Implantable fiber-optic sensor tested as a potential hearing aid

The technology is based on completely fiber-optic technology, which senses the tiniest ossicle movements.

Karl Landsteiner University of Health Sciences (Krems, Austria) and partners are moving closer to developing a fully implantable hearing aid as demonstrated in recent tests. The technology is based on completely contact-free fiber-optic technology, which senses the tiniest ossicle movements and uses them to stimulate the acoustic nerves. The joint Austrian-Serbian team has tested this new innovation and results are published in the journal Biosensors and Bioelectronics.

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Hearing aids should be heard, not seen. And this is precisely what fully surgically implantable hearing devices can deliver. Their Achilles heel is the microphones, which receive sounds and use a sophisticated process to transform them into impulses for the acoustic nerves. It is essential that they can function error-free inside the human body for many years. With existing technology, this is only possible to a limited extent, so new solutions are urgently needed.

Speaking about the background to the latest breakthrough, professor Georg Mathias Sprinzl, head of the Ear, Nose and Throat Department at St Pölten University Hospital, which is part of KL Krems, said, "Even state-of-the-art hearing aids often require parts outside the ear. This has many disadvantages for people who wear hearing aids: they can be stigmatised if the device is visible, parts of the ear often become inflamed and the wearer’s own voice can sound distorted. Fully implantable hearing aids can overcome these problems--but the technology still needs to be fine-tuned. And that’s what we are working on."

One highly significant advance is the use of contact-free fiber-optic measuring technology to detect sounds, which would allow the microphone to be positioned inside the ear. The technology is based on low-coherence interferometry, a method which picks up superimposed sound waves. The team used this approach for the optical measurement of nanometer-sized ossicle vibrations. As Sprinzl explained, "The ability to pick up sound from the ossicles is a huge advantage because it fully preserves the natural amplification function of the outer ear and the eardrum. On the technological side, this also minimises signal distortion and feedback."

However, with a view to deploying the system in the human ear, Sprinzl and his colleagues needed to address a number of fundamental requirements. For example, they had to develop the operative procedure for the implantation, as well as the means of "targeting" the laser used for sensing. Sprinzl, who performs over 1,000 implants of various types of hearing aid each year, noted, "Obviously, we did not carry out this development work on people. Instead, we used artificial and animal models, which allowed us to optimise the quality of the ossicle vibration sensing system."

The recently published findings confirm the effectiveness of the technology and that, in principle, it could be used inside the ear for long periods. In these initial tests, the team found that the laser beam which is critical for sensing vibrations remained accurately aligned with the selected ossicle for five months. The team's measurements also showed that the system can distinguish between the sounds to be transmitted and background noise, although more work will be required in this respect in future. Aspects such as system miniaturization and electricity consumption will also be addressed by the team, which comprises ACMIT GmbH, the Medical University of Vienna, the University of Belgrade, KL Krems, and ENT specialists.

SOURCE: Karl Landsteiner University of Health Sciences; https://www.kl.ac.at/en

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