Summary
The optical cochlear implant (oCI) aims to restore near natural hearing in profoundly hearing impaired and deaf patients. Sound perception will be restored through an implantable medical device in combination with a gene therapy medicinal product. Thereby the auditory nerve is stimulated directly through focused light replacing the dysfunctional or absent hair cells. This is achieved through combination of micro-scale light emitter technology and precise neural control through expression of light-gated ion channels in the auditory nerve (called optogenetics).
Here, we propose to prove feasibility of an optical waveguide modules for future optical cochlear implants. Building on fabricating micro-scaled waveguide arrays, multi-beam laser diode emitters, we plan to couple them via micro-lens arrays in a compact multi-channel optical module for testing the feasibility of miniaturization and integration of the optical components. Preclinical validation shall be performed in rodents.
The proposed waveguide-based optical module combines several aspects, which makes it a candidate for later clinical application. The optical emitters can be safely integrated in the hermetically sealed titanium package housing the internal oCI electronics. Thus, there is no need to directly insert the emitters in the cochlear turns, which mitigates the risk of heat impact on the patient during optical stimulation. Furthermore, emerging red light activated opsins can be addressed by readily available red laser diode technology.
Here, we propose to prove feasibility of an optical waveguide modules for future optical cochlear implants. Building on fabricating micro-scaled waveguide arrays, multi-beam laser diode emitters, we plan to couple them via micro-lens arrays in a compact multi-channel optical module for testing the feasibility of miniaturization and integration of the optical components. Preclinical validation shall be performed in rodents.
The proposed waveguide-based optical module combines several aspects, which makes it a candidate for later clinical application. The optical emitters can be safely integrated in the hermetically sealed titanium package housing the internal oCI electronics. Thus, there is no need to directly insert the emitters in the cochlear turns, which mitigates the risk of heat impact on the patient during optical stimulation. Furthermore, emerging red light activated opsins can be addressed by readily available red laser diode technology.
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| Web resources: | https://cordis.europa.eu/project/id/101113433 |
| Start date: | 01-03-2023 |
| End date: | 31-08-2024 |
| Total budget - Public funding: | - 150 000,00 Euro |
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Original description
The optical cochlear implant (oCI) aims to restore near natural hearing in profoundly hearing impaired and deaf patients. Sound perception will be restored through an implantable medical device in combination with a gene therapy medicinal product. Thereby the auditory nerve is stimulated directly through focused light replacing the dysfunctional or absent hair cells. This is achieved through combination of micro-scale light emitter technology and precise neural control through expression of light-gated ion channels in the auditory nerve (called optogenetics).Here, we propose to prove feasibility of an optical waveguide modules for future optical cochlear implants. Building on fabricating micro-scaled waveguide arrays, multi-beam laser diode emitters, we plan to couple them via micro-lens arrays in a compact multi-channel optical module for testing the feasibility of miniaturization and integration of the optical components. Preclinical validation shall be performed in rodents.
The proposed waveguide-based optical module combines several aspects, which makes it a candidate for later clinical application. The optical emitters can be safely integrated in the hermetically sealed titanium package housing the internal oCI electronics. Thus, there is no need to directly insert the emitters in the cochlear turns, which mitigates the risk of heat impact on the patient during optical stimulation. Furthermore, emerging red light activated opsins can be addressed by readily available red laser diode technology.
Status
SIGNEDCall topic
ERC-2022-POC2Update Date
12-03-2024
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