Optimising Islet Transplantation With Vascularized Tissue Engineering Chambers
Funder
National Health and Medical Research Council
Funding Amount
$451,651.00
Summary
Diabetics have high blood sugar levels because cells in the pancreas known as islets produce too little of the hormone insulin. Most diabetics need daily insulin injections to maintain normal blood sugar levels. Transplanting islets is the most promising way to treat type 1 diabetes, but, apart from the obvious difficulty of rejection of foreign islets, several major problems remain: (1) there are insufficient pancreata (and therefore islets) for transplantation; and (2) the efficiency of delive ....Diabetics have high blood sugar levels because cells in the pancreas known as islets produce too little of the hormone insulin. Most diabetics need daily insulin injections to maintain normal blood sugar levels. Transplanting islets is the most promising way to treat type 1 diabetes, but, apart from the obvious difficulty of rejection of foreign islets, several major problems remain: (1) there are insufficient pancreata (and therefore islets) for transplantation; and (2) the efficiency of delivery of surviving islet transplants is too low. In pilot studies we have grown a new living pancreatic organ in mice by inserting islets from genetically-related mice together with a structural protein matrix, growth factors and blood vessels inside a plastic chamber. The blood vessels maintain nutrition to the islet cells and simultaneously allow insulin to be released into the bloodstream, thus normalising the high blood sugar in diabetics. In Aim 1 of these experiments we will find the optimal way to grow mature islets in blood vessel-containing chambers in diabetic mice, focusing on (a) the best time to add islets to the chamber - 0, 1 or 2 weeks after establishment, (b) the minimum number of islets to effectively normalise blood sugar and (c) how long we can keep islets alive and functional in chambers, examining periods up to 12 months. In Aim 2 we will test the ability of islet stem cells (provided by our co-investigators at Walter and Eliza Hall Institute, Melbourne) to survive in the chambers and to produce sufficient insulin to effectively lower blood sugar levels to normal in diabetic mice. In Aim 3 we will grow human islets in chambers in special diabetic mice that do not reject foreign tissue, in order to confirm similar behaviour of human islets in this controlled environment. Using this data, we hope to create a research model of functioning islets, that is accessible, retrievable and manipulable, for the further study of diabetes and transplantation.Read moreRead less
Mechanisms Of CD44v2-10-mediated Tumour Metastasis.
Funder
National Health and Medical Research Council
Funding Amount
$441,000.00
Summary
Cancer metastasis remains the principal cause of treatment failure in malignant disease. Current therapies for metastases are generally non-specific, and can cause considerable systemic toxicity. The ideal target for metastasis therapy would be expressed by a broad range of tumours, but be restricted in expression in normal tissues. CD44 is a family of widely expressed cell-surface adhesion molecules and its members are implicated in a variety of physiological and pathological processes, includi ....Cancer metastasis remains the principal cause of treatment failure in malignant disease. Current therapies for metastases are generally non-specific, and can cause considerable systemic toxicity. The ideal target for metastasis therapy would be expressed by a broad range of tumours, but be restricted in expression in normal tissues. CD44 is a family of widely expressed cell-surface adhesion molecules and its members are implicated in a variety of physiological and pathological processes, including tumour progression and metastasis. CD44 has considerable molecular diversity and its broad range of known biological activities suggests that multiple domains in the molecule may confer different biological functions. The core CD44 molecule, termed CD44s, is the most commonly expressed CD44 molecule. CD44 variants (termed CD44v) are much more restricted in their expression in normal tissues, and hence may make specific targets for anti-metastasis therapy. We have shown that CD44 variants are expressed by colorectal tumours from the earliest stages of tumour development, and that theses variants are found to be expressed by colorectal hepatic metastases. We targeted two key domains in the variants and found that by inhibiting expression in these domains we showed complete abrogation of metastasis, and of primary tumour growth in mice. Hence these domains in the CD44 molecule are directly involved in cancer spread. We propose to investigate the mechanisms by which specificdomains in the CD44 variants actually cause tumour spread. Understanding of the various mechanisms involved in tumour spread, and targeting the functions of the domains has enormous potential as a therapeutic target.Read moreRead less
Improved Ex-vivo Culture Of Keratinocytes For Clinical Applications
Funder
National Health and Medical Research Council
Funding Amount
$275,203.00
Summary
Skin cells grown for clinical applications currently require animal-derived cells and-or non-defined products for their expansion in the laboratory; these reagents can potentially infect patients who receive these therapies. This project will identify the essential components provided by these reagents and develop a fully synthetic and defined culture system. This improvement will provide safer, cost-effective grafts and cell-based therapies that will benefit patients suffering burns and wounds.
Optimizing Implanted Cell Survival Using A Tissue Engineering Model
Funder
National Health and Medical Research Council
Funding Amount
$589,175.00
Summary
Cell therapy and tissue engineering involve the insertion of specific cells into damaged tissues or into a bioraector in a patient's body to generate new replacement tissues. This project seeks to improve two factors associated with inserting cells : 1. The innate survival characteristics of the cells being inserted, and 2. The blood vessel supply at the site of insertion. These techniques will greatly improve the survival of inserted cells.
Evaluation A Novel Vitronectin:growth Factor Complex For Treatment Of Chronic Venous Leg Ulcers
Funder
National Health and Medical Research Council
Funding Amount
$854,975.00
Summary
Chronic leg ulcers in the elderly are an important problem, diminshing quality of life and costing at least A$1 billion per year. New treatments are urgently required. This study will test a new topical growth factor therapy designed to have greatly improved activity in wounds.The project is a collaboration between scientists and doctors at the Queensland Univeristy of Technology and the University of Western Australia. Many wound types may ultimately benefit from this treatment.