The Role Of Grb10 In The Regulation Of Muscle Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$624,960.00
Summary
Obesity increases the risk of metabolic diseases such as type 2 diabetes. Muscle is a key tissue for balancing whether energy is used or stored as fat and as we age, muscle mass normally decreases making maintaining a healthy metabolism even more difficult. We have discovered that removing the Grb10 gene from mice produces bigger muscles. This project will investigate the mechanisms of this effect so that strategies can be developed to regulate muscle mass and improve metabolic health
Identifying A Novel Role For Pigment Epithelium-derived Factor In Obesity-related Metabolic Dysfunction
Funder
National Health and Medical Research Council
Funding Amount
$361,637.00
Summary
Obesity is an important factor contributing to insulin resistance and type 2 diabetes; however, the factors linking these disorders are not well defined. A protein called PEDF is elevated in obesity and type 2 diabetes. This project will examine how PEDF causes insulin resistance and whether blocking PEDF's actions prevents insulin resistance. Successful completion of this project may lead to therapeutics that reduce the risk of developing type 2 diabetes.
Adrenergic Activation Of Brown Adipose Tissue In Humans.
Funder
National Health and Medical Research Council
Funding Amount
$323,301.00
Summary
Obesity is a major health and financial threat to society in the near future, thus new anti-obesity therapies are essential. Activation of brown adipose tissue (BAT) can increase resting energy expenditure by 20%, and its recent conclusive identification in adults renewed interest in its potential as an anti-obesity target. We will determine whether BAT can be activated pharmacologically in humans, whether obesity reduces its activity and if long-term drug treatment can increase BAT function.
In Vivo Tissue Engineering Of Adipose Tissue For Reconstructive Surgery
Funder
National Health and Medical Research Council
Funding Amount
$713,545.00
Summary
We are able to grow vascularised tissue in implanted plastic chambers to a predetermined size and shape in the rat and mouse (NHMRC Project Grant 01-03; #145782; CIA Morrison). The basis of this growth is blood vessel sprouting from the surface of the vessel bundle or loop, followed by synthesis of structural molecules and the migration of surrounding cells into the vascularised network to form a stable tissue. Unlike other in vivo models of tissue engineering, the tissue grows spontaneously and ....We are able to grow vascularised tissue in implanted plastic chambers to a predetermined size and shape in the rat and mouse (NHMRC Project Grant 01-03; #145782; CIA Morrison). The basis of this growth is blood vessel sprouting from the surface of the vessel bundle or loop, followed by synthesis of structural molecules and the migration of surrounding cells into the vascularised network to form a stable tissue. Unlike other in vivo models of tissue engineering, the tissue grows spontaneously and is densely vascularised, enabling continuous growth and surgically transfer to another part of the body, or to another animal. In this renewal application of the above NHMRC grant, we propose to direct these findings towards the development of vascularised fat tissue which would be ideal for reconstructive surgery as a stable, inert tissue filler. Our efforts to grow fat tissue in vivo to date have identified 4 major requirements: a fat precursor cell source; an instructive basement membrane matrix (which may include growth-differentiation factors); space into which the tissue can grow; a stable blood supply. We will focus here on optimising the precursor cell source and instructive matrix to generate vascularised fat tissue around the blood supply we can engender in our tissue engineering chamber. We have found Matrigel, a mouse tumor-derived matrix rich in basement membrane components, to be instructive for growing fat, and will also build on preliminary observations that either muscle or fat tissue can provide the appropriate precursor cells for this process. Finally we propose to adapt and upsize the vascularised fat tissue chamber to the pig, in a step towards human use, and assess its transplantability and longevity. The clinical application of our work is to produce breast reconstruction tissue and lipo filling for contour deformities resulting from trauma, congenital deformity, ageing and cancer surgery, particularly breast reconstruction.Read moreRead less