QUANTITATIVE ASSESSMENT OF LOOSENING IN HIP ARTHROPLASTIES USING MECHANICAL VIBRATION DIAGNOSTICS
Funder
National Health and Medical Research Council
Funding Amount
$185,665.00
Summary
Recent advances and improvements made to the mechanical design of artificial joints have led to greater strength, fatigue life and wear resistance. However, this extension to the working life of joint replacements has led to patients becoming increasingly vulnerable to the problem of joint loosening. There are over 500 000 hip joint replacements performed every year, on a worldwide basis. Of these 7 to 13% will require revision surgery because of loosening at some stage of their working life. Th ....Recent advances and improvements made to the mechanical design of artificial joints have led to greater strength, fatigue life and wear resistance. However, this extension to the working life of joint replacements has led to patients becoming increasingly vulnerable to the problem of joint loosening. There are over 500 000 hip joint replacements performed every year, on a worldwide basis. Of these 7 to 13% will require revision surgery because of loosening at some stage of their working life. This is becoming a major concern to health services around the world since revision surgery is associated with a higher risk to the patient and costs are far greater than for the primary operation. Current diagnostic techniques using radiographic imaging are both invasive and lack diagnostic accuracy. The ability to detect joint loosening and to discriminate between the various causes of joint loosening following arthroplasty is of great importance to the success of subsequent care plans. This study will be the first in the world to assess the validity of a new diagnostic test that uses low energy mechanical vibration to quantify the degree of loosening in both components of the implanted hip joint. Once the technique has been proven it could readily be extended to evaluate the degree of fixation of other implanted prostheses used to replace the knee, ankle or joints of the upper limbs.Read moreRead less
Intelligent Freeform Bio-fabrication for Customised Anatomical Structures for Reconstructive Surgery. This project contributes towards the ARC priority goal on advanced materials and frontier technologies by developing an intelligent freeform biofabrication facility to produce accurate anatomical biocompatible replica structures and implants for reconstructive surgery. The products, produced from patient's CT or MRI scan data, will contribute to complex surgical procedure planning and patient ed ....Intelligent Freeform Bio-fabrication for Customised Anatomical Structures for Reconstructive Surgery. This project contributes towards the ARC priority goal on advanced materials and frontier technologies by developing an intelligent freeform biofabrication facility to produce accurate anatomical biocompatible replica structures and implants for reconstructive surgery. The products, produced from patient's CT or MRI scan data, will contribute to complex surgical procedure planning and patient education. The proposed facility will be based on multifunctional freeform fabrication process supported by intelligent software tools and database of biocompatible materials. The prospective outcomes are likely to have an excellent commercial and patenting potential that may help Australia become a leader in biomanufacturing technology.Read moreRead less
Computational haemodynamics system for prediction of risk of rupture of cerebral aneurysms. Every year about 2000 Australians suffer a ruptured aneurysm in the brain and some 750 of these die within 4 weeks. Since there is an increase in the detection of unruptured aneurysms, especially in healthy young people, there is an urgent need to be able to decide which lead to rupture and to provide suitable treatment options. This project, which will provide markedly improved means of patient-specific ....Computational haemodynamics system for prediction of risk of rupture of cerebral aneurysms. Every year about 2000 Australians suffer a ruptured aneurysm in the brain and some 750 of these die within 4 weeks. Since there is an increase in the detection of unruptured aneurysms, especially in healthy young people, there is an urgent need to be able to decide which lead to rupture and to provide suitable treatment options. This project, which will provide markedly improved means of patient-specific risk determination for aneurysm rupture, will have significant impact in reducing associated costs on the national health burden due to cerebral hemorrhage and stroke, on community productivity and disability and on more efficient targeting of expensive and dangerous brain surgery.Read moreRead less
Development Of A Smart Arthroscopy System And Prototype Probe For Joint Tissues
Funder
National Health and Medical Research Council
Funding Amount
$230,632.00
Summary
This project relates to the ever growing use of arthroscopy in the management of joint defects. An innovative probe that will combine all the molecular, microstructural and biomechanical characteristics of joint articular cartialge and bone for the purposes of diagnosis, treatment, treatment-related decisions, comparison of the effectiveness of treament methods and post treatment evaluation will be developed. This system will produce spin-offs for artrhoscopy of other soft tissues and bodies.