Heart failure is a severely debilitating condition with a poor prognosis. It is characterized by retention of fluid and high nervous activity especially to the kidneys and the heart. Even with the best current treatment available, patients with heart failure still suffer from abnormally high nerve activity to the further detriment of this condition. The successful completion of this project will provide considerable insight into the role of the brain in the elevated nerve activity in heart failu ....Heart failure is a severely debilitating condition with a poor prognosis. It is characterized by retention of fluid and high nervous activity especially to the kidneys and the heart. Even with the best current treatment available, patients with heart failure still suffer from abnormally high nerve activity to the further detriment of this condition. The successful completion of this project will provide considerable insight into the role of the brain in the elevated nerve activity in heart failure. It will also provide us with a significant understanding of the role in reflex sympathetic nerve regulation of an important brain region known as the hypothalamic paraventricular nucleus (PVN). Our findings will help us understand the nature of the neurotransmitters contributing to the reflex nerve regulation and the specific neurons within the PVN involved. This knowledge could help us to identify novel potential therapeutic targets within the brain to alleviate the problems observed in heart failure.Read moreRead less
Fluid intake is essential for survival. Disorders of thirst whether they be excessive or inadequate have dire conseqences as evidenced in recent heat waves in Europe and Indiawhere thousands of lives were lost primarily in the elderly whose thirst mechanisms are often disrupted. The excessive fluid intake, seen in psychotic disorders such as schizophrenia, is equally damaging. Much of the research over the last 50 years has concentrated on the hypothalamic regulation of thirst. This project will ....Fluid intake is essential for survival. Disorders of thirst whether they be excessive or inadequate have dire conseqences as evidenced in recent heat waves in Europe and Indiawhere thousands of lives were lost primarily in the elderly whose thirst mechanisms are often disrupted. The excessive fluid intake, seen in psychotic disorders such as schizophrenia, is equally damaging. Much of the research over the last 50 years has concentrated on the hypothalamic regulation of thirst. This project will attempt, for the first time, to define the location in the cerebral cortex of the drive to ingest water (perception of thirst).Read moreRead less
Effects Of Increased Endolymph Volume On Cochlear And Vestibular Function And Morphology Of Inner Ear Tissues
Funder
National Health and Medical Research Council
Funding Amount
$313,391.00
Summary
Our recent research suggests that the vertigo attacks associated with enlarged fluid volumes in the inner ear, in diseases such as Ménière's Disease, maybe triggered when the fluid pressure forces open tissue valves located in the fluid-ducts connecting the hearing and balance organs. This project aims to identify the functional role of these valves, and to develop an animal model of abrupt changes in vestibular activity due to hydrops, to allow future treatments to be developed.
Promoting Intestinal Stem-cell Mediated Regeneration Following Damage: A Critical Role For Neuregulin 1
Funder
National Health and Medical Research Council
Funding Amount
$648,447.00
Summary
Diseases, infections and pathologies are common clinical problems of the intestine in humans that can lead to loss of intestinal tissue. Individuals with these conditions can experience nutritional problems and severe cases result in death. Promoting regeneration of the damaged tissue is critical to re-establish intestinal function. In this study, we will examine the regenerative potential of a growth factor called Neuregulin1 in the intestine with the aim of facilitating tissue regeneration.
Targeting Skeletal MTORC1 As A Novel Approach For The Treatment Of Diet-induced Insulin Resistance
Funder
National Health and Medical Research Council
Funding Amount
$586,979.00
Summary
Diet-induced insulin resistance is a pathology that underlies type 2 diabetes. Elucidating the pathways and tissues that contribute to this condition is crucial for drug development. The skeleton has emerged as a critical insulin target tissue. We provide evidence that suppression of mTORC1, a complex over-activated by nutrients, in bone cells improves insulin sensitivity. In this study, we will determine if blocking mTORC1 function in bone cells can treat diet-induced insulin resistance.