Abstract

The goal of this proposal is to establish how endolymph composition and volume are regulated. Lack of knowledge in this area severely limits our understanding of disease processes of the inner car, such as Meniere's disease and perilymph fistula. For a number of years, we have pioneered the development of novel techniques to study inner ear fluids. Markers are iontophoresed, without volume disturbance, into the inner ear fluids and their movements monitored by ion-selective microelectrodes. These techniques have allowed the cross-sectional area and longitudinal movements of cochlear fluids to be accurately quantified in vivo. For some time, we have known that in the normal cochlea, longitudinal movements of cochlear fluids are extremely slow. We have now found that when endolymph volume is disturbed, longitudinal movements do occur which make a significant contribution to the ionic changes in endolymph.
The first aim of this project is to characterize the dependence of endolymph area changes and longitudinal movements on mechanical factors, such as pressure and volume disturbances. We will then assess whether or not pharmacological manipulations of ion transport processes in the cochlea result in area or flow changes. Comparable measures will be made in animals in which the endolymphatic sac has been ablated, to assess the role of this structure in endolymph volume regulation. The pathophysiology of the initial stages of hydrops development will be investigated in detail. In addition, magnetic resonance (MR) microscopy will be used to generate accurate 3-D reconstructions of the cochlear fluid spaces under a variety of experimental conditions. These anatomic data will provide the basis for numeric models of homeostatic processes in the cochlear fluids, which will be used to optimize experimental design and to generate accurate quantitative interpretation of findings. We will correlate anatomic measures, physical measures of flow and area, and chemical measures of electrolyte composition with measures of cochlear function. Only by understanding the relationships between mechanical, chemical and physiological processes, can we hope to understand how endolymph volume is regulated and how disturbances of volume can be treated in patients.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute on Deafness and Other Communication Disorders (NIDCD)
Type
Research Project (R01)
Project #
5R01DC001368-08
Application #
2882687
Study Section
Hearing Research Study Section (HAR)
Project Start
1992-01-01
Project End
2000-02-29
Budget Start
1999-03-01
Budget End
2000-02-29
Support Year
8
Fiscal Year
1999
Total Cost
Indirect Cost

  Institution

Name
Washington University
Department
Otolaryngology
Type
Schools of Medicine
DUNS #
062761671
City
Saint Louis
State
MO
Country
United States
Zip Code
63130

  Publications

Salt, Alec N; Plontke, Stefan K (2018) Pharmacokinetic principles in the inner ear: Influence of drug properties on intratympanic applications. Hear Res 368:28-40
Li, Wei; Hartsock, Jared J; Dai, Chunfu et al. (2018) Permeation Enhancers for Intratympanically-applied Drugs Studied Using Fluorescent Dexamethasone as a Marker. Otol Neurotol 39:639-647
Salt, Alec N; Hirose, Keiko (2018) Communication pathways to and from the inner ear and their contributions to drug delivery. Hear Res 362:25-37
Liebau, Arne; Pogorzelski, Olivia; Salt, Alec N et al. (2017) Hearing Changes After Intratympanically Applied Steroids for Primary Therapy of Sudden Hearing Loss: A Meta-analysis Using Mathematical Simulations of Drug Delivery Protocols. Otol Neurotol 38:19-30
Lichtenhan, J T; Hirose, K; Buchman, C A et al. (2017) Direct administration of 2-Hydroxypropyl-Beta-Cyclodextrin into guinea pig cochleae: Effects on physiological and histological measurements. PLoS One 12:e0175236
Plontke, Stefan K; Hartsock, Jared J; Gill, Ruth M et al. (2016) Intracochlear Drug Injections through the Round Window Membrane: Measures to Improve Drug Retention. Audiol Neurootol 21:72-9
Salt, Alec N; Plontke, Stefan K (2016) Drug Diffusion to the Apex of the Human Cochlea? A Comment on ""Kang WS, Nguyen K, McKenna CE, Sewell WF, McKenna MJ, Jung DH. Intracochlear Drug Delivery Through the Oval Window in Fresh Cadaveric Human Temporal Bones"". Otol Neurotol 37:1462-3
Lichtenhan, J T; Hartsock, J; Dornhoffer, J R et al. (2016) Drug delivery into the cochlear apex: Improved control to sequentially affect finely spaced regions along the entire length of the cochlear spiral. J Neurosci Methods 273:201-209
Salt, A N; Hartsock, J J; Gill, R M et al. (2016) Perilymph pharmacokinetics of locally-applied gentamicin in the guinea pig. Hear Res 342:101-111
Ellis, Erica M; Borovsky, Arielle; Elman, Jeffrey L et al. (2015) Novel word learning: An eye-tracking study. Are 18-month-old late talkers really different from their typical peers? J Commun Disord 58:143-57

Showing the most recent 10 out of 76 publications