Engineered Hydroxamic Acids for Zirconium-89 Positron Emission Tomography (PET) Imaging of Prostate Cancer. Positron emission tomography (PET) using a zirconium-89-ligand complex bound to a prostate-specific membrane antigen is used to detect and monitor prostate cancer. The hydroxamic acid-based ligand bound to zirconium has a high affinity towards iron, which can cause metal exchange in vivo and loss of radiotracer. The project will prepare new ligands with a higher specificity towards zirconi ....Engineered Hydroxamic Acids for Zirconium-89 Positron Emission Tomography (PET) Imaging of Prostate Cancer. Positron emission tomography (PET) using a zirconium-89-ligand complex bound to a prostate-specific membrane antigen is used to detect and monitor prostate cancer. The hydroxamic acid-based ligand bound to zirconium has a high affinity towards iron, which can cause metal exchange in vivo and loss of radiotracer. The project will prepare new ligands with a higher specificity towards zirconium over iron, and measure immuno-PET imaging activity. A second series of macrocyclic zirconium-specific ligands will be prepared to establish the relationship between variable water-lipid solubility and pharmacokinetic properties. The results will increase the capability of immuno-PET for prostate cancer detection and improve survival outcomes.Read moreRead less
Detection of infrared-biomarkers for the diagnosis and treatment of canine neoplasia. This research hopes to discover infrared-biomarkers for canine cancers using synchrotron infrared and laser light. Many dog cancers are similar to human cancers so cancerous tissues and cells from dogs make excellent models for human cancer research. This project will provide new insights and technological approaches to cancer diagnosis and treatment.
Discovery Early Career Researcher Award - Grant ID: DE120101331
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Fundamental electromagnetic modelling of light-biological tissue interactions: a platform for future medical microscopy. Methods for modelling the fundamental electromagnetic interaction of light with biological tissue will be developed. This will allow a range of biomedical optical images to be properly interpreted ultimately leading to the holy grail of quick and minimally invasive methods for detecting cancer.
Caged lanthanides for use in photo-dynamic therapy and near infra-red imaging. The early detection and effective treatment of cancer are two critical factors which determine survivability. This project will provide improved drugs for photo-dynamic therapy and develop emissive probes for near infra-red imaging to allow better discrimination between healthy and diseased tissue and improve subsequent treatment.
MRI Molecular Imaging Agents - from fundamental design to In Vivo Applications. Of approximately 60 million magnetic resonance imaging (MRI) procedures performed annually worldwide, around 30 per cent of these use MRI imaging agents. Imaging agents allow the doctors to study blood flow and to identify particular tissue types and diseases. This project will lead to new classes of high-performance imaging agents which offer the prospect of faster more accurate diagnosis.