Monitoring Bone Loss And Response To Therapy Through Bone Material And Structural Composition
Funder
National Health and Medical Research Council
Funding Amount
$696,111.00
Summary
Millions of scripts are filled for treatment of osteoporosis. However, there is no way of knowing if these drugs are right for these individuals, if it improves bone strength or are actually doing harm. Bone density measurement is of limited value. We have developed a new analysis method that measures changes in bone structure that tell us if the treatment is or is not working so alternative treatment can be used. The aim of this study is to test this new method.
Prediction Of Adverse Outcomes Following A Fragility Fracture
Funder
National Health and Medical Research Council
Funding Amount
$148,426.00
Summary
Individuals with an existing fracture are at increased risk of adverse outcomes such as re-fracture and premature mortality, but it is not clear why. We propose to evaluate risk factors, and prognostic models, for predicting the risk of adverse outcomes. We also propose to develop a quantitative risk-benefit framework for evaluating the clinical utility of such prognostic models and help ensure that therapies appropriately address real-life experience of osteoporotic patients.
Identifying Novel Susceptibility Loci For Osteoporosis Through Whole Genome Sequencing
Funder
National Health and Medical Research Council
Funding Amount
$623,969.00
Summary
Our highly successful genome-wide studies of bone mineral density (a risk factor for osteoporosis) have highlighted 60 loci relevant to the disease. However, a substantial amount of genetic variance remains unexplained. This project will focus on less common variants that have larger effect sizes and are relevant to osteoporosis, but are not well studied by approaches such as high-density SNP arrays and genome-wide association studies.
Long-term Effects Of Very Low Energy Diet Versus Conventional Diet On Adiposity, Lean Body Mass, Muscle Strength And Bone Density In Obese Adults, And Mechanisms Promoting Changes
Funder
National Health and Medical Research Council
Funding Amount
$925,990.00
Summary
Very low energy diets (VLEDs) are increasingly used to treat obesity. Of concern is the fact that VLEDs induce adaptive responses that can inhibit loss of – and promote regain of – fatness (particularly belly fat) while decreasing lean body mass, muscle strength and bone density. This project will therefore determine whether VLEDs could have negative effects on body composition that increase the risk of metabolic disease, sarcopenia or osteoporosis, and if so, what are the mechanisms involved.
Osteoporosis is the commonest metabolic bone disease worldwide, and costs Australia >1% of GDP. It is a strongly inherited disease. We recently completed a genome-wide association study in 2000 postmenopausal women with either very high or very low bone density, and identified many genes contributing to BMD. The current study aims to use next-generation sequencing to study these women in greater genetic depth, aiming to identify more clearly the exact genetic determinants of bone mass.
Bisphosphonate Therapy With Zoledronate Or Tenofovir Switching To Improve Low Bone Mineral Density In HIV-Infected Adults: A Strategic, Randomised Trial
Funder
National Health and Medical Research Council
Funding Amount
$716,300.00
Summary
Most HIV+ Australians receive tenofovir, a ‘preferred’ drug in all HIV treatment guidelines, and may do for decades, as HIV therapy is lifelong and because there are very few new HIV drugs. 40% of HIV+ adults have low bone density and HIV+ adults experience more fractures. Of all HIV drugs, tenofovir causes the most bone loss. This trial compares two approaches: a drug to improve bone density and switching tenofovir to another drug. This ‘treat versus switch’ approach is a world-first for HIV.
Identification Of Novel PTH Anabolic Targets In Osteoblasts
Funder
National Health and Medical Research Council
Funding Amount
$547,216.00
Summary
Osteoporosis is a major disease affecting Australians. Whilst there are a number of drugs available that will reduce bone loss, there are few drugs available that build new bone, and little is known of the action of these drugs. New targets have been identified that modulate bone formation, and this project aims to validate these in appropriate models and determine their mechanism of action.
Optimising Bone Regeneration Using Advanced Design And Fabrication Technologies
Funder
National Health and Medical Research Council
Funding Amount
$916,671.00
Summary
The aging population has produced a rapidly increasing demand for synthetic implants that can regenerate lost or diseased bone. This project will produce an implant that represents a viable alternative to bone autografts and allografts with broad applications for the repair of large or challenging bone defects. Such an achievement will have significant healthcare benefits by reducing patient morbidity and recovery time, and improving long-term outcomes.
Determining The Influences Of Cell Stress And Heat Shock Factor-1 Action In Osteoclast Formation And Pathological Bone Loss.
Funder
National Health and Medical Research Council
Funding Amount
$657,287.00
Summary
Cancer and rheumatoid arthritis cause painful bone destruction. This occurs due to increased numbers of bone destroying cells called osteoclasts. We found stress responses in bone cells can increase osteoclast numbers by activating proteins inside the bone cells that encourage osteoclasts to form. We will thus study whether cell stress blocking drugs might stop bone loss. As arthritis and cancer both cause stress responses, this work could identify a new way that such diseases affect bone.
Sclerostin: A Key Regulator Of Bone Mineralisation And Bone Catabolism
Funder
National Health and Medical Research Council
Funding Amount
$536,653.00
Summary
The regulation of bone mass is critical for many areas of human disease including osteoporosis, osteoarthritis, inflammatory bone loss conditions, e.g. rheumatoid arthritis, cancers of bone and problems relating to orthopaedic prosthesis failure. The osteocyte, the most abundant bone cell, plays a central role in normal bone biology and is likely key to these diseases. Sclerostin is one osteocyte product that may be a key to understanding how boneÍs mass and composition is controlled locally.