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Displaying 1 to 9 of 9 results for audiology

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  • Auditory Brainstem Laboratory

    The overall goal of the Auditory Brainstem Library is to understand how abnormal auditory input from the ear affects the brainstem, and how the brain in turn affects activity in the ear through efferent feedback loops. Our emphasis is on understanding the effects of different forms of acquired hearing loss (genetic, conductive, noise-induced, age-related, traumatic brain injury-related) and environmental noise. We are particularly interested in plastic changes in the brain that compensate for some aspects of altered auditory input, and how those changes relate to central auditory processing deficits, tinnitus, and hyperacusis. Understanding these changes will help refine therapeutic strategies and identify new targets for treatment. We collaborate with other labs in the Depts. of Otolaryngology, Neuroscience, Neuropathology, the Wilmer Eye Institute, and the Applied Physics Laboratory at Johns Hopkins, in addition to labs outside the university to increase the impact and clinical relev...ance of our research. view more

    Research Areas: hearing disorders, compound action potentials, auditory brainstem response, otoacoustic emissions, operation conditions, audiology, acoustic startle modification, hearing, neurology

  • Bowditch Research Group

    Bowditch Research Group conducts research regarding speech discrimination in background noise, cochlear implants and osseointegrated hearing devices

    Research Areas: implantable technology, audiology, cochlear implant, hearing loss, hearing aids

  • Carey Research Group

    John Carey’s Research Group conducts research regarding diseases of the inner ear that affect both balance and hearing mechanisms. Key interests include superior semicircular canal dehiscence syndrome (SCDS), the normal vestibular reflexes and how they change with age, novel intratympanic treatments (i.e., middle ear injections) for conditions like Menière’s disease and sudden hearing loss, and the mechanisms of vestibular migraine. With Lloyd Minor, Dr. Carey helped develop the operation to repair the superior canal in patients with SCDS using image-guided surgery. Dr. Carey has been funded by the National Institutes of Health – National Institute on Deafness and Other Communication Disorders to study inner ear balance function in Menière’s disease and steroid treatment of sudden hearing loss.

    Research Areas: meniere's disease, vertigo, audiology, neurotology/otology, superior canal dehiscence, cochlear implant, hearing loss

  • Dwight Bergles Laboratory

    The Bergles Laboratory studies synaptic physiology, with an emphasis on glutamate transporters and glial involvement in neuronal signaling. We are interested in understanding the mechanisms by which neurons and glial cells interact to support normal communication in the nervous system. The lab studies glutamate transport physiology and function. Because glutamate transporters play a critical role in glutamate homeostasis, understanding the transporters' function is relevant to numerous neurological ailments, including stroke, epilepsy, and neurodegenerative diseases like amyotrophic lateral sclerosis (ALS). Other research in the laboratory focuses on signaling between neurons and glial cells at synapses. Understanding how neurons and cells communicate, may lead to new approaches for stimulating re-myelination following injury or disease. Additional research in the lab examines how a unique form of glia-to-neuron signaling in the cochlea influences auditory system development, whethe...r defects in cell communication lead to certain hereditary forms of hearing impairment, and if similar mechanisms are related to sound-induced tinnitus. view more

    Research Areas: epilepsy, synaptic physiology, ALS, stroke, neuronal signaling, glutamate transport physiology and function, audiology, neuroscience, neurology, nervous system, molecular biology

    Lab Website

    Principal Investigator

    Dwight Bergles, Ph.D.

    Department

    Neuroscience

  • Fuchs Laboratory

    The Fuchs Laboratory uses cellular electrophysiology, immunolabeling and electron microscopy to study synaptic connections between sensory hair cells and neurons in the cochlea. One effort focuses on an unusual cholinergic receptor that mediates efferent inhibition of hair cells, driving discovery of the molecular mechanisms, and offering a target for protection against acoustic trauma. A second topic concerns the small number of unmyelinated "type II" afferent neurons whose synaptic connectivity and response properties argue for a role as the pathway for noxious (too loud) sound. Our studies are motivated by curiosity about fundamental mechanisms, and to provide a foundation for understanding cochlear pathogenesis.

    Research Areas: synaptic connections, immunolabeling, neurons, elecrophysiology, audiology, cellular electrophysiology, hearing loss, electron microscopy, cochlea, cochlear pathogensesis

  • Glowatzki Lab

    Research in the Glowatzki Lab focuses on the auditory system, with a particular focus on synaptic transmission in the inner ear.

    Our lab is using dendritic patch clamp recordings to examine mechanisms of synaptic transmission at this first, critical synapse in the auditory pathway. With this technique, we can diagnose the molecular mechanisms of transmitter release at uniquely high resolution (this is the sole input to each afferent neuron), and relate them directly to the rich knowledge base of auditory signaling by single afferent neurons.

    We study pre- and post-synaptic mechanisms that determine auditory nerve fiber properties. This approach will help to study general principles of synaptic transmission and specifically to identify the molecular substrates for inherited auditory neuropathies and other cochlear dysfunctions.

    Research Areas: synaptic transmission, auditory synapses, inner ear, neurotransmitters, inherited auditory neuropathy, cochlear dysfunctions, otolaryngology, audiology, neuroscience, sound

  • Laboratory of Auditory Neurophysiology

    Research in the Laboratory of Auditory Neurophysiology aims to understand brain mechanism responsible for auditory perception and vocal communication in a naturalistic environment. We are interested in revealing neural mechanisms operating in the cerebral cortex and how cortical representations of biologically important sounds emerge through development and learning.

    We use a combination of state-of-the-art neurophysiological techniques and sophisticated computational and engineering tools to tackle our research questions.

    Current research in our laboratory includes the following areas (1) neural basis of auditory perception, (2) neural mechanisms for vocal communication and social interaction, and (3) cortical processing of cochlear implant stimulation.

    Research Areas: neurophysiology, neuroengineering, audiology, cochlear implant, learning, language

    Lab Website

    Principal Investigator

    Xiaoqin Wang, Ph.D.

    Department

    Biomedical Engineering

  • Lin Research Group

    The Lin Research Group addresses research questions that lie at the interface of hearing loss, gerontology, and public health. Using a range of methodologies and multidisciplinary collaboration, research broadly focuses on investigating three basic questions pertaining to hearing loss and public health: 1) what are the consequences of hearing loss for older adults?; 2) what is the impact of treating hearing loss on potentially mitigating these outcomes?; and 3) how can hearing loss be addressed from the societal perspective given that nearly 2/3 of all older adults have a clinically-significant hearing impairment?

    Research Areas: otolaryngology, public health, audiology, gerontology, hearing loss, societal perspectives

  • Vestibular NeuroEngineering Lab

    Research in the Vestibular NeuroEngineering Lab (VNEL) focuses on restoring inner ear function through “bionic” electrical stimulation, inner ear gene therapy, and enhancing the central nervous system’s ability to learn ways to use sensory input from a damaged inner ear. VNEL research involves basic and applied neurophysiology, biomedical engineering, clinical investigation and population-based epidemiologic studies. We employ techniques including single-unit electrophysiologic recording; histologic examination; 3-D video-oculography and magnetic scleral search coil measurements of eye movements; microCT; micro MRI; and finite element analysis. Our research subjects include computer models, circuits, animals and humans. For more information about VNEL, click here.
    VNEL is currently recruiting subjects for two first-in-human clinical trials:
    1) The MVI Multichannel Vestibular Implant Trial involves implantation of a “bionic” inner ear stimulator intended to partially restore sensation... of head movement. Without that sensation, the brain’s image- and posture-stabilizing reflexes fail, so affected individuals suffer difficulty with blurry vision, unsteady walking, chronic dizziness, mental fogginess and a high risk of falling. Based on designs developed and tested successfully in animals over the past the past 15 years at VNEL, the system used in this trial is very similar to a cochlear implant (in fact, future versions could include cochlear electrodes for use in patients who also have hearing loss). Instead of a microphone and cochlear electrodes, it uses gyroscopes to sense head movement, and its electrodes are implanted in the vestibular labyrinth. For more information on the MVI trial, click here.
    2) The CGF166 Inner Ear Gene Therapy Trial involves inner ear injection of a genetically engineered DNA sequence intended to restore hearing and balance sensation by creating new sensory cells (called “hair cells”). Performed at VNEL with the support of Novartis and through a collaboration with the University of Kansas and Columbia University, this is the world’s first trial of inner ear gene therapy in human subjects. Individuals with severe or profound hearing loss in both ears are invited to participate. For more information on the CGF166 trial, click here.
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    Research Areas: neuroengineering, audiology, multichannel vestibular prosthesis, balance disorders, balance, vestibular, prosthetics, cochlea, vestibular implant

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