THIS GRANT IS A CONTINUATION OF N000141512130 Drugs to Stimulate Neurite Regeneration from Damaged Cochlear Neurons

Abstract

Continuous exposure to high noise levels such as that produced by ship and jet engines and by blast exposure or weapon firing can cause Noise Induced Hearing Loss (NIHL). The majority of NIHL cases reported are of the sensorineural type. This occurs when the acoustic stimulation or shock wave is so powerful or of such consistent duration that it directly damages the auditory nerve and/or destroys the hair cells, the sound-sensing cells of the inner ear. When hair cells are destroyed, they cannot naturally grow back and the cochlear spiral ganglion neurons that originally connected the hair cells with the brain die or degenerate. Hearing loss from acoustic injury can be as profound as total deafness or as seemingly mild as a slow, inexorable degeneration of neurons over time. Moreover, not only can hearing be damaged during insult that causes Traumatic Brain Injury (TBI), but it is also negatively affected by medical interventions to treat TBI, including the administration of ototoxic but life-saving antibiotics. As hearing loss significantly impairs the communication necessary for job performance in the Armed Forces and quality of life after service, this disability is a significant problem for the Navy, the Marines, the Army and others in the Military. Adding to the decay in job performance caused by auditory dysfunction and the premature retirement of otherwise highly skilled and seasoned personnel, the financial burden to the Veterans Administration to care for affected veterans has risen to an annual cost of over $1 billion.The Navy has recognized the need for a multipronged attack on the problem, encouraging a range of basic and applied research in areas such as hair cell regeneration, personal protective gear, noise-dampening engineering and diagnostic devices. The key focus of this project is on the cochlear spiral ganglion neurons, the cells that connect the cochlear hair cells with the neurons in the brain. Without these neurons, the auditory information encoded by hair cells, medically induced regenerated hair cells, or cochlear implants will remain disconnected and undetected by the interpretive centers in the brain.This proposed project is meant to build on the foundation laid under a previous ONR-funded project. Under that grant, the PI developed a novel method for discovery of drugs aimed at inducing regrowth of nerve fibers from spiral ganglion neurons in vitro and used it to screen over 1000 compounds. The most promising chemical candidates were promoted to evaluation in a guinea pig model of noise induced hearing loss, using physiologic and confocal imaging analyses and pioneered the use of X-ray tomography to visualize and count spiral ganglion neurons in intact (unsectioned) cochleas of noise and drug exposed cochleas. It was shown that the compound identified in the screening protects against noise induced hearing loss. Here, the PI proposes to build on the discoveries made in the initial project by continuing to evaluate the effects of a promising drug candidate on noise induced hearing loss, to continue to evaluate new chemical compound libraries for their abilities to promote spiral ganglion neurite elongation, to explore more efficient ways to test drugs in vivo, and to continue to evaluate promising new compounds in animal models of noise induced hearing loss.

Document Details

Document Type

DoD Grant Award

Publication Date

Aug 12, 2016

Source ID

N000141612508

Entities

Tags