| Scientists have long known that hair cells along the basilar membrane inside the cochlea translate sound waves into electrical impulses that are then sent to the brain for further processing. Different frequencies of sound waves are captured by the hair cells at different points along the membrane which helps the brain identify the frequency and sort complex sounds into recognizable patterns.
Diagram of the structure of the human ear. Source: MIT.
Several years ago MIT researchers Dennis Freeman and Roozbeh Ghaffari identified that the tectorial membrane - a small string of gel material less than an inch long and thinner than a single strand of human hair - also plays a role in this process. They discovered that sound waves that move up and down travel along the basilar membrane while those that move side to side travel along the tectorial membrane.
Freeman, Ghaffari, and several other collaborators recently discovered that sound waves did not travel as fast or as far along the tectorial membrane in mice missing the TectB gene (which encodes one of three proteins that form the tectorial membrane) as compared to mice with that gene intact. This leads to fewer hair cells being stimulated, making it more difficult to distinguish between similar sounds.
The researchers hope to use this discovery to develop a new generation of hearing aides capable of tuning into specific ranges of frequencies correlating to the human voice. Hearing aides today are not able to focus on specific sounds but rather amplify all of the sounds input into them, both signal and noise.
TFOT has previously reported on other research and technology related to hearing and assisting the hearing impaired including new tactile devices that translate sounds into vibrations the deaf and hearing impaired can feel on their skin, an ear implant that makes it easier for the hearing impaired to distinguish sounds from each other, and a computerized lip reading system that can help the hearing impaired as well as help the police solve crimes.
Read more about the MIT research into how the tectorial and basilar membranes work during the hearing process in this press release.