The Social Life of Death. This project aims to investigate experiences of death, dying and bereavement amidst rapid social, economic and political transformation. In the wake of COVID19, and as Australia’s anticipated ‘death boom’ approaches, how to foster good deaths has never been more uncertain, nor more urgent. Drawing on innovative methods and socio-cultural theory, and working in partnership with families and communities, this project aims to generate new knowledge to better inform and imp ....The Social Life of Death. This project aims to investigate experiences of death, dying and bereavement amidst rapid social, economic and political transformation. In the wake of COVID19, and as Australia’s anticipated ‘death boom’ approaches, how to foster good deaths has never been more uncertain, nor more urgent. Drawing on innovative methods and socio-cultural theory, and working in partnership with families and communities, this project aims to generate new knowledge to better inform and improve policy and spark cultural renewal around the end of life. Expected outcomes include setting the international benchmark for novel scholarly understandings of death, dying and bereavement, and centring community voices in addressing contemporary challenges to dying well.
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Highly Efficient Nanomotors for Autonomous Cell Recognition and Isolation. This project aims to develop next-generation self-driven nanomotors capable of long-range motion with highly controlled directionality for cell recognition, transportation and separation in complex biological environments, to allow autonomous and seamless cell sorting with high accuracy. The anticipated goal of this project is to advance the field of nanotechnology and advanced manufacturing with potential to support new ....Highly Efficient Nanomotors for Autonomous Cell Recognition and Isolation. This project aims to develop next-generation self-driven nanomotors capable of long-range motion with highly controlled directionality for cell recognition, transportation and separation in complex biological environments, to allow autonomous and seamless cell sorting with high accuracy. The anticipated goal of this project is to advance the field of nanotechnology and advanced manufacturing with potential to support new applications and to value-add Australia’s advanced manufacturing industry, presenting new opportunities for Australian MedTech industries with innovative, disruptive technologies to address its unique needs and to claim Australia’s position within the competitive global market.Read moreRead less
Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others a ....Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others are used in biotechnology for biosynthetic chemical production or bioremediation. This project expects to help the future development of new antibiotics and assist in the design of strains to be used in biotechnological applications.Read moreRead less
Novel inkjet-printed organic solvent nanofiltration membranes. The pharmaceutical industry is one of fastest growing industries in Australia. Manufacturing pharmaceutical products requires the use of hazardous and expensive organic solvents, which are toxic for the environment and expensive to recover due to the energy intensive thermal process required. This project aims to discover and manufacture a novel, low-cost, chemically robust nanomaterial-based membrane using an industry scalable inkje ....Novel inkjet-printed organic solvent nanofiltration membranes. The pharmaceutical industry is one of fastest growing industries in Australia. Manufacturing pharmaceutical products requires the use of hazardous and expensive organic solvents, which are toxic for the environment and expensive to recover due to the energy intensive thermal process required. This project aims to discover and manufacture a novel, low-cost, chemically robust nanomaterial-based membrane using an industry scalable inkjet printing process. The membrane will be resistant to organic solvents while efficiently recovering valuable and hazardous organic solvents with minimum environmental footprint. It will effectively provide for the future growth of the Australian pharmaceutical industry while also having global applications.Read moreRead less
Designing high performance gas separation by interfacial diffusion membrane. This project aims to develop a new generation of interfacial diffusion membranes for industrial gas separations including carbon dioxide removal, nitrogen gas enrichment, methane purification and air separation. The project focuses on advancing separation technologies for the petrochemical, natural gas, and clean energy industries in the mining sector. The project is expected to reveal new separation properties and perf ....Designing high performance gas separation by interfacial diffusion membrane. This project aims to develop a new generation of interfacial diffusion membranes for industrial gas separations including carbon dioxide removal, nitrogen gas enrichment, methane purification and air separation. The project focuses on advancing separation technologies for the petrochemical, natural gas, and clean energy industries in the mining sector. The project is expected to reveal new separation properties and performance based on highly selective interfacial diffusion membranes. The project will also create new scientific knowledge about the role of functional surfaces and nanostructures that will not only facilitate new membrane designs but also offer new, more cost-effective devices for solar conversion, energy storage and harvesting, biomedical applications, sensing and information technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101055
Funder
Australian Research Council
Funding Amount
$448,737.00
Summary
How blood vessel stiffness regulates their growth and maintenance. This project aims to reveal an unidentified molecular mechanism of how endothelial cells in the walls of blood vessels detect stiffness of the surrounding environment in order to regulate blood vessel growth and maintenance. The results are expected to advance the emerging field of mechanobiology by combining cutting-edge cell biology and microscopy techniques carried out in novel 3D cell culture and unique quail models. The bene ....How blood vessel stiffness regulates their growth and maintenance. This project aims to reveal an unidentified molecular mechanism of how endothelial cells in the walls of blood vessels detect stiffness of the surrounding environment in order to regulate blood vessel growth and maintenance. The results are expected to advance the emerging field of mechanobiology by combining cutting-edge cell biology and microscopy techniques carried out in novel 3D cell culture and unique quail models. The benefits of these outcomes include generation of knowledge on the impact of tissue stiffness on the signalling mechanisms that drive formation and maintenance of blood vessels. In the long term, this fundamental understanding could give rise to major developments in emerging industries such as organ bioengineering.Read moreRead less
Sensing biomechanical forces in the heart. Mechanosensitive ion channels are key molecules that define how each heart cell interacts with their physical environment. Yet how they enable cells to decode biomechanical cues remains poorly understood. At the heart of this problem is a lack of tools to quantify the force required for activation. This project aims to develop novel technologies to record the activity of these essential channels in a critical cell type within the heart, and use this inf ....Sensing biomechanical forces in the heart. Mechanosensitive ion channels are key molecules that define how each heart cell interacts with their physical environment. Yet how they enable cells to decode biomechanical cues remains poorly understood. At the heart of this problem is a lack of tools to quantify the force required for activation. This project aims to develop novel technologies to record the activity of these essential channels in a critical cell type within the heart, and use this information in addition to micro-engineering approaches to fully understand the role of these channels in force sensing and generation, at both the single cell and micro-tissue levels. This knowledge and technology has broad utility that extends far beyond cardiac biology into multiple fields.Read moreRead less
Confronting everyday harms: preventing abuse of people with disability. The findings of the Disability Royal Commission necessitate new approaches to prevent violence, abuse, neglect and exploitation. Framed by recognition theory, this project proposes empirical research with young people with cognitive disability, using a new concept of ‘everyday harms’ in their paid relationships. The results will inform early responses to poor quality interactions in disability support. The strategic alliance ....Confronting everyday harms: preventing abuse of people with disability. The findings of the Disability Royal Commission necessitate new approaches to prevent violence, abuse, neglect and exploitation. Framed by recognition theory, this project proposes empirical research with young people with cognitive disability, using a new concept of ‘everyday harms’ in their paid relationships. The results will inform early responses to poor quality interactions in disability support. The strategic alliances with the government, industry and community partners will develop a practice framework to prevent everyday harms and the escalation to abuse, and to promote safety and wellbeing. The research has policy benefits for capacity-building in the sector to act on the rights and voices of people with disability. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100661
Funder
Australian Research Council
Funding Amount
$426,551.00
Summary
Nanoparticle with Metal Organic Framework for Lithium Recovery from Brine. The project aims to develop technology enabling lithium to be cost-effectively extracted from brine. Today Australia meets the increasing demand for lithium by mining hardrock lithium, an environmentally damaging activity. An alternative is to source lithium from brine produced as industrial wastewater (in desalination or shale gas production). The main challenge that brine presents to selectively extracting lithium is co ....Nanoparticle with Metal Organic Framework for Lithium Recovery from Brine. The project aims to develop technology enabling lithium to be cost-effectively extracted from brine. Today Australia meets the increasing demand for lithium by mining hardrock lithium, an environmentally damaging activity. An alternative is to source lithium from brine produced as industrial wastewater (in desalination or shale gas production). The main challenge that brine presents to selectively extracting lithium is competing ions. By advancing knowledge of nanomaterials and membrane distillation, the project expects to overcome both this technical challenge and other practical challenges. From wastewater, the anticipated system will produce additional clean water and a valuable commodity that can offset the cost of water treatment. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101128
Funder
Australian Research Council
Funding Amount
$444,154.00
Summary
Decode Neuro-Mechanobiology:mechanosensitive ion channels in proprioception. Human bodies are densely covered with numerous mechanosensory neurons that provide us with the sense of touch and pain. However, the molecular force sensors remain poorly identified. This project aims at defining the fundamental roles of mechanosensitive ion channels to sense and respond to various mechanical stimuli, and how their responses may encode mechanical cues.The ultimate goal is to provide a fundamentally new ....Decode Neuro-Mechanobiology:mechanosensitive ion channels in proprioception. Human bodies are densely covered with numerous mechanosensory neurons that provide us with the sense of touch and pain. However, the molecular force sensors remain poorly identified. This project aims at defining the fundamental roles of mechanosensitive ion channels to sense and respond to various mechanical stimuli, and how their responses may encode mechanical cues.The ultimate goal is to provide a fundamentally new understanding of proprioception and motion sensing. The new multimodality approach generated in this project is expected to evolve as a national facility for neuro-mechanobiology, and future research may lead to the inspiration of novel bionic sensor design and brain-computer interface for future neuroengineering industry.Read moreRead less