Despite lacking evidence for sympathetic overactivation in Ménière's disease, surgeons eagerly adopted sympathectomies, and later betahistine, and the latter is still commonly used outside the U.S. as treatment.
Understanding Inner Ear Fluid Buildup in Ménière’s Disease
Fluid buildup in the saccule and cochlear duct might be due to increased pressure, while the utricle might be better protected due to its thicker walls and functioning valve. This points to an inverse relationship between membrane thickness and fluid buildup, helping us better understand how fluid buildup occurs in Ménière's disease.
Activación de Canales TRPA1 en la Cóclea: ¿Tapones de Oído Propios Después de la Exposición al Ruido?
Our researcher translated her paper’s summary into Spanish: ¿Alguna vez te has sentido sordo o con los oídos tapados después de estar en un lugar con mucho ruido? Junto a mi equipo de investigadores en la Universidad de Kentucky encontramos que los canales TRPA1 contribuyen a este fenómeno.
Activation of TRPA1 Channels in the Cochlea: Built-in ‘Earplugs’ After Noise Exposure?
The activation of TRPA1 channels in the cochlea seems to be a protective mechanism—like wearing earplugs—that minimizes the exposure to sound.
Mouse Studies Tune Into Hearing Regeneration
In the non-sensory supporting cells of the inner ear, key genes required for conversion to sensory cells are shut off through a process known as epigenetic silencing. By studying how the genes are shut off, we begin to understand how we might turn them back on to regenerate hearing.
Brain Targets for Hearing Recovery After Noise-Induced Hearing Loss
Our results hold the promise to advance understanding of the cortical mechanisms underlying disorders associated with maladaptive cortical plasticity after peripheral damage, such as tinnitus, hyperacusis, and difficulty hearing in noisy environments.
Potential Therapy for Blast-Induced Hearing Loss and Tinnitus
These findings suggest that by inhibiting PARP1, a protein, it may be possible to maintain the health and survival of hair cells following blast injuries. The restoration of energy production from both mitochondria and glycolysis contributes to this protective effect.
Driven by Data and Collaboration
The collaborative spirit of our Hearing Restoration Project consortium is especially evident as we work together to complete a publication describing our analysis of hair cell gene expression.
Scientists Discover Repair Process That Fixes Damaged Hair Cells
The hair cells deploy a protein called XIRP2, which can sense damage to the cores that are made of a substance called actin. The researchers found that XIRP2 first senses damage, then migrates to the damage site and repairs the cores by filling in new actin.
Sounds Emitted by the Ear Provide a Window Onto the Cochlea’s Frequency Tuning
We demonstrated that sounds emitted by the ear—called otoacoustic emissions (OAEs), specifically distortion-product OAEs—may provide a noninvasive window onto cochlear frequency tuning. OAEs are a byproduct of the amplification process mediated by outer hair cells and are often measured in clinical hearing screenings.