HARNESSING THE PHYSIOLOGICAL EFFECTS OF STRONTIUM AND ZINC TO PRODUCE NOVEL BIOMATERIALS FOR ORTHOPAEDIC APPLICATIONS
Funder
National Health and Medical Research Council
Funding Amount
$560,082.00
Summary
Large skeletal defects resulting from congenital defects or disease processes are challenging to regenerate and represent a major financial burden to our health system. Bone graft treatments are widely used but have considerable drawbacks. Available synthetic alternatives lack the physical-biological properties necessary. We have developed new scaffolds with improved mechanical-biological properties for bone regeneration.
Mechanisms Of Bone Formation At The Device/tissue Interface: Role Of Biomaterial Surface Chemistry Modification
Funder
National Health and Medical Research Council
Funding Amount
$489,375.00
Summary
In 1992 300,000 prosthetic devices, artificial hips and knees were implanted into patients in a global market worth $2.1 billion. Growth in this field of medicine has been exceptional with now more than 1 million implants carried out each year. In 1998-99, 38,512 artificial hips and knees were implanted in Australia alone, with approximately 10% of these replacing older, failed implants. Since joint replacements provide great benefits for the patient considerable health funding is required for j ....In 1992 300,000 prosthetic devices, artificial hips and knees were implanted into patients in a global market worth $2.1 billion. Growth in this field of medicine has been exceptional with now more than 1 million implants carried out each year. In 1998-99, 38,512 artificial hips and knees were implanted in Australia alone, with approximately 10% of these replacing older, failed implants. Since joint replacements provide great benefits for the patient considerable health funding is required for joint replacements. However, failure of the implants is a major concern to the patient and financially to our health system, especially with the ever increasing life expectancy of our population. The long-and short-term success of an implant depends on the healthy support of the surrounding bone. This study aims to find ways of improving the attachment of healthy bone to the implant by modifying the surface characteristics of the implant. We will modify the surface chemistry of biomaterials with divalent cations, such as magnesium, which is known to play a critical role in bone remodelling and skeletal development. Our goal is to improve the formation of healthy bone that will promote a rapid and permanent fixation of implant into skeletons. This study goes further to study the factors, inside the cell, on the cell surface and secreted by the cell, which promote this attachment. Once these factors are identified, it should be possible to alter implant surfaces in ways to improve stability. In this proposal we will use novel bioceramic coatings and ion beam technologies. This study will not only improve our understanding of the interactions of bone and implant but also identify ways of improving implants to benefit the patient's quality of life and reduce costs in this important heath areaRead moreRead less
At present the failure rate of joint replacement is unacceptably high and will continue to rise due to the ageing and active life styles of the baby-boomer generation, placing an increasing burden on the health budget. We have developed a new bioactive material with improved mechanical-biological properties for bone regeneration. We will modify the surface of the currently used orthopaedic implants with this bioactive material to promote permanent fixation of the prosthesis to the bone.
Application Of Novel Sutureless Technology For Eye Surgery
Funder
National Health and Medical Research Council
Funding Amount
$342,623.00
Summary
Corneal disease and trauma are major causes of blindness. Corneal trauma requires surgical repair and vision lost from disease may be restored with corneal transplantation. In both cases sutures are used and can have significant complications. Application of a new surgical adhesive for cost-effective, quick and easy corneal surgery with enhanced wound healing is an innovative solution to a major problem in public health with manifold implications in the field of eye surgery
Peptides Bound To Commonly Used Orthopaedic And Dental Biomaterials:In Vitro And In Vivo Effect On Osteogenesis.
Funder
National Health and Medical Research Council
Funding Amount
$273,428.00
Summary
In 1992, the orthopaedics industry fitted some 300,000 prosthetic devices, artificial hips, knees, giving this industry a global market of $2.1 billion with a projected market growth exceeding 10% per annum. In (1994-5) 5,717 prosthetic hips and 4,593 knees were surgically implanted in NSW of which 14% of hips and 9.5% of knees were revisions. Considerable health funding is allocated to joint replacement for the nation, although successful, outcomes are finite. Importantly, and aside from costs, ....In 1992, the orthopaedics industry fitted some 300,000 prosthetic devices, artificial hips, knees, giving this industry a global market of $2.1 billion with a projected market growth exceeding 10% per annum. In (1994-5) 5,717 prosthetic hips and 4,593 knees were surgically implanted in NSW of which 14% of hips and 9.5% of knees were revisions. Considerable health funding is allocated to joint replacement for the nation, although successful, outcomes are finite. Importantly, and aside from costs, patients morbidity is high. The major cause of long-term failure of these prosthetic replacements is aseptic loosening, the result of bone loss at the bone-device interface. Novel approaches to development of more efficient implant materials would ultimately lead to major contributions to the mobility and and quality of life for these patients. Considerable effort has been devoted to alter surface characteristics of orthopaedic implants to improve the interlocking of device and skeleton. We were the first to demonstrate that surface chemical modification of biomaterials using selected ions resulted in an enhanced bone formation. This proposal is aimed at chemically modifying the surfaces of commonly used orthopaedic and dental materials, to improve the biocompatibility of new devices and the surface coatings for existing prostheses. Furthermore, this application will build on the in vitro data showing that particular peptides specifically bind osteoblasts and therefore have the potential to provide a surface on a prosthesis that is conducive to bone formation. To date, we have coupled these peptides to metallic surfaces and will proceed to study the osteoblastic phenotype and subsequent osteogenesis. Development of these novel biocompatible surfaces is anticipated to reduce patient morbidity and result in significant health care savings.Read moreRead less