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Gastrointestinal Function And Appetite In Obesity - Acute And Longer-term Effects Of Changes In Energy Intake
Funder
National Health and Medical Research Council
Funding Amount
$744,645.00
Summary
The prevalence of obesity is assuming epidemic proportions. While weight loss diets help people to lose weight, body weight stabilises over time despite continued dieting. Our research proposal represents a novel initiative with the aim to understand the adaptations in gastrointestinal mechanisms in response to acute and longer-term dietary restriction that compromise weight loss. Ultimately our research will help to develop weight loss strategies that are successful in the long-term.
Effects Of The Fatty Acid, Lauric Acid, On Energy Intake And Gut Motor And Hormonal Function In Health And Obesity
Funder
National Health and Medical Research Council
Funding Amount
$744,645.00
Summary
Obesity is largely due to energy intake exceeding energy expenditure, thus, strategies that reduce energy intake will result in weight loss. We discovered recently that the fatty acid, lauric acid, markedly reduces energy intake. Our studies will determine the effects of lauric acid on energy intake and body weight reduction in obese subjects. The research is a new initiative and explores the potential of lauric acid as a novel, nutrient-based and side-effect free approach to obesity management.
Effects Of Dietary Protein On Gastrointestinal Function: Implications For The Regulation Of Energy Intake In Obesity
Funder
National Health and Medical Research Council
Funding Amount
$677,157.00
Summary
Obesity is largely due to energy intake exceeding energy expenditure. The CI has reported that dietary protein markedly reduces energy intake but the mechanisms underlying this effect remain unknown. The proposed studies will determine whether gastrointestinal mechanisms are involved in the regulation of appetite and energy intake and how they relate to body weight reduction in obese subjects. The research represents a unique approach to the management of obesity and health.
Mechanisms Of Cortical Plasticity And Facilitation Of Functional Recovery Following Stroke
Funder
National Health and Medical Research Council
Funding Amount
$427,500.00
Summary
Specific regions of the human brain have been shown to reorganise following damage to the brain or peripheral nerves. This reorganisation is seen in both young and older subjects and is thought to be useful in helping to restore function. For example, following a stroke a patient may, initially, be unable to move one arm. However, in the following weeks and months some function may return. A number of mechanisms may be responsible for this improvement. However, it is likely that at least some of ....Specific regions of the human brain have been shown to reorganise following damage to the brain or peripheral nerves. This reorganisation is seen in both young and older subjects and is thought to be useful in helping to restore function. For example, following a stroke a patient may, initially, be unable to move one arm. However, in the following weeks and months some function may return. A number of mechanisms may be responsible for this improvement. However, it is likely that at least some of the improvement is due to reorganisation within the sensorimotor cortex. Following the stroke the control of the arm may be taken over by adjacent undamaged regions of the brain. This reorganisation allows impressive functional recoveries to occur. We have preliminary evidence to support the idea that patterns of activity generated in peripheral nerves (afferent input) following stroke may be crucial for the development of the organisational changes seen within the brain. We have shown that by applying specific patterns of sensory input we are able to produce organisational changes within the motor cortex of control subjects. Also, we have been able to induce similar changes in stroke patients. These changes have been accompanied by improvements in motor control. These novel and exciting findings support our hypothesis that by applying certain patterns of afferent input to patients following stroke we will be able to facilitate functional recovery by maximising reoganisation within the cortex. In the present project we will establish the organisation patterns in the brain of stroke patients and contrast the findings with control subjects. Secondly we will investigate the potential for facilitating recovery of stroke patients by the application of specific patterns of afferent input. These novel experiments may lead to important therapeutic developments that will benefit the large population of patients suffering strokes.Read moreRead less
This project will test the proposal that rising follicle-stimulating hormone (FSH) levels in ageing females directly accelerate reproductive failure and bone loss , major public health issues due to delayed childbearing and our rising ageing population. We have developed a unique mouse model with elevated FSH levels that cause premature female infertility. We will now use this model to determine the direct effects of high FSH upon ovarian and uterine function, as well as bone loss with age.
Understanding The Human Hand In Grasping And How This Changes After Stroke
Funder
National Health and Medical Research Council
Funding Amount
$227,855.00
Summary
The hand allows remarkable feats of dexterity. But, paralysis of the hand severely limits daily activities and is common after stroke. We will determine key mechanisms that control the hand at the level of the brain and spinal cord. We will assess some limits that develop in the muscle itself. Stroke patients will be tested so that we can better understand the brain�s control of the hand and use this to enhance recovery of hand performance in those with impaired function.
Pain changes movement. Although undisputed, there is a surprising lack of agreement regarding the underlying mechanisms. This project involves an innovative mix of neurophysiological methods to investigate the drive to muscle cells from the nervous system and changes in the mechanics of contraction. These studies will resolve the perplexing problem of how pain changes our ability to activate muscle. Clear understanding of the underlying mechanisms can guide rehabilitation.
Mechanisms Of Mechanotransduction In Primary Visceral Afferents
Funder
National Health and Medical Research Council
Funding Amount
$253,500.00
Summary
Mechanotransduction is the process whereby mechanical stimuli are converted into signals in sensory nerves. This forms the basis of touch, hearing, position sense and many aspects of internal perception. It also constitutes a major component of pain. Our group aims to discover the molecular basis of mechanotransduction in mammals, and in particular how it relates to signaling of events in the digestive system. We and our collaborators have been among the first to explore this question, and have ....Mechanotransduction is the process whereby mechanical stimuli are converted into signals in sensory nerves. This forms the basis of touch, hearing, position sense and many aspects of internal perception. It also constitutes a major component of pain. Our group aims to discover the molecular basis of mechanotransduction in mammals, and in particular how it relates to signaling of events in the digestive system. We and our collaborators have been among the first to explore this question, and have found that three genes are responsible for many aspects of mechanotransduction. Each gene is transcribed to produce a channel or pore in the membrane of sensory nerve fibres which responds to mechanical forces by allowing ions to enter and induce electrical signals. Our early findings in mice with disruption of individual genes indicate that a complex positive and negative interaction of these channels must underlie normal mechanotransduction. However, these channels must represent only a part of the transduction mechanism, with extracellular and intracellular anchors inevitably playing a major role. The identity of such anchoring proteins in mammals is currently emerging, and we are fortunate to have access to mice deficient in specific genes that will provide information about candidates for this role. Through our studies on mechanotransduction in the digestive system in parallel with our collaborators' studies on mechanotransduction in skin we shall not only identify the fundamental mechanisms of mammalian mechanotransduction, but also reveal which components of mechanotransducers are peculiar to the gut. Such peculiarities provide molecular targets for therapy of diseases in which alteration of mechanosensory signaling is itself an aim.Read moreRead less