Research Group Biomedical Technology for Diagnostic Tests and Tissue Engineering

This research group is investigating new implant materials in 3D cell culture models and the dynamic cultivation of autologous (endothelial) cell systems in special pulse wave bioreactors for a vascular graft. Microstructured scaffolds and new bioinks are designed using 3D printing. In addition, lateral flow tests are developed, e.g., after kidney transplantation, as well as optogenetically active cell systems for drug release in the inner ear (Hearing4All). KI-based indicators from complex databases support, among other things, health care research projects (MinDial, focus: patients with kidney disease).

Tissue engineering is a rapidly growing sector in the field of future-oriented medicine and offers enormous potential in the development of bioartificial vascular prostheses, which are becoming increasingly important in a rapidly aging society. One of the main problems within this project is the isolation and cultivation of endothelial cells under the aspect of autologous transplantation. However, recent studies show that human mesenchymal stem cells isolated from adipose tissue of patients (hASCs, cooperation with the Department of Plastic Surgery of the MHH) have approaches for differentiation in an endothelial direction and positively influence the differentiation of immature endothelial cells into capillaries. We therefore developed a protocol for the targeted use of stem cells in coculture with endothelial cells. For the induced secretion of proangiogenic markers, the cultivation parameters hypoxia and shear stress play an important role. In parallel, we isolate endothelial progenitor cells from peripheral blood (cooperation with the blood bank of the MHH) and optimize their extracorporeal expansion and development into a confluent cell layer on scaffold materials for endothelialization. Flow cytometric analysis of specific cell subsets and selective subcultivation supports the formation of mature endothelial monolayers. In addition, we investigate the influence of different shear stress conditions (static vs. dynamic cultivation under pulsatile or laminar flow of different flow velocities) on these endothelial progenitor cells isolated from peripheral blood.    

In cooperation with eNIFE, our research group developed a functional bioreactor for the clinical supply and cultivation of a "vascular graft" (bioartificial vascular prosthesis). In contrast to existing systems, this bioreactor also regulates the differentiation process of the growing graft and controls the cultivation conditions. For this purpose, sensor systems for pH, temperature, glucose, etc. were adapted and non-contact monitoring via ultrasound was established. The bioreactor has already been awarded with the VDI prize in 2018 and is now being optimized in line with current concepts of Medical Device Regulation. The following topics are being worked on here: Sterility tests, tightness tests, monitoring concepts by means of sensor technology, pressure monitoring i. Vgl. with Comsol-Estimierungen for near-wall shear stress during a cultivation, flow measurements by means of various tubular scaffolds, among others, from pig and horse, but also from the 3 D bio-printer    

As part of the Cluster of Excellence “Hearing for All” we use our experience with mesenchymal stem cells and cell transfections for the development of optogenetically activatable cells for human therapy. In cooperation with the group of Prof. A. Warnecke, light induction by means of an optogenetic switch will be used to induce the transcription of certain pharmacologically or neuroprotectively important proteins, e.g. during the healing of cochlear implants in the context of accompanying cell therapies. Enzymes can also be specifically switched on for the activation of nanoparticles in drug delivery (cooperation with the research group of Prof. P. Behrens, Inorganic Chemistry, NIFE). An optogenetic system of the WG of Prof. W. Weber, University of Freiburg could already be successfully optimized in CHO cells for induction by laser systems of the WG Prof. A. Heisterkamp in NIFE and is currently being transferred to mesenchymal stem cells from adipose tissue or bone marrow.

The working group participated in the MCA project by setting up mobile SARS-CoV-2 analysis by throat swab at the diagnostic container, quality management according to RiLibaek and medical support. In particular, an immunological screening was established, which allows the evaluation of different test systems.

Three studies on SARS-CoV-2 acute diagnostics, Aantibody screening and immunity testing in occupational groups in the greater Lower Saxony area were submitted to the Medical Association of Lower Saxony in cooperation with coronavirus researchers at the University of Veterinary Medicine Hannover and have now been carried out.