Investigations into the antibacterial mechanism of action of cannabidiol. This project aims to understand how the compound cannabidiol is able to kill bacteria by examining its interactions with bacteria from a genetic and molecular level. This research is critical, because future development of cannabidiol and design of improved analogs is predicated on knowing how it works. Expected outcomes include the first detailed understanding of how cannabidiol interacts with bacteria. This should lead ....Investigations into the antibacterial mechanism of action of cannabidiol. This project aims to understand how the compound cannabidiol is able to kill bacteria by examining its interactions with bacteria from a genetic and molecular level. This research is critical, because future development of cannabidiol and design of improved analogs is predicated on knowing how it works. Expected outcomes include the first detailed understanding of how cannabidiol interacts with bacteria. This should lead to significant benefits, including high impact publications, additional collaborations with industrial partner Botanix, and a new class of antibiotics to overcome antibiotic resistance.Read moreRead less
Developing the basis for an quality control platform for human pluripotent stem cells and their differentiated derivatives. Biophotonic techniques based on spectroscopy have the potential to provide low-cost, automatable measurements for the quality control of stem and differentiated cells produced for use in industry and regenerative medicine. This project is aimed at acquiring the fundamental scientific knowledge base required to bring this about.
Australian Laureate Fellowships - Grant ID: FL160100139
Funder
Australian Research Council
Funding Amount
$2,965,538.00
Summary
Outside-In: Strain stiffening as a key to cell control. Outside-In: Strain stiffening as a key to cell control. This research project aims to unravel the highly complex mechanical behaviour of the extracellular matrix, and develop a whole new class of sophisticated and responsive extracellular matrix (ECM) materials. In any multicellular organism, the ECM provides cells with essential mechanical (such as strain stiffening) and biochemical support. The ECM is also critical for biological processe ....Outside-In: Strain stiffening as a key to cell control. Outside-In: Strain stiffening as a key to cell control. This research project aims to unravel the highly complex mechanical behaviour of the extracellular matrix, and develop a whole new class of sophisticated and responsive extracellular matrix (ECM) materials. In any multicellular organism, the ECM provides cells with essential mechanical (such as strain stiffening) and biochemical support. The ECM is also critical for biological processes inside the cell, including proliferation, differentiation and migration. Exactly how the physical and chemical properties of ECMs on the outside of the cell modify the behaviour of a cell on the inside remains unclear. Outcomes would include a blueprint for synthetic ECMs, pushing the boundaries of materials development in the biological and life sciences.Read moreRead less
The role of chlorophyll f in photosynthesis. The knowledge of energetic limits of oxygenic photosynthesis will provide opportunities for improving the efficiency of photosynthesis by using a wider range of the solar spectrum. This project aims to understand the roles of newly discovered chlorophyll f in central photoreactions and its biosynthesis.