Cochlear Implantation: Concept, Results Outcomes and Quality of Life
- PMID: 35605612
- DOI: 10.1055/a-1731-9321
Cochlear Implantation: Concept, Results Outcomes and Quality of Life
Abstract
Cochlear implant today are an essential method of auditory rehabilitation in patients with severe to profound hearing loss. Due to the rapid development of implant technology the results have been markedly improved. Today about 80 % of patients can use the telephone and children achieve near to normal hearing and speech development. In consequence, more patients are candidates for a cochlear implant today including those with high frequency deafness and single sided deafness. However, today only 60,000 out of 1 Million CI-candidates in Germany have been implanted so far. In future multi modal universal auditory implants will provide combined electric-mechanical stimulation to make best use of the residual auditory hearing and the electrical stimulation of the auditory nerve. They allow a continuous adaptation of the stimulation strategy onto the given functional status of haircells and auditory nerve fibers especially in cases of progressive hearing loss. Brain computer interfaces will allow the automated fitting and adaptation to the acoustic scene by optimizing the signal processing for best possible auditory performance. Binaural hearing systems will improve directional hearing and speech perception in noise. Advanced implants are composed of individualized electrodes by additive manufacturing which can be inserted atraumaticly by a computer and robot assisted surgery. After insertion they automatically adept to the anatomy of the individual cochlear. These advanced implants are composed with additional integrated biological components for the preservation of residual hearing and regeneration of neural elements to improve the electrode nerve interface. This will allow to increase the number of electrical contacts as a major step towards the bionic ear. This will allow overcoming the principal limits of today's cochlear implant technology. Advanced care models will allow an easy way for the patient towards hearing preservation cochlear implantation under local anesthesia using minimal invasive high precision cochlear implant surgery. These implant systems will become a personal communicator with improved connectivity. Remote care and self-fitting will empower the patient to optimize his own hearing.
Cochlea-Implantate stellen heute eine unverzichtbare Methode zur auditiven Rehabilitation hochgradig hörgeschädigter Patienten dar. Durch die rasante Entwicklung der Implantat-technologie haben sich die Hörergebnisse erheblich verbessert, ca 80% der Patienten können telefonieren und Kinder erreichen eine nahezu normale Hör- und Sprachentwicklung. Das hat zu einer Indikationsausweitung hin zu Patienten mit Hochtontaubheit und einseitiger Taubheit geführt. Zur Zeit sind aber nur etwa 60 000 der ca 1 Million CI-Kandidaten implantiert. Zukünftig werden multimodale universelle Hörimplantate für die kombinierte elektro-mechanische Stimulation zur Verfügung stehen, die fortlaufend eine Anpassung der Stimulationsstrategie an den jeweiligen Funktionszustand von Haarzellen und Hörnerven auch bei progredienter Schwerhörigkeit ermöglichen. Brain-Computer-Interfaces erlauben die automatisierte Anpassung an die Hörsituation und eine Optimierung der Signalverarbeitung zur Erzielung eines bestmöglichen Hörvermögens. Binaurale Hörsysteme erlauben eine Verbesserung von Richtungshören und Hören im Störgeräusch. Advanced Implants besitzen additiv gefertigte individualisierte Elektroden, die sich nach atraumatischer robotisch assistierter Insertion aktiv der Anatomie der Cochlea anpassen. Sie sind in Abhängigkeit von der Pathophysiologie mit integrierten biologischen Komponenten ausgestattet, unterstützen die Erhaltung des Restgehörs und ermöglichen die Regeneration neuraler Elemente zur Verbesserung der Elektroden-Nerven-Schnittstelle. Dadurch lassen sich die heutigen grundsätzlichen Grenzen der CI-Technologie überwinden und in Richtung des physiologischen Gehörs verschieben. Das Bionische Ohr ist somit in Reichweite. Durch konsequente Weiterentwicklung mit Vereinfachung der Versorgung, hörerhaltender Implantation unter Lokal-Anästhesie und Anwendung robotischer Systeme werden zukünftig mehr Patienten von dem neuen physiologischen Hören profitieren.
The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial-License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/).
Conflict of interest statement
Die Autorinnen/Autoren geben an, dass kein Interessenkonflikt besteht.
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