Peter Osypka Institute of Medical Engineering
Research
The scientific work in the field of surgical navigation and augmented reality focuses on the development of new technologies to support computer-assisted surgical interventions. Both commercially available navigation systems and self-developed devices are used. The focus is also on the use of augmented reality goggles to provide the surgeon with location-accurate overlays directly in the surgical site. The exact calibration of the cameras and AR glasses used is of crucial importance in these applications.
The aim of the research and development focus on electrostimulation and ablation is the continuous improvement of diagnostics and therapy of heart diseases.
Cooperation with maximum care institutions such as the MediClin Heart Center Lahr/Baden and the University Hospital of the Ludwig-Maximilians-University Munich enables us to conduct interdisciplinary basic and clinical application research and to develop new methods and technologies.
With the aim of increasing the effectiveness of education and training of medical and medical technology staff, company employees and students of medical technology, we are developing didactic solutions for teaching and learning materials for cardiac electrotherapy in cooperation with the Freiburg University of Education.
The new research field of medical engineering materials is currently being established at Offenburg University of Applied Sciences. The focus is on materials and manufacturing processes in medical engineering with an emphasis on metallic materials, biodegradable metals and additive manufacturing methods. A corresponding research laboratory is also being set up and will be available for laboratory tests, project work and final theses as well as for research projects.
Research in the field of neuroacoustics focuses on a deeper understanding of the human auditory system - also in interaction with other sensory organs. The aim is to further improve diagnostics and thearpy of hearing loss, for example with hearing aids or cochlear implants. Methods of signal processing, technical and audiological acoustics, electrical engineering and computer science are used.
Research in NeuroScience is currently focused on the development of new intelligent neuroprosthetic approaches, primarily for the hand. This involves the use of 3-D computer-aided design (CAD), multi-material polymer printing, finite element method (FEM), deep learning and augmented reality methods.
Title | Plasticity of the auditory system with respect to static time differences of the ear signals (PASD Teil 1 - PASD2020) |
Short Name | PASD2020 |
Short Description | Ziel ist es, den Einfluss von statischen Laufzeitunterschieden, die durch unterschiedliche Hörsystemversorgung (z.B. Cochlea-Implantat ipsi- und Hörgerät kontralateral) auftreten können, auf die Schalllokalisationsfähigkeit und auf die räumliche Entmaskierung von Sprache unter Berücksichtigung von audiovisueller Interaktion zu ermitteln. |
Year Of Acquisition | 2020 |
Start Date | 2021-04-01 |
End Date | 2024-04-30 |
Project Managers | Zirn, Stefan, Prof. Dr. |
Faculties | EMI |
Institution | POIM |
Funder Kind | DFG |
Private Funders | |
Public Funders | DFG |
Sponsorship | DFG Sachbeihilfe |
Cooperation Partners | |
Research focus of the university | Life Science Engineering |
Dissertation | Sebastian Roth: "Plastizität des auditorischen Systems in Bezug auf statische Zeitunterschiede der Ohrsignale" |
Project Finances
Year | Amount Type | Sum | Description |
---|---|---|---|
Fördersumme III (brutto mit PP) | 288,438.00 € |