For many hearing-impaired, their hearing is so damaged that a standard hearing aid is no longer enough. A new device will improve patients' hearing and can be implanted during outpatient surgery.
|Although the laboratory prototype of the electro-acoustic transducer is square in shape, future designs will be round. © Fraunhofer IPA|
''Sorry? I didn't catch that. Can you speak up please?'' People who are hard of hearing can quickly drift into social isolation. Worse, they can also get into dangerous situations, for example when driving or crossing the road.
In the case of patients with severe hearing impairments, however, conventional behind-the-ear hearing aids reach the limits of their usefulness. These patients' hearing can only be helped by an implant, which amplifies sounds more effectively than conventional systems and boasts better sound quality. But here's the snag: these middle ear implants require complex operations that last several hours. The high risk and expense of the surgery mean that it is rarely performed. But scientists could soon present patients with more hopeful prospects, thanks to their work on an innovative hearing aid that is significantly easier to implant, making it affordable for large numbers of people.
The new solution is composed of three parts - a case with a microphone and battery; wireless, optical signal and energy transmission between the outer and middle ear; and an electro-acoustic transducer – the centerpiece and loudspeaker of the implant.
Researchers from the Fraunhofer Institute for Manufacturing Engineering and Automation (IPA) in Stuttgart are developing the electro-acoustic transducer, which will be round in shape and measure approximately 1.2 millimeters.
The IPA's partners in the project, which is sponsored by the Federal Ministry of Education and Research, are the University Department of Otolaryngology, Head and Neck Surgery Tübingen, the Natural and Medical Sciences Institute (NMI) at the University of Tübingen, and the hearing aid specialist auric Hörsysteme GmbH.
''Our goal is to take the better sound quality of implantable hearing aids and combine it with a much simplified operation,'' says Dominik Kaltenbacher, engineer at IPA. ''To implant our system, all surgeons have to do is make a small incision at the side of the eardrum and then fold it forward. This can be done in outpatient surgery.''
Micro-actuator placed between middle and inner ear
The electro-acoustic transducer, which takes the form of a piezoelectric micro-actuator, is then placed directly at the connection between the middle and inner ear known as the ''round window''.
From there it transmits acoustic signals to the inner ear in the form of amplified mechanical vibrations, thereby enhancing the hearing capacity of patients. ''The electro-acoustic transducer works on the same principle as bending actuators,'' explains Kaltenbacher. ''The bending elements, which are arranged in the shape of a pie, consist of a laminated composite made from piezo-ceramics and silicon. If voltage is applied, the elements bend upwards and generate a mechanical vibration. This spreads to the membrane of the round window and the inner ear, stimulating the auditory nerve.''
The effect? Although the round window implant is no larger than a pinhead, it can output volumes of up to 120 decibels, which is roughly the noise a jackhammer makes. ''This high performance is necessary for very good speech comprehension, particularly for high-pitched sounds, which people who are severely hard of hearing find especially difficult to pick up,'' says the IPA researcher.
Experts are currently testing a first working prototype in the laboratory. Results have been positive to date. ''The individual components of the hearing aid have all been developed. The next step is to optimize and assemble them,'' says Kaltenbacher.
The implant must measure up to high requirements: the material must be encased so the body tolerates it and it has to remain stable over long periods – after all, hearing aid implants should last at least 10 years. The optimised individual components should be ready by June of this year; testing of the overall system is planned for 2014.