Using Stem Cells And Bioengineered Scaffolds To Promote Regeneration Following Necrotic Brain Injury
Funder
National Health and Medical Research Council
Funding Amount
$710,857.00
Summary
A number of injuries, including stroke, result in tissue loss. Consequently promoting repair will require restoration of tissue structure, replacement cells and a supportive environment to promote integration of these new cells. This study will engineer and develop novel scaffolds that can replace tissue whilst additionally providing physical and chemical support for newly implanted stem cells. This work will be conducted in an animal model of stroke.
Standardising Protocols For The Differentiation And Integration Of Human Pluripotent Stem Cell-derived Neural Transplants In Parkinson's Disease
Funder
National Health and Medical Research Council
Funding Amount
$987,664.00
Summary
Clinical trials have shown that transplanting dopamine neurons (specific nerve cells) into the brain of Parkinson’s disease patients can improve symptoms. Trials use fetal tissue for implantation, which is unsustainable and highly variable. This proposal will examine stem cells as an alternative. We will establish a reliable protocol to instruct human stem cells to become dopamine neurons, develop methods to select these cells and, examine the integration of these transplanted cells in the brain
Bilateral Cochlear Implants: Restoring Binaural Processing By Experience And Training With Binaural Cues
Funder
National Health and Medical Research Council
Funding Amount
$968,030.00
Summary
Cochlear implantation in both ears is increasingly common and while there are benefits, performance falls short of expectations, likely due to the degradation of the long-term deaf brain’s sensitivity to small timing differences of sounds reaching each of the two ears. By confirming the hypothesis that experience with high-fidelity timing information will improve performance, this study will drive the technical innovations required to maximise the benefits and investment of bilateral implants.
Neuroanatomical Correlates Of Susceptibility In A Model Of Genetic Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$329,275.00
Summary
Genetic generalized epilepsy (GGE) is the most common form of epilepsy, but our understanding of the pathogenesis, in particular anatomical effects of genetic mutations, is incomplete. This project represents the first quantitative study of anatomical changes caused by a human GGE mutation. Pilot data show that the fundamental wiring of the cortex is different in GGE brains with obvious implications for epileptogenesis. This study is expected to inspire improved treatment and diagnosis.
Effective Sensory Rehabilitation After Stroke: Targeting Viable Brain Networks.
Funder
National Health and Medical Research Council
Funding Amount
$767,525.00
Summary
New therapies have been developed to help the brain recover after stroke. We will compare brain networks involved in recovery of touch sensation under two new training conditions and in individuals with interruption to different parts of the network. Brain imaging will identify the functional and anatomical connections between brain regions. Our findings will guide therapists in choosing the best therapy for the right individual, based on knowledge of brain networks that have capacity to adapt.
Selective Modulation Of Neural Network Activity Using Focal Brain Stimulation
Funder
National Health and Medical Research Council
Funding Amount
$531,496.00
Summary
Transcranial magnetic stimulation (TMS) has been touted as a viable treatment for a range of psychiatric and neurological disorders. However, the extent to which localised TMS influences widespread brain networks remains unknown. To fill this gap, we will combine neuroimaging and TMS in healthy adults. The project will provide a scientific foundation for the use of brain stimulation as an effective tool for improving function in a range of clinical conditions.
A Role For The Pulvinar Nucleus In Visual Cortical Development And Plasticity
Funder
National Health and Medical Research Council
Funding Amount
$844,435.00
Summary
This project will investigate a part of the brain responsible for processing visual information, the pulvinar. This area has received little attention but has more recently been associated with the capacity for infants to recover vision following injuries such as stroke, as well as in mental health conditions such as schizophrenia. We will take a cell-to-system approach to uncover how this area develops and modulates the processing of visual information.
Schizophrenia affects 1 in 100 people, and yet its causes remain largely unclear. To improve understanding, treatment and management of the disease, the team performing this research will evaluate whether mobile DNA elements found in our genome are activated by stress and thereby alter how brain cells work in individuals affected by schizophrenia. They will also test whether mobile DNA can be blocked by drugs, perhaps revealing new strategies to treat the disease.
The Pulvinar Is Instrumental In The Development Of Visual Cortical Networks
Funder
National Health and Medical Research Council
Funding Amount
$1,192,911.00
Summary
This Project will elucidate the mechanisms and brain structures involved in visual system development and how their perturbation in early life can lead to neurodevelopmental and cognitive brain disorders, such as Williams and fragile-X syndromes as well as dyslexia. Furthermore, it will demonstrate how the visual brain has a greater capacity to compensate and achieve preservation of vision following an injury in early life.
Neogenin: A Molecular Determinant Of Neural Progenitor Polarity And Function
Funder
National Health and Medical Research Council
Funding Amount
$569,296.00
Summary
The neuroepithelium (NEP) contains the embryonic neural stem cells essential for the production of all neurons in the adult brain. Failure in NEP function leads to devastating neural tube defects and syndromes such as epilepsy, schizophrenia, and mental retardation. This project will identify the molecular mechanisms regulating NEP stem cell activity and the birth of new neurons in the embryonic neocortex.