Hypothalamic Signalling In Cortical And Trabecular Bone Anabolic Activity
Funder
National Health and Medical Research Council
Funding Amount
$472,770.00
Summary
Osteoporosis is a disease associated with an exponential rise in the number of fractures in the elderly. These fractures are so common that around 1 in 3 women and 1in four men will be affected. They cause pain, disability that can be permanent disability and are associated with premature death. Current treatments are able to effectively increase bone strength in osteoporotic patients but can not return bone strength to normal. Some new treatments can restore bone strength to some extent but the ....Osteoporosis is a disease associated with an exponential rise in the number of fractures in the elderly. These fractures are so common that around 1 in 3 women and 1in four men will be affected. They cause pain, disability that can be permanent disability and are associated with premature death. Current treatments are able to effectively increase bone strength in osteoporotic patients but can not return bone strength to normal. Some new treatments can restore bone strength to some extent but these are limited by expense and safety concerns. We have discovered a pathway in the brain that reduces bone formation and by blocking this pathway we can achieve doubling of the amount of bone in key bone sites. This occurs due to a marked increase in the amount of new bone formed. In fact, genetic manipulation of this pathway was able to double the speed at which bone is made by the skeleton. Excitingly, these increases in bone were possible in adult mice, suggesting such changes could be potential therapy for human patients. However, in order to be able to harness this pathway we must understand what molecules within the brain are responsible for the signals that reach the bone. Our proposal aims to identify the nerve signalling molecule(s) and the receptor for these signals within the brain that initiates the increase in bone formation. This project ultimately aims to identify a target for new therapies that could cause this beneficial effect by administration of a simple treatment, preferably by mouth in adult humans.Read moreRead less
Influence Of Osteocytes On Anabolic Bone Therapies
Funder
National Health and Medical Research Council
Funding Amount
$586,965.00
Summary
This project seeks to define the influence of changes in gene expression in cells called osteocytes, that exist within the substance of bone. These cells form a communication network within the bones of the skeleton, and appear to influence bone formation; changes in gene expression by these cells could influence the efficacy of current and emerging osteoporosis therapies.
The Therapeutic Value Of Targeting Wnt Signalling For The Treatment Of Osteoarthritis
Funder
National Health and Medical Research Council
Funding Amount
$561,535.00
Summary
Osteoarthritis (OA) affects 1.62 million Australians and imposes a significant burden on healthcare. It is characterised by damage to joint cartilage, and increased bone formation with formation of bone spurs. Our studies will determine the importance of the Wnt signalling pathway in mediating OA joint degeneration and identify mechanisms that regulate the activation of this pathway in OA. This will inform the development of novel therapeutic strategies which could halt joint damage in OA.
Relationships Between Human Osteoblasts And Haemopoietic Cells In Bone Remodelling
Funder
National Health and Medical Research Council
Funding Amount
$436,450.00
Summary
Bone diseases, such as osteoporosis and osteoarthritis, currently afflict more than 4 million Australians. These diseases are characterised by abnormal bone remodelling, which can result in a net loss of bone (for example, in osteoporosis) or abnormal bone structure (for example, in osteoarthritis). We are seeking to better understand the factors that regulate bone remodelling, and particularly the cells involved in this process. Physiological bone remodelling results from the intimate collabora ....Bone diseases, such as osteoporosis and osteoarthritis, currently afflict more than 4 million Australians. These diseases are characterised by abnormal bone remodelling, which can result in a net loss of bone (for example, in osteoporosis) or abnormal bone structure (for example, in osteoarthritis). We are seeking to better understand the factors that regulate bone remodelling, and particularly the cells involved in this process. Physiological bone remodelling results from the intimate collaboration between osteoblasts and osteoclasts. Osteoblasts stimulate the formation of osteoclasts and also produce new bone at resporption sites. However, the way that the same type of cell can perform both these tasks, is not clear. Our studies are designed to increase our understanding of the development of human osteoblasts and of the factors that cause them to be sequentially pro-osteoclastic and then pro-osteogenic. We believe that an important factor in this process is vitamin D and we will test the hypothesis that this molecule is produced in bone and acts locally to regulate bone turnover.Read moreRead less
The Molecular Mechanisms Controlling Maintenance Of Osteogenic Precursor Cells And Skeletal Tissue Regeneration
Funder
National Health and Medical Research Council
Funding Amount
$234,750.00
Summary
Within human bone marrow there exists a rare population of bone marrow stromal stem cells (BMSSCs) able to develop into the different cell types that form haematopoietic supportive stroma and surrounding skeletal tissue. There has been alot of interest of late in the potential of BMSSCs as a cellular based therapy to treat and manage bone fractures or bone loss caused by disease. Increasing evidence suggests that decreased bone mass due to osteoporosis dos not purely result in an increase of bon ....Within human bone marrow there exists a rare population of bone marrow stromal stem cells (BMSSCs) able to develop into the different cell types that form haematopoietic supportive stroma and surrounding skeletal tissue. There has been alot of interest of late in the potential of BMSSCs as a cellular based therapy to treat and manage bone fractures or bone loss caused by disease. Increasing evidence suggests that decreased bone mass due to osteoporosis dos not purely result in an increase of bone resorption by osteoclasts, but may also occur through a decline in the number of bone forming cells called osteoblasts or their progenitors. Fracture non-union, prosthetic loosening and the replacement of large defects in bone are common and difficult problems. The use of autologous bone cells generated from isolated BMSSCs in combination with bio-compatible implant materials would provide a novel solution for the treatment of these problems, avoiding the use of autografts and allografts of bone with all their associated difficulties. However, large numbers of ex vivo expanded BMSSCs are currently required to heal even small bone defects in animal models. This is compounded by the decline in proliferation rates and bone forming capacity of BMSSCs during prolonged expansion in culture. An improved understanding of the genes that regulate the proliferation and differentiation of BMSSCs in vitro is therefore an essential prerequisite for the effective management of bone fracture and bone loss. We propose to genetically manipulate the expression of genes in BMSSCs, that are known to regulate cellular growth and development inorder to maintain the growth of stem cell populations in vitro and to extend their capacity to form bone when transplanted in vivo.Read moreRead less
Osteoporosis is a disease associated with a progressive rise in the number of fractures in the elderly. These fractures are so common that around 1 in 3 women and 1in 4 men will be affected. They cause pain, disability that can be permanent and are associated with loss of independence even premature death. Current treatments are able to partially restore bone strength in osteoporotic patients but can not return bone strength to normal. Some new treatments can restore bone strength to some extent ....Osteoporosis is a disease associated with a progressive rise in the number of fractures in the elderly. These fractures are so common that around 1 in 3 women and 1in 4 men will be affected. They cause pain, disability that can be permanent and are associated with loss of independence even premature death. Current treatments are able to partially restore bone strength in osteoporotic patients but can not return bone strength to normal. Some new treatments can restore bone strength to some extent but these are limited by expense and safety concerns. We have discovered a pathway in the brain that when blocked, results in a doubling of the amount of bone in key bone sites and dramatic increases in bone strength. This occurs due to a marked increase in the amount of new bone formed. In fact, genetic manipulation of this pathway was able to double the speed at which bone is made by the skeleton. Excitingly, these increases in bone were possible in adult mice, suggesting such changes could be potential therapy for human patients. We went on to test the effectiveness of this pathway in animal models of human skeletal weakness and have shown that it is capable of remarkable benefits. However, in order to be able to harness this pathway we must understand what molecules within the bone that are responding to the signals from the brain. Our proposal aims to identify the nerve signalling molecule(s) and pathways for these signals within the bone that initiate the increase in bone formation. This project ultimately aims to identify a target for new therapies that could achieve this beneficial effect by administration in osteoporotic women and menRead moreRead less
Interaction Between PTH And Y2 Bone Anabolic Pathways
Funder
National Health and Medical Research Council
Funding Amount
$731,311.00
Summary
Osteoporosis is a costly condition that affects more than 150 million people worldwide and fills more hospital beds than any other disease*. People who have osteoporotic fractures experience a diminished quality of life and a reduced life expectancy. Although there are currently a number of therapies in use to reduce further loss of bone in osteoporotic patients, there is only one to replace lost bone, parathyroid hormone. For clinical and economic reasons, there is a need for additional bone-bu ....Osteoporosis is a costly condition that affects more than 150 million people worldwide and fills more hospital beds than any other disease*. People who have osteoporotic fractures experience a diminished quality of life and a reduced life expectancy. Although there are currently a number of therapies in use to reduce further loss of bone in osteoporotic patients, there is only one to replace lost bone, parathyroid hormone. For clinical and economic reasons, there is a need for additional bone-building therapies. Like all tissues, the nervous system affects skeletal function. We recently discovered a powerful control pathway by which the nervous system regulates bone formation. This project will test whether altering the function of this neural pathway can increase bone formation and whether it can work together with parathyroid hormone therapy to produce an enhanced bone formation response greater than either therapy alone. This research is important because of the need for new osteoporosis therapies to repair weakened bones. The knowledge gained from this study has the potential to provide a very important and useful contribution to skeletal health and thus aged health worldwide. *The Burden of Brittle Bones: Costing Osteoporosis in Australia. A report prepared by Access Economics Pty. Ltd. September 2001Read moreRead less
Nutrient Dependent Signalling In Bone Via Calcium Sensing Receptors
Funder
National Health and Medical Research Council
Funding Amount
$226,650.00
Summary
Osteoporosis is a major health problem that affects as many as 10% of the Australian Community and costs the health budget millions of dollars each year. A number of key nutritional factors including calcium and dietary protein intake are known to be important in the development of osteoporosis. This proposal will test the hypothesis that human bone cells express a protein which senses calcium and amino acids, the calcium-sensing receptor, and thereby respond to nuritional signals arising from t ....Osteoporosis is a major health problem that affects as many as 10% of the Australian Community and costs the health budget millions of dollars each year. A number of key nutritional factors including calcium and dietary protein intake are known to be important in the development of osteoporosis. This proposal will test the hypothesis that human bone cells express a protein which senses calcium and amino acids, the calcium-sensing receptor, and thereby respond to nuritional signals arising from the presence of calcium ions and amino acids in plasma. Furthermore, we propose that by promoting osteoblast proliferation, maturation and survival, the calcium sensing receptor acts as the key molecular mechanism by which dietary calcium and protein promotes bone formation.These studies have potential to explain relationships between bpne resorptive activity, which raises local calcium concentrations, and bone formation activity and the coupling of bone forming and resorbing activity. These studies have the potential to explain the positive effects of calcium and protein intake on bone mass and may also shed light on the regulation of the coupling between osteoblastic and osteoclastic activityRead moreRead less
The Role Of TWIST Family Basic Helix-Loop-Helix Transcription Factors In Bone Cell Commitment, Function And Repair
Funder
National Health and Medical Research Council
Funding Amount
$485,928.00
Summary
In developed countries, projected estimates predict an alarming trend of a two to three fold increase in the number of fractures that require surgical intervention and rehabilitation therapy in the coming decades as a consequence of an aging population. Fracture healing is a complex physiological process that involves the coordinated participation of different bone marrow cells, immune cells and skeletal progenitor cells. Multiple factors regulate interactions between these cell types that influ ....In developed countries, projected estimates predict an alarming trend of a two to three fold increase in the number of fractures that require surgical intervention and rehabilitation therapy in the coming decades as a consequence of an aging population. Fracture healing is a complex physiological process that involves the coordinated participation of different bone marrow cells, immune cells and skeletal progenitor cells. Multiple factors regulate interactions between these cell types that influence the capacity of bone cell progenitors to develop into functional bone forming cells known as osteoblasts. An understanding of the fracture healing is critical for the future advancement of fracture treatment, and for identifying the mechanisms of skeletal growth and repair as well as the causes of aging and disease. This proposal seeks to identify critical regulatory molecules that act to mediate bone cell progenitor recruitment and development during bone fracture repair.Read moreRead less
Is Periosteal Bone Formation Responsible For Sexual Dimorphism In Bone Fragility
Funder
National Health and Medical Research Council
Funding Amount
$316,320.00
Summary
Men and women sustain fractures as they age because their bones become fragile. Women sustain fractures more often than men. Bone thinning occurs in both sexes but it is usually believed that this thinning or loss of bone is greater in women than men. We have evidence to suggest that this may not be correct. In fact, it is likely that men and women lose a similar amount of bone, about half what they started with, but during ageing, men lay down more bone on the outside surface of the bone than w ....Men and women sustain fractures as they age because their bones become fragile. Women sustain fractures more often than men. Bone thinning occurs in both sexes but it is usually believed that this thinning or loss of bone is greater in women than men. We have evidence to suggest that this may not be correct. In fact, it is likely that men and women lose a similar amount of bone, about half what they started with, but during ageing, men lay down more bone on the outside surface of the bone than women compensating for the similar amount lost on the inside of the bone. We also have evidence to suggest than men and women who get spine fractures do so because the process of laying down bone may fail to occur normally. We will study these processes of bone loss inside the bone and bone gain outside the bone to try to better understand why bones become weak. We will measure the bone size and its density in healthy men and women and patients with fractures to determine how the increasing size of the bone produced by laying down bone on its outside helps to keep it strong and to preserve the bone that would otherwise be lost if it didn't occur or if a disease developed that might reduce the compensatoryRead moreRead less