Ménière's Disease
Hearing Health Foundation’s Emerging Research Grants (ERG) program awards grants to researchers studying Ménière's disease, including:
Mechanisms of endolymphatic hydrops including mechanisms of cochlear fluid regulation
Genetics of Ménière's disease
Animal models of Ménière's disease
Imaging of hydrops
Etiology, diagnosis, and treatment of Ménière's disease
Vestibular function and dysfunction
ERG awards are for up to $50,000 per year, one year in length in the first instance, and renewable for a second year. Find more information below about Ménière's disease projects awarded a grant in prior years.
Researchers interested in applying for an Emerging Research Grant are encouraged to review our grant policies, subscribe to alerts, and check our ERG page for application cycle dates and specific grant opportunities available this year.
Recent Ménière's Disease Grantees & Projects
Mass Eye and Ear
Auditory and vestibular phenotype characterization of a Ménière’s disease model in humans and mice with X-linked hypophosphatemia
Our group has begun to segregate the pool of Ménière’s disease patients into distinct subtypes based upon specific clinical characteristics and morphologic features of the inner ear endolymphatic sac and vestibular aqueduct. One cohort—designated MDhp—demonstrated on histopathology and radiologic imaging an incompletely developed (hypoplastic) endolymphatic sac and vestibular aqueduct and had a high comorbid prevalence of X-linked hypophosphatemia. XLH is a genetic phosphate metabolism and bone growth disorder caused by a loss-of-function variant in the Phex gene. The high coincidence of XLH in the MDhp cohort led to the hypothesis that the two disorders may have etiologic similarities. Our preliminary studies suggest that the Phex gene-deficient XLH mouse also recapitulates clinical features of the MDhp cohort: hearing loss and balance dysfunction, endolymphatic hydrops, and hypoplasia of the endolymphatic sac and vestibular aqueduct. During this project we will determine whether the inner ear phenotype of humans with XLH generally resembles that of MDhp, and whether the XLH mouse model also exhibits an MDhp phenotype. Characterizing the MDhp phenotype within the context of patients with XLH and a Phex-deficient mouse model is a critical first step toward investigating the pathophysiology of MD and elucidating the genetic etiology of the MDhp subgroup. This research may demonstrate that the Phex gene-deficient mouse can be used as a reliable animal model of the MDhp subtype, which will pave the way for future studies of the role of the Phex gene mutation in MD patients and, more generally, the genetic basis of this complex disease.
UCLA David Geffen School of Medicine
Cellular and molecular biology of the microvasculature in the macula utricle of patients diagnosed with Ménière’s disease
To investigate the microscopic structure of the vasculature (blood vessel system) of balance organs from patients with intractable Ménière’s disease. Ishiyama’s hypothesis is that altered biochemical pathways affecting the vasculature of the blood labyrinthine barrier—which protects the inner ear from toxins and infections—may cause a dysfunction of the inner ear, leading to hearing loss and vertigo.
Ishiyama’s recent research revealed structural cellular changes in the blood labyrinthine barrier of the utricle, a balance organ, in Ménière’s patients. This project continues the work by detailing the cells and biochemical pathways that are altered in Ménière’s disease. This will provide greater information on the blood labyrinthine barrier and allow for the development of interventions that prevent the progression of hearing loss and stop the disabling vertigo in Ménière’s disease patients.
The Ohio State University
Differentiating Ménière's disease and vestibular migraine using audiometry and vestibular threshold measurements
Patients presenting with recurrent episodic vertigo (dizziness), such as Ménière's disease (MD) and vestibular migraine (VM), can present a diagnostic challenge as they can both produce recurrent vertigo, tinnitus, motion intolerance, and hearing loss. Further complicating this issue is that the diagnosis of each is based upon patient history with little contribution from an objective measure. Previous attempts to better differentiate MD and VM have included a variety of auditory and vestibular tests, but these evaluations have demonstrated limitations or not shown the appropriate sensitivity and specificity to be used in the clinical setting. Recently, vestibular perceptual threshold testing has shown the potential to better differentiate MD and VM by demonstrating different and opposite trends with testing, and these evaluations are ongoing. In addition to vestibular evaluations, audiometry (hearing testing) is a mainstay of testing in those with vestibular symptoms, especially with any concern of MD, and is thus commonly available. Standard hearing testing, however, is not sensitive or specific enough alone to differentiate MD and VM, but this project’s hypothesis is that combining audiograms with vestibular perceptual threshold testing will result in a diagnostic power greater than that possible with either option used individually. The population of patients with MD and VM is an ideal setting to examine similarities and differences, as MD is classically an otologic disease and VM, in theory, has little to do with auditory function. Additionally, this same principal can be applied to any disease process that affects both vestibular and auditory function (such as tumors, ototoxicity).
Rice University
Understanding the biophysics and protein biomarkers of Ménière’s disease via optical coherence tomography imaging
Our sense of hearing and balance depends on maintaining proper fluid balance in a specialized fluid in the inner ear called the endolymph. Ménière’s disease is an inner ear disorder associated with increased fluid pressure in the endolymph that involves dizziness, hearing loss, and tinnitus. Ménière’s disease is difficult to diagnose and treat clinically, which is a source of frustration for both physicians and patients. Part of the barrier to diagnosing and treating Ménière’s disease is the lack of imaging tools to study the inner ear and a poor understanding of the underlying causes. The goal of this research is to develop an approach to noninvasively image the inner ear and study the internal structures in the vestibular system in typical and disease states. We will utilize optical coherence tomography (OCT), a technique capable of imaging through bone, and observe changes in the fluid compartments in the inner ear. The expected outcome of this research will be the establishment of a powerful non-invasive imaging platform of the inner ear that will enable us to test hypotheses, in living animals, on how ion transport regulates the endolymph, how disorders of ion transport cause disruption of endolymphatic fluid, and how the expression of different biomarkers lead to disorders of ion transport.
Harvard Medical School
Development and Physiology of the Endolymphatic Duct and Sac in Zebrafish
Abnormalities in our sense of hearing and balance are incapacitating in the extreme, and, when subtle, cause psychological distress. Meniere’s disease is an inner ear disease with unclear causes that is inferred from episodes of vertigo, hearing loss, tinnitus, and the sensation of fullness in the ear that can last two to four hours. An unstable inner ear environment is believed to underlie Meniere’s disease. Recently, Swinburne has developed methods to image the live development and physiology of the portion of the Zebrafish ear conserved in humans and believed to be dysfunctional in Meniere’s disease: the endolymphatic duct and sac. With these methods, Ian hopes to gain basic understanding of how the inner ear’s environment is normally maintained and how a defect can lead to a disease.
Classifying the endolymphatic duct and sac cell types and their gene sets using high-throughput single-cell transcriptomics
To understand how the inner ear endolymphatic duct and sac stabilize the inner ear’s environment and to identify ways to restore or elevate this function to mitigate or cure Ménière's disease. The endolymphatic duct and sac play important roles in stabilizing a fluid composition necessary for sensing sound and balance. The recurrent vertigo in Ménière's is likely caused by a malfunction of the endolymphatic sac, causing volume or pressure changes in the inner ear.
Swinburne recently found that the typical-functioning endolymphatic sac periodically inflates and deflates like a balloon, and that specialized cell structures in the sac appear to transiently open, causing the deflation of the endolymphatic sac. The sac, then, appears to act as a relief valve to maintain a consistent volume and pressure within the inner ear. This project will generate a list of endolymphatic sac cell types and the genes governing their function, which will aid in Ménière's diagnosis (which can be delayed due to the range of fluctuating symptoms) and the development of a targeted drug or gene therapy.
Johns Hopkins University School of Medicine
The effect of fluid volume on vestibular function and adaptation in patients with Ménière’s disease
Individuals with Ménière’s disease experience spontaneous attacks of spinning vertigo, ear fullness, tinnitus, and hearing loss. We do not know the pathophysiology of Ménière’s disease. On some tests of the inner ear, individuals with Ménière’s have responses indicating inner ear balance is not functioning well (absent caloric responses), but other tests suggesting it is (head impulse testing). The reason for this is debated. Strong magnetic resonance imaging (MRI) scanners cause dizziness and nystagmus (back-and-forth beating of the eyes from inner ear stimulation) in all healthy humans due to magnetic vestibular stimulation (MVS). The combination of MVS and MRI imaging provides a unique opportunity to better understand the physiology of patients with Ménière’s disease. This project will assess nystagmus in strong MRI machines in individuals with Ménière’s and compare this to tests of vestibular function and to imaging of the inner ear.
Arizona State University
The role of unipolar brush cells in vestibular circuit processing and in balance
The cerebellum receives vestibular sensory signals and is crucial for balance, posture, and gait. Disruption of the vestibular signals that are processed by the vestibular cerebellum, as in the case of Ménière’s disease, leads to profound disability. Our lack of understanding of the circuitry and physiology of this part of the vestibular system makes developing treatments for vestibular disorders extremely difficult. This project focuses on a cell type in the vestibular cerebellum called the unipolar brush cell (UBC). UBCs process vestibular sensory signals and amplify them to downstream targets. However, the identity of these targets and how they process UBC input is not understood. In addition, the role of UBCs in vestibular function must be clarified. The experiments outlined here will identify the targets of UBCs, their synaptic responses, and the role of UBCs in balance. A better understanding of vestibular cerebellar circuitry and function will help us identify the causes of vestibular disorders and suggest possible treatments for them.
Long-term goal: To develop a better understanding of the neural circuits that underlie vestibular function. A more complete understanding of the circuitry and physiology of the vestibular cerebellum is necessary to develop therapies for vestibular dysfunction caused by peripheral disorders such as Ménière’s disease.