Elige tu región

Selecciona la región que mejor se ajuste a tu ubicación o preferencias.

Elige el idioma del sitio

Esta configuración controla el idioma de la interfaz de usuario, incluidos los botones, los menús y todo el texto del sitio. Selecciona tu idioma preferido para la mejor experiencia de navegación.

Elige los idiomas para los anuncios de empleo

Selecciona los idiomas para los anuncios de empleo que deseas ver. Esta configuración determina qué anuncios de empleo se mostrarán.

Collaborative Research Centre (CRC) 1270 ‘Electrically Active ImplanNts – ELAINE’

Collaborative Research Centre (CRC) 1270 ‘Electrically Active ImplanNts – ELAINE’

Visitar página Web

Sobre el empleador

Summary of the research programme of the Collaborative Research Centre ELectrically Active ImplaNts - ELAINE

European populations are ageing rapidly. By the year 2060, every third person living in Germany will be older than 65. For this reason, the social and socio-economic relevance of regenerative therapies is clearly increasing. This holds particularly true for implants: the older the population grows, the more medical implants for various indication areas are required and the more often they have to be replaced during the course of therapy. The research vision pursued by the Collaborative Research Centre focuses on novel electrically active implants. Specifically, we address implants employed for the regeneration of bone and cartilage, and implants for deep brain stimulation to treat movement disorders. Three central research objectives are a means to implement the research vision. The first objective is to establish innovative energy autonomous implants that allow a feedback-controlled electrical stimulation. Thus, we will pave the ground for new long-time medical applications, and individual patient treatment by conceiving an ultra-low power, miniaturised implant electronic platform supporting all electrically active implants being considered in ELAINE.

A second objective is efficient multi-scale simulation models to enable rapid progress in targeted implant improvements and patient-specific therapies. Here, new methods in the simulation of biomaterial compounds, electromagnetic stimulus of living cells and the validation of results will push the fundamental understanding in ELAINE far beyond the state of the art. The third long-term objective is to analyse the basic mechanisms of electrical stimulation in bone, cartilage and brain, and to translate this knowledge into clinical practice. The technical vision focuses on an energy-minimised electrical stimulator that is 12-weeks autonomous, fully programmable and implantable with continuous and intermittent modes for application both in humans and in animals. For this purpose, scientists from the fields of electrical engineering, computer science, mechanical engineering, material science, physics, biology, and medicine will work together in an interdisciplinary manner. As a unique characteristic, our interdisciplinary consortium enables a scientifically sound validation of newly derived theoretical models, computational methods and technical solutions through experiments in both engineering and the life sciences. This high-risk collaborative and interdisciplinary research programme is designed to demonstrate new approaches for future biomedical implants, hopefully increasing the chances of overcoming the above-mentioned health problems of ageing populations.

Funder:

 

Partner:

 

Ubicación de la empresa

Descubre empleadores similares

Fraunhofer-Gesellschaft
Fraunhofer-Gesellschaft Alemania 0 posiciones abiertas
University of Cologne
University of Cologne Alemania 22 posiciones abiertas
Helmut Schmidt University
Helmut Schmidt University Alemania 4 posiciones abiertas
University of Bayreuth
University of Bayreuth Bayreuth, Alemania 3 posiciones abiertas
Carl von Ossietzky University of Oldenburg
Carl von Ossietzky University of Oldenburg Oldenburg, Alemania 2 posiciones abiertas
Más empleadores

Esto puede ser de tu interés

Buried treasure: How the ocean’s history reveals our climate’s future
Buried treasure: How the ocean’s history reveals our climate’s future NIOZ Royal Netherlands Institute for Sea Research 4 minutos de lectura
Using AI to accelerate recycling
Using AI to accelerate recycling OFFIS 4 minutos de lectura
Building belonging: Rethinking diversity in the classroom
Building belonging: Rethinking diversity in the classroom Free University of Bozen - Bolzano 4 minutos de lectura
Why KTH Is the Ideal Place to Shape the Future Through Your Work
Why KTH Is the Ideal Place to Shape the Future Through Your Work KTH Royal Institute of Technology 5 minutos de lectura
Bringing Society’s Voice into Science
Bringing Society’s Voice into Science University of Oulu 5 minutos de lectura
Más historias

Descubrir trabajos relacionados

Postdoc in Real-Time Computational Biomechanics
Postdoc in Real-Time Computational Biomechanics University of Luxembourg hace 5 meses
Doctoral researcher in Translational Neuroscience
Doctoral researcher in Translational Neuroscience University of Luxembourg hace 5 meses
PhD in Informatics
PhD in Informatics University of Luxembourg hace 8 meses
Postdoctoral Researcher in Cyber-Resilient Systems
Postdoctoral Researcher in Cyber-Resilient Systems University of Luxembourg hace 10 meses
Scientist – Ion-trap chips (all genders)
Scientist – Ion-trap chips (all genders) Silicon Austria Labs (SAL) hace 4 meses
PhD Positions at International Max Planck Research School on Cellular Biophysics
PhD Positions at International Max Planck Research School on Cellular Biophysics International Max Planck Research School on Cellular Biophysics (IMPRS-CBP) hace 4 meses
Doctoral Researcher in Advanced Communications
Doctoral Researcher in Advanced Communications University of Luxembourg hace 5 meses
Más trabajos