cell Biology.

In a published scientific study, researchers have succeeded in accurately diagnosing common types of brain tumors in children and adolescents based on tumor-derived genetic material in cerebrospinal fluid. Until now, these so-called liquid biopsies were not capable enough for such reliable diagnostics. The international research team has therefore optimized a sequencing technique and developed an AI-based computational method. In a later step,…

In a joint study conducted by the DZHK sites in Heidelberg, Munich and Göttingen, researchers are deciphering how the spatial organisation of the genome in the heart determines genetic disease risks.

How modern medical technology can prevent serious consequences of surgical procedures is demonstrated by a recent internationally recognized scientific publication. The study “Validation of conductive resin as electrode material in neuromonitoring with 3D-printed probes” under the leadership of Drs. Kiese and Bucher was awarded at the ICST Conference in Japan and highlights a medical topic that is crucial for the quality of life of many people.

Researchers at the Hopp Children's Cancer Center Heidelberg, the German Cancer Research Center, the Heidelberg Medical Faculty of Heidelberg University, and Heidelberg University Hospital have taken a decisive step toward more precise diagnosis of brain tumors. The latest version of the AI-based Heidelberg CNS Tumor Methylation Classifier can identify more than 180 tumor types —twice as many as the previous version.

The technology company KyooBe Tech GmbH and the German Center for Infection Research (DZIF) have signed a memorandum of understanding to collaborate on future research and development projects. The aim of the collaboration is to evaluate an innovative technology for inactivating pathogens using the specific effect of low-energy accelerated electrons (Low Energy Electron Irradiation—LEEI) and to make it available to DZIF scientists.

At the new Institute for Adaptive Mechanical Systems (IAMS) at the University of Stuttgart, the focus is on a new generation of walking robots and “soft robotics”. The researchers are developing adaptable robots inspired by natural movement patterns and made from innovative soft materials. The applications range from healthcare and industrial production to energy supply.

LICIT Solutions completes Series A financing to accelerate the development and commercialization of next-generation sustainable active ingredients for hygiene, preservation, and protective applications LICIT Solutions GmbH, a spin-out from the Institute for Clinical Anatomy and Cell Analysis at the University of Tübingen, has successfully completed its Series A financing round.

Worldwide, almost one third of women of childbearing age suffer from bacterial vaginosis. Such a disorder of the vaginal flora can cause urogenital infections, abscesses on the ovaries or fallopian tubes or premature births. As part of a BW Sprint project, the DITF have laid the basis for the development of a panty liner that supports the health of the vaginal environment and can prevent bacterial vaginosis.

A method developed at the Fraunhofer Institute for Interfacial Engineering and Biotechnology IGB enables bacterial, viral, fungal, or parasitic pathogens in sepsis patients to be identified much faster than before and with the highest precision. The approach is based on high-throughput sequencing of cell-free DNA circulating in the blood and was honored with the EARTO Innovation Award in the "Impact Delivered" category on October 14,…

Human immunodeficiency viruses (HIV) are insidious. They can evade the immune defence and antiviral drugs by becoming "latent". In this state, they are largely invisible and unassailable. As long as these dormant viruses persist, there is no cure for HIV/AIDS. However, researchers at Ulm University Hospital have discovered a new way to reactivate latent HI viruses.

On the basis of the cooperative relations that have developed over time, Heidelberg University and Harvard University are going to deepen and expand their cooperation. They have signed a Memorandum of Understanding to that effect. As an institutional internationalization project, the state of Baden-Württemberg is providing ten million euros to support this initiative, which is part of the state’s “Global Partnership in Science” activities.

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 at Heidelberg Uni Hospital have decoded a previously unknown mechanism by which HIV-1 selects its integration targets in the human genome. A research team identified RNA:DNA hybrids as molecular signposts for the virus. These findings reveal a vulnerability in the life cycle of HIV and provide therapeutic approaches for specifically controlling HIV reservoirs in the body. This has been one of the obstacles to curative HIV therapies.

Soft robots, robot systems made of soft materials, open up new perspectives for medical technology and industry. Jun.-Prof. Dr. Aniket Pal from the University of Stuttgart is conducting research into viscoelastic materials that have the potential to embed intelligent functions in soft robots. He is receiving 1.5 million euros in funding for this research as part of the Emmy Noether Program. The funding period began on September 1, 2025.

Researchers from the German Cancer Research Center (DKFZ) have collaborated with the SILVACX project group at Heidelberg University to develop a therapeutic vaccination concept that can mobilize the immune system to target cancer cells. The team showed that virus peptides coupled to silica nanoparticles can elicit effective T-cell responses against HPV-related tumors.

Until now, the early phase of drug discovery for the development of new therapeutics has been cost- and time-intensive. Researchers at KIT have developed a platform on which extremely miniaturized nanodroplets with a volume of 200 nanoliters per droplet and containing 300 cells per test can be arranged. This platform enables the researchers to synthesize and test thousands of therapeutic agents on the same chip, saving time and resources.

If the brain no longer responds properly to insulin (insulin resistance), this can lead to overweight, diabetes, and Alzheimer's disease. Researchers at the DZD in Potsdam and Tübingen have discovered small chemical modifications to genetic material (epigenetic changes*) in the blood that indicate how well the brain responds to insulin. These markers could help to detect insulin resistance in the brain – by means of a simple blood test.

The targeted engineering of artificial proteins with unique properties – that is possible with the assistance of a novel method developed by a research team of Heidelberg University. It centers around a new AI model. This allows for forecasting how two proteins have to be fitted together at the molecular level from individual parts – subunits – in order to engineer a functional, adjustable new protein.