June 13, 2013 — Many
disorders of the inner hear which affect both hearing and balance can be
hugely debilitating and are currently largely incurable.
Cochlear
implants have been used for many years to replace lost hearing resulting
from inner ear damage.
However, to date, there has not been an
analogous treatment for balance disorders resulting from inner ear
disease.
One potential new treatment is an implantable vestibular
prosthesis which would directly activate the vestibular nerve by
electrical stimulation.
This prosthetic treatment is tested in a new study by Christopher
Phillips and his colleagues from the University of Washington in
Seattle, USA.
Their findings are published in the Springer journal Experimental Brain Research.
Meniere's disease is a disorder of the inner ear that can affect hearing and balance to varying degrees.
The characteristic symptoms are episodes of vertigo, tinnitus, a feeling of pressure in the ears and hearing loss which tends to worsen as time goes on.
Although there is medication which can help once an attack is underway, there is currently no long-term therapy which can resolve the disease completely.
Phillips and his colleagues have developed a vestibular prosthesis which delivers electrical stimulation to the fluid inside the semi-circular canals of the ear.
In effect, the stimulation of the fluid makes the brain believe that the body is moving or swaying in a certain direction.
This then causes a compensatory postural reflex to stabilize the posture thereby helping to restore balance.
For their study, this prosthesis was inserted into the ears of four subjects all suffering from long-term Meniere's disease and differing degrees of hearing loss which was resistant to other management strategies.
After a full evaluation of each participant's vestibular function, their eye function was measured in response to electrical stimulation along with their postural response both with their eyes open and closed.
The researchers found that electrical stimulation of the fluid in the semicircular canals of the affected ear did result in a change in posture, the direction of which was dependent on which ear was stimulated.
However, each subject had different sway responses to the stimulation given.
The authors believe this could be caused by small differences in the location of the electrode between subjects.
Thus fine tuning and individual calibration for each electrode implant would be required for it to be effective.
Overall the results illustrate that this type of prosthesis may eventually be a possible treatment for balance issues caused by Meniere's disease.
However, there are a large number of matters which would need resolving before it is ready for use.
The lack of consistency in direction and magnitude of sway response would require further study to ensure that any prosthesis developed could give reliable results for different individuals.
The authors conclude: "Taken together, our findings support the feasibility of a vestibular prosthesis for the control of balance and illustrate new challenges for the development of this technology.
This study is a first step in that direction."
Their findings are published in the Springer journal Experimental Brain Research.
Meniere's disease is a disorder of the inner ear that can affect hearing and balance to varying degrees.
The characteristic symptoms are episodes of vertigo, tinnitus, a feeling of pressure in the ears and hearing loss which tends to worsen as time goes on.
Although there is medication which can help once an attack is underway, there is currently no long-term therapy which can resolve the disease completely.
Phillips and his colleagues have developed a vestibular prosthesis which delivers electrical stimulation to the fluid inside the semi-circular canals of the ear.
In effect, the stimulation of the fluid makes the brain believe that the body is moving or swaying in a certain direction.
This then causes a compensatory postural reflex to stabilize the posture thereby helping to restore balance.
For their study, this prosthesis was inserted into the ears of four subjects all suffering from long-term Meniere's disease and differing degrees of hearing loss which was resistant to other management strategies.
After a full evaluation of each participant's vestibular function, their eye function was measured in response to electrical stimulation along with their postural response both with their eyes open and closed.
The researchers found that electrical stimulation of the fluid in the semicircular canals of the affected ear did result in a change in posture, the direction of which was dependent on which ear was stimulated.
However, each subject had different sway responses to the stimulation given.
The authors believe this could be caused by small differences in the location of the electrode between subjects.
Thus fine tuning and individual calibration for each electrode implant would be required for it to be effective.
Overall the results illustrate that this type of prosthesis may eventually be a possible treatment for balance issues caused by Meniere's disease.
However, there are a large number of matters which would need resolving before it is ready for use.
The lack of consistency in direction and magnitude of sway response would require further study to ensure that any prosthesis developed could give reliable results for different individuals.
The authors conclude: "Taken together, our findings support the feasibility of a vestibular prosthesis for the control of balance and illustrate new challenges for the development of this technology.
This study is a first step in that direction."
Story Source:
The above story is based on materials provided by Springer Science+Business Media.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
- Phillips, C. et al. Postural responses to electrical stimulation of the vestibular end organs in human subjects. Experimental Brain Research, 2013 DOI: 10.1007/s00221-013-3604-3
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