Derivation Of Pancreatic Beta Cells From Embryonic Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$2,968,050.00
Summary
People with type 1 diabetes require regular insulin injections because the organ that normally makes insulin, the pancreas, no longer functions. The goal of this program is to derive human fetal pancreas tissues from embryonic stem cells. Such tissue could be used to replace the missing insulin producing cells in people with type 1 diabetes. The program brings together expertise in ES cell biology at Monash University and the leading diabetes research at the Walter and Eliza Hall Institute.
Development of new systems for the commercial collection, processing and storage of adipose stem cells. This project is aimed at developing a standardised method to commercially extract and expand stem cells from adipose tissue. This product will then be available commercially as a therapeutic treatment.
The development of new scaffolds for bone repair comprising polycaprolactone and strontium-substituted bioactive glasses. The drive to develop bone grafts to fill major gaps in the skeleton, whilst circumventing the need to use permanent implants has led to a major research thrust towards developing biomaterials for bone-tissue engineering. The project will develop scaffolds with highly osteoconductive bioactive glasses in a polymer matrix for bone regeneration applications.
Potency and activity of Meso-Endothelial bipotent progenitors in vivo. This project aims to characterise a new stem cell population that can maintain both blood vessels and contribute to a variety of tissues whether fibrous, bone, fat or cartilage. Blood vessels comprise an inner endothelial layer and surrounding mesenchyme, are integral to many organs and constitute a unique system connecting different parts of the body. Despite their importance little is known about how they are maintained and ....Potency and activity of Meso-Endothelial bipotent progenitors in vivo. This project aims to characterise a new stem cell population that can maintain both blood vessels and contribute to a variety of tissues whether fibrous, bone, fat or cartilage. Blood vessels comprise an inner endothelial layer and surrounding mesenchyme, are integral to many organs and constitute a unique system connecting different parts of the body. Despite their importance little is known about how they are maintained and how they contribute to the response to injury. Previous work has described several populations of stem cell capable of self renewal and repletion of the endothelium or the mesenchyme. This project will examine the potency of these different progenitors to give rise to each of these fates in homeostasis but also during sounding and bone formation. This will help define a unique population of stem cells capable of both vascular and mesenchymal repair.Read moreRead less
Dissecting the physiology of multipotent mesenchymal stromal cells to develop vaccine candidates for respiratory disease. The project aims to gain an understanding of how a type of adult stem cell inhibits immune responses that cause asthma. The project will produce new stem cell products and facilitate the design of a vaccine for asthma and other respiratory diseases, which would greatly reduce the burden of such conditions.
Discovery Early Career Researcher Award - Grant ID: DE170100398
Funder
Australian Research Council
Funding Amount
$410,507.00
Summary
How T cells modulate stem cells and tissue regeneration. The project aims to determine how T cells modulate tissue repair and regeneration in mammals. Most of the mechanisms modulating the healing of tissues are elusive. This research is expected to reveal unknown mechanisms controlling the processes of tissue repair and regeneration, particularly the nexus between the stem cells involved in the tissue healing process and the immune response .
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100200
Funder
Australian Research Council
Funding Amount
$270,427.00
Summary
AutoStem: a high performance, automated stem cell bioengineering facility. This project aims to establish an automated stem cell bioengineering ("AutoStem") facility that will enable critical insights into the molecular mechanisms that underly the loss in stem cell function and tissue homeostasis as we age. The AutoStem facility expects to lead to the discovery of the key drivers of stem cell ageing and the development of novel technological solutions to maintain tissue function with age. The o ....AutoStem: a high performance, automated stem cell bioengineering facility. This project aims to establish an automated stem cell bioengineering ("AutoStem") facility that will enable critical insights into the molecular mechanisms that underly the loss in stem cell function and tissue homeostasis as we age. The AutoStem facility expects to lead to the discovery of the key drivers of stem cell ageing and the development of novel technological solutions to maintain tissue function with age. The outcomes produced from the AutoStem facility will have significant economic and social benefits in enabling healthy ageing and increased productivity for an ageing Australia.Read moreRead less
Understanding the cellular cues that direct muscle stem cell specification. The project aims are to identify the metabolic factors that regulate muscle stem cell identity and to examine how changes in the local metabolic environment can influence how stem cells respond to biological perturbations. One of the most important and unresolved issues in skeletal muscle biology is understanding the role of muscle stem cells in the regulation of growth and development, adaptation and plasticity. We have ....Understanding the cellular cues that direct muscle stem cell specification. The project aims are to identify the metabolic factors that regulate muscle stem cell identity and to examine how changes in the local metabolic environment can influence how stem cells respond to biological perturbations. One of the most important and unresolved issues in skeletal muscle biology is understanding the role of muscle stem cells in the regulation of growth and development, adaptation and plasticity. We have identified that the local skeletal muscle metabolic milieu may regulate the activity of skeletal muscle stem cells. This project could reveal novel mechanisms by which skeletal muscle stem cells can be regulated. This information is crucial for our fundamental understanding of stem cell biology and its future applications.Read moreRead less
Generating multi-component scaffolding to influence the differentiation of embryonic stem cells. Nervous system diseases are debilitating and will develop in over 50 per cent of people at some time in their life. This project will develop strategies so that stem cells can be utilised to encourage brain repair for the treatment of Parkinson's disease. The technology developed will also be of benefit for the treatment of other nervous system disorders.
Industrial Transformation Training Centres - Grant ID: IC190100026
Funder
Australian Research Council
Funding Amount
$4,969,663.00
Summary
ARC Training Centre for Cell and Tissue Engineering Technologies. The ARC Training Centre for Cell and Tissue Engineering Technologies aims to provide training to create a highly skilled workforce for the tissue engineering and regenerative medicine sector and to enhance research performance and innovation in Australia through fundamental and applied research carried out in industry-led PhD projects. The research aims to address major aspects of the manufacturing and commercialisation pathway an ....ARC Training Centre for Cell and Tissue Engineering Technologies. The ARC Training Centre for Cell and Tissue Engineering Technologies aims to provide training to create a highly skilled workforce for the tissue engineering and regenerative medicine sector and to enhance research performance and innovation in Australia through fundamental and applied research carried out in industry-led PhD projects. The research aims to address major aspects of the manufacturing and commercialisation pathway and barriers faced by the sector, namely improving process efficiencies, enabling early-stage scale-up (cell/tissue) and development of the sector's supply chain. The knowledge created and research undertaken would help to accelerate commercialisation in regenerative medicine, tissue engineering and cell therapies.Read moreRead less