Discovery of new neurons in the inner ear can lead to new therapies for hearing disorders
Researchers at Karolinska Institutet in Sweden have identified four types of neurons in the peripheral auditory system, three of which are new to science. The analysis of these cells can lead to new therapies for various kinds of hearing disorders, such as tinnitus and age-related hearing loss. The study is published in Nature Communications.
When sound reaches the inner ear, it is converted into electrical signals that are relayed to the brain via the ear’s nerve cells in the cochlea. Previously, most of these cells were considered to be of two types: type 1 and type 2 neurons, type 1 transmitting most of the auditory information. A new study by scientists at Karolinska Institutet shows that the type 1 cells actually comprise three very different cell types, which tallies with earlier research showing variations in the electrical properties and sonic response of type 1 cells.
“We now know that there are three different routes into the central auditory system, instead of just one,” says François Lallemend, research group leader at the Department of Neuroscience, Karolinska Institutet, who led the study. “This makes us better placed to understand the part played by the different neurons in hearing. We’ve also mapped out which genes are active in the individual cell types.”
The team conducted their study on mice using the relatively new technique of single-cell RNA sequencing. The result is a catalogue of the genes expressed in the nerve cells, which can give scientists a solid foundation for better understanding the auditory system as well as for devising new therapies and drugs.
“Our study can open the way for the development of genetic tools that can be used for new treatments for different kinds of hearing disorders, such as tinnitus,” says Dr. Lallemend. “Our mapping can also give rise to different ways of influencing the function of individual nerve cells in the body.”
The study shows that these three neuron types probably play a part in the decoding of sonic intensity (i.e. volume), a function that is crucial during conversations in a loud environment, which rely on the ability to filter out the background noise. This property is also important in different forms of hearing disorders, such as tinnitus or hyperacusis (oversensitivity to sound).
“Once we know which neurons cause hyperacusis we’ll be able to start investigating new therapies to protect or repair them,” explains Dr. Lallemend. “The next step is to show what effect these individual nerve cells have on the auditory system, which can lead to the development of better auditory aids such as cochlear implants.”
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