Phenotypic Characterization Of Chloroquine Resistance In Plasmodia
Funder
National Health and Medical Research Council
Funding Amount
$585,473.00
Summary
In the Asia-Pacific region, vivax malaria is becoming the dominant species of infection. The emergence and spread of chloroquine resistant strains of P. vivax threatens malaria control and elimination efforts. This project aims to elucidate fundamental aspects of chloroquine resistance in non-falciparum malaria and identify novel therapeutic options. We will develop novel tests that will help national malaria control programs to monitor declining activity of standard anti-malarial drugs.
Interaction Of New Kinase Inhibitor Drugs With Multi-drug Resistance (MDR) Transporter Proteins.
Funder
National Health and Medical Research Council
Funding Amount
$411,000.00
Summary
Multidrug transporter proteins are remarkable molecular pumps that expel a wide variety of drugs and toxins from cells. They are located at strategic sites where they eliminate harmful substances from the body or prevent them being absorbed from our diet in the first place. Multidrug transporters are also found at natural barriers within the body where they protect vulnerable tissue compartments, including the brain, cerebrospinal fluid, testes and, in preganant women, the foetus. Nevertheless, ....Multidrug transporter proteins are remarkable molecular pumps that expel a wide variety of drugs and toxins from cells. They are located at strategic sites where they eliminate harmful substances from the body or prevent them being absorbed from our diet in the first place. Multidrug transporters are also found at natural barriers within the body where they protect vulnerable tissue compartments, including the brain, cerebrospinal fluid, testes and, in preganant women, the foetus. Nevertheless, multidrug transporters sometimes interfere with drug therapy. They can prevent efficient absorption of drugs, increase the rate of drug elimination from the body, or prevent drug access to some tissues . Moreover, the activity of the transporters is quite variable, both between patients and within the same patient over time. This makes it difficult to provide optimal drug doses, particularly when treating cancer, where the drugs must be given at the maximum tolerated dose. The presence of drug transporter proteins in tumour cells can prevent entry of anticancer drugs, rendering them resistant to treatment. This is the main cause of failure in chemotherapy. This project will investigate a class of very promising new anticancer drugs, kinase inhibitors, to determine whether they are pumped by multidrug transporters, whether they alter the amounts of drug transporters in cells, and whether they alter transporter activity. We will also determine the consequences that follow from this for drug therapy. This information will help clinicians to rationally optimise therapy with the new drugs, to identify in advance both favourable (synergistic) and unfavourable (harmful) drug interactions in combination chemotherapy, to optimise drug doses and to minimise toxic side effects. The information will also add to our general understanding of drug absorption and elimination, and to the basic science of the remarkable multidrug transporter proteins.Read moreRead less
Novel Cellular Trafficking Mechanisms For The Drug Influx Transporter, Human Organic Anion Transporting Polypeptide 1A2 (OATP1A2)
Funder
National Health and Medical Research Council
Funding Amount
$337,614.00
Summary
Human organic anion transporting polypeptides (OATPs) are membrane proteins that regulate the cellular uptake of endogenous and exogenous substances including anti-cancer drugs. OATPs strongly determine whether such drugs enter the tissues where they are required to exert their effects. This project will study novel mechanisms that we have recently identified that determine the orientation of transporters in the cells. These processes can be impaired by a common pharmacogenetic variant in indivi ....Human organic anion transporting polypeptides (OATPs) are membrane proteins that regulate the cellular uptake of endogenous and exogenous substances including anti-cancer drugs. OATPs strongly determine whether such drugs enter the tissues where they are required to exert their effects. This project will study novel mechanisms that we have recently identified that determine the orientation of transporters in the cells. These processes can be impaired by a common pharmacogenetic variant in individuals.Read moreRead less
Epilepsy is one of the most common chronic neurological disorders; it affects 1% of the world’s population, yet about 1 in 3 patients fail to achieve seizure control with current drugs. We will improve the properties of small molecules (drugs) that specifically target the GTPase activity of the enzyme dynamin, to reduce seizure effect in the brain by a novel mechanism. We will optimize and pre-clinically test these future chemical entities as potential anti-epileptic drugs.
Predicting Drug-drug Interactions Due To Tyrosine Kinase Inhibitors: Inhibition Of Drug Metabolising Enzymes And Transporters
Funder
National Health and Medical Research Council
Funding Amount
$535,495.00
Summary
Tyrosine kinase inhibitors (TKIs) are a new class of anticancer agents. Cancer patients typically receive multiple drugs, for the treatment of cancer and other diseases, increasing the probability of interactions between coadministered drugs. Despite the widespread use of TKIs, their potential to cause drug interactions is poorly understood. Using novel in vitro approaches, this project will identify drug interactions precipitated by TKIs thereby improving drug efficacy and patient safety.
Lipoceramic Technologies: A Solution To Low And Variable Bioavailability Of Poorly Soluble Anti-inflammatory Drugs
Funder
National Health and Medical Research Council
Funding Amount
$200,600.00
Summary
A novel oral drug delivery platform will be developed that improves the absorption of poorly soluble drugs from the GI tract, leads to improved clinical outcomes and has significant commercial value. This development will be based on the combination of formulation, in vitro analysis and in vivo animal model studies. An advanced prototype formulation will be established for celecoxib (a non-steroidal anti-inflamatory drug) that will be suitable for human phase 1 clinical trials.
Developing Synergisers Of The Antimalarial Drug, Chloroquine, For The Treatment Of Chloroquine-resistant P. Falciparum.
Funder
National Health and Medical Research Council
Funding Amount
$243,000.00
Summary
Malaria is a debilitating parasitic disease that is responsible for the deaths of about two million children each year. As drugs, such as chloroquine, become increasingly useless due to the development of parasite resistance, there is an urgent need to understand the mode of action of and the molecular basis of resistance to existing antimalarials and to design affordable treatments that can replace chloroquine. It is known that some compounds, that have only poor antimalarial activity themselve ....Malaria is a debilitating parasitic disease that is responsible for the deaths of about two million children each year. As drugs, such as chloroquine, become increasingly useless due to the development of parasite resistance, there is an urgent need to understand the mode of action of and the molecular basis of resistance to existing antimalarials and to design affordable treatments that can replace chloroquine. It is known that some compounds, that have only poor antimalarial activity themselves, can synergise the action of chloroquine. This may involve the inhibition of the activity of proteins that directly or indirectly extrude chloroquine from its site of action in the parasite's digestive apparatus. Unfortunately, thechloroquine synergisers examined to date have been too toxic to be useful in vivo. In preliminary studies we have identified some compounds that would be suitable for use in malaria patients, including a widely used antimalarial drug, primaquine, that can synergise the activity of chloroquine against chloroquine-resistant parasites. We will attempt to understand the molecular basis of this interaction. This will allow us to define optimal combinations of chloroquine and a resistance-reversing quinoline for use treating malaria. This could extend the clinical life of this important antimalarial drug. The information obtained may also help to design novel antimalarial drugs.Read moreRead less
A Nanostructured Drug Delivery Approach For Improved Colorectal Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$560,072.00
Summary
Based on nanotechnology a new medicine will be developed for chemotherapy drugs. Drugs that are currently only delivered by injection will be able to be taken as an orally dosed tablet. A novel therapy for colorectal cancer will be advanced with potential improved clinical outcomes and reduced side-effects, e.g. nausea and diarrhoea. Cancer patients will no longer need to visit the hospital for injection therapy and therefore reducing the burden on the health service.
Development Of Fragment Hits Into Effective Antimalarials; Targeting Malaria Eradication
Funder
National Health and Medical Research Council
Funding Amount
$676,798.00
Summary
We have used a novel method that samples the diversity of natural products with a small sub-set of compounds, and observed direct interaction between these compounds and proteins important in the malaria parasite life cycle. This project will develop these identified active compounds towards the goal of producing a drug to fight stages of the malaria parasite’s life cycle that are not targeted by currently available antimalarial drugs.