University of Pittsburgh
The Influence of Dynamic Limb Movement on Activity within the Vestibular Nuclei: the Role of the Cerebellum

Balance is inherently a multi-modal sense. To maintain balance in upright stance or during walking, input from several modalities – namely the vestibular system (from the inner ear), proprioceptive system (from muscles and joints), and visual system – must be interpreted by the central nervous system and synthesized to understand body position in space relative to gravity. Our goal is to investigate how vestibular and limb proprioceptive inputs interact in the central nervous system, with a particular focus on the brainstem and cerebellum as these are key sites of multisensory processing of balance input. We anticipate that the results of these studies will have important implications for the understanding of multi-sensory processing within central vestibular pathways and for the clinical treatment of humans with vestibular disorders.

Research area: Vestibular and Balance Disorders; Vestibular Physiology

Long-term goal of research: To elucidate the physiologic pathways responsible for integrating vestibular and proprioceptive information and to ultimately develop clinical strategies based upon these physiologic underpinnings to improve the health of humans with vestibular disorders.

University of Tennessee

Auditory neuroplasticity following experience with cochlear implants

Cochlear implants provide several benefits to older adults, though the amount of benefit varies across people. The greatest improvements in speech understanding abilities usually happen within the first 6 months after implantation. It is generally accepted that these gains in performance are a result of neural changes in the auditory system, but while there is strong evidence of neural changes following cochlear implantation in children, there is limited evidence in adults with hearing loss in both ears. This study will examine how neural responses change as a function of the amount of cochlear implant use, when compared to longstanding hearing aid use. Listeners who are candidates for a cochlear implant (who either decide to pursue implantation or to keep wearing hearing aids) will be tested at several time points, from pre-implantation and up to 6 months after implantation. The results of this project will improve our understanding of the impact of cochlear implant use on neural responses in older adults, and their relationship with the ability to understand speech.

Cincinnati Children’s Hospital Medical Center
Signaling defects due to Tricellulin deficiency

Mutations in a protein called Tricellulin lead to hereditary hearing loss in humans and degeneration of cochlear sensory cells and deafness in mice. In the inner ear, Tricellulin is found in the sensory epithelia at sites where three epithelial cells meet. The localization of Tricellulin at the junction between cells gives it the potential to respond to external cues and transmit the signals to the cell interior. The current project aims at uncovering the potential cellular signaling roles of Tricellulin by determining the gene expression changes in the inner ear of Tricellulin mutant mice compared to wild-type mice. The results of this study will not only add to the existing knowledge of the inner ear development and maintenance but also will examine the direct effects of losing a protein that helps preserve our hearing.

Research area: Fundamental Auditory Research

Long-term goal of research: To determine the role of cell junction proteins in the inner ear function and elucidate the biological processes that are affected by genetic mutations in these proteins. As tight junctions are also the focus of drug delivery studies, it is valuable to realize the cellular functions of the associated proteins so that they can be manipulated for therapeutic purposes.

Washington University
Cellular and Genetic Bases of Age-Associated Strial Degeneration and EP decline in NOD congenic mice

The electric currents that run through cochlear sensory cells are largely driven by a specialized cochlear structure called the stria vascularis. The work of the stria requires a lot of energy, so that it is densely vascularized (hence the name). Loss of strial blood vessels is thought to be a common cause of age-related hearing loss. Not everyone shows signs of this kind of pathology, however, so that there must be forms of certain genes carried by some people that act as ‘risk’ genes. People who carry ‘risk’ genes may be more likely to experience loss of strial blood vessels, and ultimately loss of the stria itself. In 2008 we discovered that a particular breed of mice (NOD mice) start out with a normal stria, but then show loss of strial vessels, followed by loss of the stria beginning from both ends of the cochlea and progressing toward the middle. These changes were accompanied by other distinctive anatomic features that may tell us something about the process, or may be unrelated. By crossing these mice with another strain that does not show pathology, we will be able to determine what pathologic features are inherited together (thus caused by the same genes), how many genes are involved, and their approximate locations. Any gene(s) we find may have human counterparts that exert similar effects.

Research areas: auditory physiology/pathophysiology, cell biology of hearing and deafness

Long-term goal of research: Finding ‘risk’ genes may not point directly to cures or allow us to predict who will lose their hearing. Nevertheless, identifying the genes, gene networks, and gene products will help pinpoint key reactions that can be tweaked pharmacologically. We are among the first to seek out mouse strains with pathology of the stria vascularis and to use these to uncover genes that promote strial degeneration in mice, and possibly in humans.

University of Florida College of Medicine
Prevention of aminoglycoside-induced hearing loss with the mitochondria-targeted antioxidant MitoQ

Aminoglycoside antibiotics, such as gentamicin, are commonly used to treat serious infections due to bacteria. However, these drugs can cause hearing loss. At present, there is no solution to prevent hearing loss caused by aminoglycoside antibiotics. This research will determine if the antioxidant MitoQ will prevent hearing loss induced by aminoglycoside antibiotics.

Research area: Hearing loss, Ototoxicity

Long-term goal of research: To develop and apply practicable intervention strategies to prevent hearing loss induced by drugs that are toxic to the inner ear.

University of Massachusetts, Amherst
The Impact of Total Communication on the Auditory Perception of Speech

For decades, most children with severe-to-profound hearing loss were educated in special schools for the deaf. In more recent years, increasing numbers of these children have been partially or fully main-streamed and educated along-side their peers with normal hearing. Much debate has ensued regarding the best language of instruction (sign-only, sign+speech, speech only) for them. It is generally thought that a symbolic, gesture-based language system, such as manually-coded English used as part of simultaneous communication methods, provides a facilitative benefit. However, there is not enough information about how children combine manual and spoken cues in this type of communication system to draw firm conclusions about optimal approaches to classroom teaching that best support aural reception of spoken language. We plan to ask and answer a very specific question: What is the direct effect of simultaneously delivered sign language on the perception of speech for children with hearing loss developing spoken language? The research approach builds from the observation that perception of speech that has been artificially degraded (e.g., to mimic a hearing loss) is strikingly improved when listeners have knowledge of the content of the message. The proposed study applies this hypothesis to children with hearing loss to determine whether signs serve in part as a prime to improve auditory perception of speech.

Research area: Auditory Development; Congenital Hearing Loss; Fundamental Auditory Research

Long-term goal of research: To assess how total communication – the combined use of manual signs, speech, and speech-reading – can most effectively be employed as a habilitation strategy to improve auditory perceptual abilities.

Oregon Health & Science University
Changes in Residual Hearing in a Hearing-impaired Guinea Pig Model of Hybrid Cochlear Implants (CIs)

The goal of the current study is to understand mechanisms of hearing loss with “hybrid” or “electro-acoustic” cochlear implants (CIs), a new type of CI designed to preserve low-frequency hearing and allow combined acoustic-electric stimulation in the same ear. Hybrid CI users perform significantly better than standard CI users on musical melody recognition, voice recognition, and speech recognition in the presence of background talkers. However, approximately 10% of hybrid CI patients lose all residual hearing, and another 20% lose 20-30 dB after implantation. We hypothesize that in addition to surgical trauma, electrical stimulation through the hybrid CIs also damages cochlear cells, leading to the residual hearing loss (HL). Aim 1 is to determine the contribution of electrical stimulation to the residual HL in hybrid CI guinea pigs with noise-induced steeply-sloping high frequency hearing loss (NIHFHL). Aim 2 is to examine the effect of electrical stimulation on the cochlear pathology. The findings will guide the development of strategies to prevent hearing loss with electrical stimulation, and allow extension of the hybrid concept to all cochlear implant recipients with usable residual hearing.

Research area: Cochlear implants

Long term goal of research: To improve residual hearing preservation with “hybrid” or “electro-acoustic” cochlear implants (CIs), a new type of CI designed to preserve low-frequency hearing and allow combined acoustic-electric stimulation in the same ear.

University of Michigan
Cellular and synaptic basis of binaural gain control through the commissure of the inferior colliculus

Deficits in binaural hearing make it difficult for users of cochlear implants and hearing aids to localize sounds and follow speech in everyday situations. One of the most important sites for binaural computations is the inferior colliculus (IC). Located in the auditory midbrain, the IC is the hub of the central auditory system, receiving most of the ascending output of the auditory brainstem and much of the descending output of the auditory cortex. The left and right lobes of the IC communicate with each other through a massive connection called the commissure. Recent data from in vivo recordings show that commissural projections shape how IC neurons encode sound location. This suggests that important binaural interactions arise through the IC commissure, but the cellular and synaptic basis of these interactions are largely unknown. Understanding these interactions will provide foundational knowledge to guide future efforts to restore binaural hearing.

Johns Hopkins University
Mechanisms involved in efferent synapse formation and maintenance in cochlear hair cells

This research aims at understanding the molecular mechanisms that underlie the formation and maintenance of the connections between the sensory hair cells and efferent nerve fibers that provide feedback from the brain to the ear. Such fibers are important modulators of inner ear activity. Our investigation includes different approaches (electrophysiology, confocal microscopy, and mouse genetics) in parallel.

Research area: synaptic transmission in the inner ear

Long-term goal of research: to understand the developmental machinery in the inner ear, which can lead to the ability to treat deficits in their function.