NEURAL MODULATION OF HEARING LOSSES INDUCED BY LOUD SOUND
Funder
National Health and Medical Research Council
Funding Amount
$290,500.00
Summary
Loud sounds, from occupational and recreational sources, are the most common threat to hearing and can result in temporary hearing losses (as might be experienced after an evening at a noisy pub or concert) or permanent hearing losses (after prolonged or multiple loud sounds, as for example in a noisy work environment). Noise reduction programs are either not always possible or effectively applied. A parallel strategy is the study of biological mechanisms that may ameliorate hearing damage, with ....Loud sounds, from occupational and recreational sources, are the most common threat to hearing and can result in temporary hearing losses (as might be experienced after an evening at a noisy pub or concert) or permanent hearing losses (after prolonged or multiple loud sounds, as for example in a noisy work environment). Noise reduction programs are either not always possible or effectively applied. A parallel strategy is the study of biological mechanisms that may ameliorate hearing damage, with a view to optimising such mechanisms. I propose to build on seminal Australian work to examine how one such system, nerves from the brain to the inner ear (the site of most damage from loud sounds), modulates hearing losses caused by loud sounds. Early studies indicated these nerves could protect from damage induced by short-lasting loud sound and this has led to international interest in functional applications of such protection to reduce hearing damage suffered by humans. However, my recent work indicates the nerves exert complex protective and exacerbative effects to loud sounds similar to common trauma or occurring under conditions similar to common trauma. They even exacerbate hearing losses due to loud sound, especially when there is an imbalance in hearing sensitivity in the two ears (bilateral) similar to what is common in humans. These findings make it critical that functional application be delayed until the full range of effects exerted by the nerves is understood. I propose to elucidate the novel complex effects of these nerves to loud sound. Specific aims are: (1) To understand effects of these pathways to loud sounds like those encountered by humans, (2) To investigate how chronic imbalanced bilateral hearing sensitivity, like that common in humans, alters effects of the nerves and when they change from being protective to exacerbative, (3) To adduce how an atraumatic sound affects hearing losses due to later loud sound and the role played by these nerves.Read moreRead less
Delayed Loss Of Acoustic Hearing After Cochlear Implantation: Mechanisms And Clinical Identification With New Cochlear Implant Technology
Funder
National Health and Medical Research Council
Funding Amount
$1,040,157.00
Summary
Natural hearing can be combined with a cochlear implant to improve sound quality and speech understanding. However, natural hearing frequently deteriorates weeks to months after cochlear implantation. This seems to occur when cochlear fluid buildup (hydrops) or fibrosis within the inner ear disrupts cochlear mechanics. We plan to monitor these processes in patients by recording directly from the cochlear implant, and conduct laboratory experiments to find therapies to alleviate their effects.
Nanoengineered Drug Delivery To The Inner Ear To Prevent Progressive Hearing Loss
Funder
National Health and Medical Research Council
Funding Amount
$479,056.00
Summary
Hearing loss is a common sensory deficit and can get progressively worse over time, eventually requiring a cochlear implant. In this project we will examine the effectiveness of a new technique that uses nanoengineered particles to provide long term and controlled delivery of drugs in order to prevent progressive hearing loss and protect residual hearing following cochlear implantation. We will develop the next generation of nanotechnology to enhance drug delivery in pathological ears.
Do ‘classical’ Or ‘oxidative’ UVR-induced DNA Adducts Drive Melanoma Induction After Ultraviolet Radiation
Funder
National Health and Medical Research Council
Funding Amount
$335,757.00
Summary
There is debate about the mechanisms by which sun exposure influences melanoma development. This leads to difficulties in formulating adequate sunscreens and guidelines for safe levels of exposure. We will elucidate the critical UV-induced DNA adducts that are necessary for MM development. This will introduce experimental evidence into the debate about sun exposure and melanoma. The use of post sunburn creams containing enzymes which rapidly remove the dangerous DNA adducts will be indicated.
The immune system employs a variety of strategies to combat parasites including viruses. One of them is cytolytic lymphocytes, cells that can recognize and destroy virus-infected target cells. These cells use, besides other molecules, enzymes called granzymes to kill target cells by inducing suicide in them. We intend to investigate if those granzymes can protect cytolytic lymphocytes themselves from being infected by viruses and turned into viral factories. We are going to use a model of a natu ....The immune system employs a variety of strategies to combat parasites including viruses. One of them is cytolytic lymphocytes, cells that can recognize and destroy virus-infected target cells. These cells use, besides other molecules, enzymes called granzymes to kill target cells by inducing suicide in them. We intend to investigate if those granzymes can protect cytolytic lymphocytes themselves from being infected by viruses and turned into viral factories. We are going to use a model of a natural infection, ectromelia, mouse pox. Mouse pox is fatal in resistant strains of mice if the genes for the two dominant granzymes are deleted. This indicates that granzymes are essential for fighting this viral disease. We will explore in which cells of the immune system granzymes are expressed and whether virus entry into a cell can actually trigger their expression. Furthermore, we will investigate how the granzymes inhibit virus infection within the infected cell to determine whether the mechanisms involved resemble those used by cytolytic lymphocytes in killing of target cells (i.e. degradation of DNA and mitochondrial damage), or whether they represent entirely new facets of granzyme function. Finally, using viruses from a number of different families, we will establish whether these functions of granzymes also contribute to protection from other viral infections. An understanding of the role of these granzymes in the innate immune response, i.e. before antigen specific T cell and antibody responses are fully activated, is of great significance as it may allow us to manipulate this particular anti-viral response and thus enhance survival and reduce morbidity in viral infections.Read moreRead less
Improving Music Appreciation For People With Prosthetic Hearing Devices By Enhancing Auditory Stream Segregation
Funder
National Health and Medical Research Council
Funding Amount
$266,560.00
Summary
Music perception is one of the most often-cited problems for people with hearing aids or cochlear implants. Part of the problem is related to the reduced ability to hear different instruments or melodic lines separately. This ability is based on perceptual differences between auditory streams. Psychophysics experiments will be performed to understand the effect of different acoustic parameters on auditory streaming. An innovative approach to restore music appreciation will be tested on people wi ....Music perception is one of the most often-cited problems for people with hearing aids or cochlear implants. Part of the problem is related to the reduced ability to hear different instruments or melodic lines separately. This ability is based on perceptual differences between auditory streams. Psychophysics experiments will be performed to understand the effect of different acoustic parameters on auditory streaming. An innovative approach to restore music appreciation will be tested on people with impaired hearing.Read moreRead less
Special Research Initiatives - Grant ID: SR0354908
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
The Insect-Plant Chemical Ecology Network (IPCEN). We bring together plant molecular biology, entomology and analytical chemistry to transform three leading fields of Australian research into an advanced science with far reaching capabilities in innovative research and applied outcomes. Expertise studying the biochemical pathways that produce specific plant compounds and expertise in insect recognition and response to these chemicals will be brought together. This will lead to new research outco ....The Insect-Plant Chemical Ecology Network (IPCEN). We bring together plant molecular biology, entomology and analytical chemistry to transform three leading fields of Australian research into an advanced science with far reaching capabilities in innovative research and applied outcomes. Expertise studying the biochemical pathways that produce specific plant compounds and expertise in insect recognition and response to these chemicals will be brought together. This will lead to new research outcomes and solutions to problems in agriculture, horticulture, forestry and protection of Australia's native flora. Researchers are struggling to create these links, constrained by disciplinary boundaries and geographical isolation. Key industries and researchers already support this proposal.Read moreRead less
Using transgenic plant-based production and delivery systems to develop an avian influenza vaccine. This project aims to provide proof-of-concept for the rapid production of plant-made vaccines of high strategic value to the poultry industry. Plant-made AI vaccines would help safeguard primary industries in Australia from exotic influenza strains and shield rural communities from the impact of stock losses. This collaboration will also contribute to the Molecular Farming industry by ensuring tha ....Using transgenic plant-based production and delivery systems to develop an avian influenza vaccine. This project aims to provide proof-of-concept for the rapid production of plant-made vaccines of high strategic value to the poultry industry. Plant-made AI vaccines would help safeguard primary industries in Australia from exotic influenza strains and shield rural communities from the impact of stock losses. This collaboration will also contribute to the Molecular Farming industry by ensuring that Australian interests are considered as this frontier technology tackles the challenges of turning academic research into marketable products. The key features of an oral plant-made AI vaccine, including rapid and non-egg based production, also make this an attractive technology for the future development of swine and human influenza vaccines.Read moreRead less
Cochlear Type II Neurons In Contralateral Suppression
Funder
National Health and Medical Research Council
Funding Amount
$459,434.00
Summary
Sound in one ear affects hearing in the other ear. This contralateral suppression is important for hearing attention and protection from noise damage. We will test the hypothesis that cochlear type II sensory neurons provide the sensory input for this process using models where neuronal development is altered, or the neurons are removed. The study addresses hearing disability in society, facilitating cochlear prosthesis development and the understanding of hearing loss.