New insulins for the improved management of diabetes. The prevalence of diabetes has increased dramatically over the past few decades and now this condition is widely considered the world’s fastest growing disease. New insulins with improved pharmacological and storage properties are desperately needed, and this project will work on chemical synthesis enabling designer insulins to be prepared for improved management of diabetes.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100021
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A diagnostics platform for advanced plasma-chemical analysis. A wide range of production processes involve the use of plasmas to modify materials, but they are not well understood. This project will give Australian researchers the tools to look inside plasma processes and fully characterise them for the first time, unlocking new knowledge and providing new insight into the plasma processing environment.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100236
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Facilities for spectroscopy and diffraction at high pressures. The provision of infrastructure for the study of novel materials under high pressures will enhance Australia's capability in creating new materials and in creating new devices that meet needs in communication, environment and medicine applications. The new facility will enable researchers to understand the response of structures to extreme pressures and will exploit the unique capabilities of the synchrotron light.
We will seek to address an important clinical problem in orthpaedics, namely the bone loss that commonly occurs around joint replacement prostheses. Termed peri-prosthetic osteolysis (PO), this bone loss can result in the loosening and ultimate failure and need for revision of the artificial joint components. PO is thought to be caused by the body's reaction to wear particles generated from the articulating surface of the prosthesis. However, it has not previously been possible to accurately exp ....We will seek to address an important clinical problem in orthpaedics, namely the bone loss that commonly occurs around joint replacement prostheses. Termed peri-prosthetic osteolysis (PO), this bone loss can result in the loosening and ultimate failure and need for revision of the artificial joint components. PO is thought to be caused by the body's reaction to wear particles generated from the articulating surface of the prosthesis. However, it has not previously been possible to accurately explore the relationship between prothesis wear and PO, or the progression of PO, because of a lack of techniques to image and measure the volume of PO around metal prosthesis components. We have developed a means to accurately and reproducibly measure the volume of bone loss, using CT, and will do so longitudinally in joint replacement patients to obtain the first information about the progression of PO. New computer based methods will be used concurrently to relate prosthesis wear and migration parameters to PO. Patients who come to surgery for replacement of failed prostheses will be investigated further by analysis of the tissues involved in the bone loss around prostheses. Basic science experiments will seek to understand the underlying causes of PO and the findings will be important in interpreting the clinical results. An animal model will be used to seek approaches to inhibiting the pathological response to wear particles. The significance of these studies is that they will lead to improved outcomes for joint replacement patients, increasing the interval to revision surgery, which is both extremely costly and brings an attendant morbidity and mortality.Read moreRead less
Smart polymer-DNA hybrids as recognition sites for advanced DNA nanotechnology applications. This project aims to design and synthesise a new family of DNA-conjugated chain transfer agents for the positional control of DNA in a broad range of 2D and 3D 'smart' polymer-DNA hybrid materials. These bioconjugated materials will be investigated to understand the fundamental self-assembly processes which underpin emerging dynamic DNA nanotechnologies. This timely research will revolutionise the use of ....Smart polymer-DNA hybrids as recognition sites for advanced DNA nanotechnology applications. This project aims to design and synthesise a new family of DNA-conjugated chain transfer agents for the positional control of DNA in a broad range of 2D and 3D 'smart' polymer-DNA hybrid materials. These bioconjugated materials will be investigated to understand the fundamental self-assembly processes which underpin emerging dynamic DNA nanotechnologies. This timely research will revolutionise the use of biologically inspired intelligent metamaterials for use in medical diagnostics, DNA computing and DNA nanomachines.Read moreRead less