Pre-clinical Development Of A Chemically Synthetic Anti-toxic Vaccine Against Malaria
Funder
National Health and Medical Research Council
Funding Amount
$165,000.00
Summary
Plasmodium falciparum malaria infects 5-10% of the global population (400 million clinical cases) and kills two million people annually1. As such it ranks along with HIV and TB as the most serious infectious disease of humanity. It is widely accepted that an efficacious vaccine is required to afford protection against malarial fatalities. The induction of broad-ranging sterilizing immunity is not considered a likely objective for anti-malarial vaccines. Instead, reduction in morbidity and mortal ....Plasmodium falciparum malaria infects 5-10% of the global population (400 million clinical cases) and kills two million people annually1. As such it ranks along with HIV and TB as the most serious infectious disease of humanity. It is widely accepted that an efficacious vaccine is required to afford protection against malarial fatalities. The induction of broad-ranging sterilizing immunity is not considered a likely objective for anti-malarial vaccines. Instead, reduction in morbidity and mortality is the realistic aim of malaria vaccine strategies. Traditional approaches seek to provide this clinical protection indirectly, by killing the parasite or by reducing parasite multiplication. To this end, current anti-malarial vaccines candidates seek to confer on the host parasiticidal immune mechanisms, which have as their target antigenic proteins expressed on the surface of the different stages of the parasite. No malaria vaccine is yet on the market. There exist several potentially competitive leads in late-stage pre-clinical-early stage clinical development, particularly recombinant proteins. The US Navy MUSTDO-25 DNA vaccines are not living up to their promise. Most leading “vaccine candidates” are polymorphic alleles. There are significant prospects for vaccine-induced selection of breakthrough variants. Multiple alleles may also prove cost-prohibitive for vaccine development. The novelty and uniqueness of this approach have contributed to the acceptance of this study for publication by Nature. The aims of this proposal are four-fold: i) to further rationalize the target through chemical synthesis of intermediates and partial structures; (ii) to examine antigenicity and immunogenicity in large experimental mammals, and undertake epitope mapping of human anti-GPI IgG responses; (iii) to obtain preliminary safety data in these animals; and (iv) to undertake a vaccine trial in a simian malaria model. We envisage objectives (i)-(iii) will take 12 months. Objective (iv) will proceed in the six months thereafter.Read moreRead less
Development Of A PET Detection System Prototype With Depth Of Interaction Capability
Funder
National Health and Medical Research Council
Funding Amount
$360,906.00
Summary
This development project invovles the development of a slim-line Positron Emission Tomogrphy (PET) detection sub-module, the crucial component of PET scanners, that is small and extremely flexible. It is planned to utilize this module in the design of customized new commercial PET scanners ideal for diagnosing human brain and breast disorders. The development will proceed in collaboration with Insight Oceania-ADAC, Sydney. Insight Oceania-ADAC are very excited by the potential applications and f ....This development project invovles the development of a slim-line Positron Emission Tomogrphy (PET) detection sub-module, the crucial component of PET scanners, that is small and extremely flexible. It is planned to utilize this module in the design of customized new commercial PET scanners ideal for diagnosing human brain and breast disorders. The development will proceed in collaboration with Insight Oceania-ADAC, Sydney. Insight Oceania-ADAC are very excited by the potential applications and future markets (Australia and overseas) of the newly developing PET detection sub-modules for dedicated PET scanners. Positron Emission Tomography (PET) is a functional imaging tool, which is able to quantify physiological and biochemical processes in vivo, using short-lived cyclotron-produced radiotracers. PET is emerging as an extremely important diagnostic procedure used in the early detection of cancers, neurological diseases and as an aid in treatment monitoring and drug development. The unique advantage of PET over anatomical imaging techniques, such as X-ray CT and MRI, arises from its ability to measure changes in tumour biology, at the molecular level, prior to anatomical changes in involved tissues, using trace amounts of a radiolabelled compound (radiotracer). The full potential of PET however, is not being completely utilized due to constraints within the current designs of PET scanners. When used to its full potential PET, in principle, would be an excellent diagnostic and treatment monitoring tool for breast cancer, brain tumours and other neurological conditions such as epilepsy, Alzheimer's, Parkinson's disease, post stress disorder, dementia, and depression. Lack of flexibility in current PET scanner designs to date has meant that no commercial human brain or breast imaging scanners exist. Pilot project data proved the feasibility of our new flexible PET detection module design.Read moreRead less