Listen Up

The outer ear funnels sound waves from the air to the ear drum. For humans, sounds in the range of 20–20,000 Hz are transmitted by three bones (the smallest bones in the body) resting under the ear drum to a membrane lying on the cochlear surface. Vibrations passed on by the fluid-filled spiral tube reach the hair cells inside, each of which supports a tuft of 30–150 stereocilia arranged in rows of increasing height. These cells transduce mechanical signals into chemical ones through

Megan Stephan
May 9, 2004
<p></p>

The outer ear funnels sound waves from the air to the ear drum. For humans, sounds in the range of 20–20,000 Hz are transmitted by three bones (the smallest bones in the body) resting under the ear drum to a membrane lying on the cochlear surface. Vibrations passed on by the fluid-filled spiral tube reach the hair cells inside, each of which supports a tuft of 30–150 stereocilia arranged in rows of increasing height. These cells transduce mechanical signals into chemical ones through mechano-sensitive channels (see story p. 26).

Mechanical vibrations bend the stereocilia, putting tension on the tip links and in turn pulling on the mechanotransduction channels to open them. The resulting entry of potassium depolarizes the cell, opening L-type calcium channels near its base. Calcium influx triggers the release of neurotransmitter-filled vesicles, generating an action potential in nearby nerve cells that ultimately reaches the brain. Otoferlin is involved...

Interested in reading more?

Magaizne Cover

Become a Member of

Receive full access to digital editions of The Scientist, as well as TS Digest, feature stories, more than 35 years of archives, and much more!
Already a member?