Discovery Early Career Researcher Award - Grant ID: DE150101863
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Strained alkenes as chemical probes for cysteine sulfenic acid. This project aims to introduce strained alkenes as probes for cysteine sulfenic acid, a poorly understood biomarker for oxidative stress. This probe will enable rapid detection of cysteine sulfenic acid and meet an urgent need for tools to map cysteine redox signalling. Moreover, since many enzymes feature a cysteine sulfenic acid at their active site, the strained alkene probes will also serve as useful inhibitor probes of these en ....Strained alkenes as chemical probes for cysteine sulfenic acid. This project aims to introduce strained alkenes as probes for cysteine sulfenic acid, a poorly understood biomarker for oxidative stress. This probe will enable rapid detection of cysteine sulfenic acid and meet an urgent need for tools to map cysteine redox signalling. Moreover, since many enzymes feature a cysteine sulfenic acid at their active site, the strained alkene probes will also serve as useful inhibitor probes of these enzymes. Such inhibitor probes will provide critical information for potential therapeutic applications in human conditions associated with oxidative stress such as ageing, cancer, and heart disease.Read moreRead less
A Tough Resilin Based Hydrogel Platform for Repair and Regeneration. This project seeks to develop novel hydrogels that mimic the properties of the body. In the field of repair and regeneration, our challenge is to make hydrogels that retain the fatigue and resilience properties of the natural body part, but are comprised of nontoxic material. Resilin is a remarkable material exhibiting a broad range of stimuli-responsive behaviour and outstanding elasticity. The project aim is to create a tough ....A Tough Resilin Based Hydrogel Platform for Repair and Regeneration. This project seeks to develop novel hydrogels that mimic the properties of the body. In the field of repair and regeneration, our challenge is to make hydrogels that retain the fatigue and resilience properties of the natural body part, but are comprised of nontoxic material. Resilin is a remarkable material exhibiting a broad range of stimuli-responsive behaviour and outstanding elasticity. The project aim is to create a tough and responsive hydrogel platform from this disordered protein family through greater understanding of structure and mechanical function and incorporating adequate stiffness, strength and biocompatibility. Such tough hydrogels would be applicable to a range of biotechnological applications (eg intervertebral disc repair or artificial skin tissue engineering).Read moreRead less
Bio-inspired molecular electronics: from nanoscience to nanotechnology. This project aims to investigate electron transport in naturally occurring peptides, while exploiting their electronic properties to promote the design and development of functional bio-inspired molecular electronic devices. Molecular electronics is at the forefront of international interdisciplinary research, with its significance and necessity stemming from the inevitable physical limitations of existing silicon-based elec ....Bio-inspired molecular electronics: from nanoscience to nanotechnology. This project aims to investigate electron transport in naturally occurring peptides, while exploiting their electronic properties to promote the design and development of functional bio-inspired molecular electronic devices. Molecular electronics is at the forefront of international interdisciplinary research, with its significance and necessity stemming from the inevitable physical limitations of existing silicon-based electronics. This project aims to establish a foundation to advance fundamental knowledge in this area, which will lead to the design and development of functional bio-inspired molecular electronic devices.Read moreRead less
Defining peptide structure and function: the shape of things to come. In this project we develop new and general ways of chemically defining the structure and function of natural peptides. This then provides a basis of potential therapies to treat a number of diseases currently confronting Australia's aging population, for example, cataract, Alzheimer's disease, cancer, and cardiovascular disease.
Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translat ....Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translated into molecular assembly line syntheses in a single unit or a series. Such syntheses should provide a versatile toolbox for molecular transformations, under continuous flow conditions where scalability is addressed upfront. This will be attractive to industry and minimise effects on the environment.Read moreRead less
Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanc ....Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanced, with higher yields and tunable selectivity, and reduced waste and energy usage, which is not possible using traditional batch processing. This will be translated into molecular assembly line processing and the development of a new synthetic toolbox, with applications in preparing pharmaceuticals.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100190
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
Electrophysiology Platform for Ion-channel Characterisation. Ion channels are ubiquitous pore-forming membrane proteins, with the human genome encoding >300 ion channels. The diverse roles of ion channels include action potential generation, control of ion flow across secretory and epithelial cells, and regulation of cell volume, motility and proliferation. Pharmacological modulators are powerful tools for probing ion channel function, but for most channels these tools are lacking. Thus, this p .... Electrophysiology Platform for Ion-channel Characterisation. Ion channels are ubiquitous pore-forming membrane proteins, with the human genome encoding >300 ion channels. The diverse roles of ion channels include action potential generation, control of ion flow across secretory and epithelial cells, and regulation of cell volume, motility and proliferation. Pharmacological modulators are powerful tools for probing ion channel function, but for most channels these tools are lacking. Thus, this project aims to develop the first comprehensive toolbox of ion channel modulators using an integrated in vitro/in vivo electrophysiology platform. These pharmacological tools will be made freely available to the Australian research community for probing the mechanism and physiological function of ion channels.Read moreRead less