Background-free imaging of single membrane-receptors with nanophosphors. This project aims to develop nanophosphor beacons and real-time, ultrahigh-sensitivity functional imaging to provide a picture of the brain. Time-gated detection microscopy will give these nanophosphors a superior optical contrast. The nanophosphors’ antibody-targeting will image single AMPA membrane receptors in their full biological context, crucial to understanding neuronal signalling. Simultaneous imaging of receptor tr ....Background-free imaging of single membrane-receptors with nanophosphors. This project aims to develop nanophosphor beacons and real-time, ultrahigh-sensitivity functional imaging to provide a picture of the brain. Time-gated detection microscopy will give these nanophosphors a superior optical contrast. The nanophosphors’ antibody-targeting will image single AMPA membrane receptors in their full biological context, crucial to understanding neuronal signalling. Simultaneous imaging of receptor trafficking and activity in neurons will help to uncover details of the dynamic activity in the brain. This technology is expected to help understand the inner workings of the brain and provide insights into its functioning.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100067
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
The Vevo 2100 Micro-ultrasound plus LAZR Photoacoustic Imaging Platform . The Vevo 2100 micro-ultrasound plus LAZR photoacoustic imaging platform: The Vevo/LAZR ultrasound/photoacoustic imaging facility will allow researchers to achieve multiple outcomes: to visualise and quantify, non-invasively, tissue and molecular structures; the movement and behaviour of cells; and the delivery patterns of administered imaging dyes and nanoparticles in mouse models and reconstructed tissues. This will enabl ....The Vevo 2100 Micro-ultrasound plus LAZR Photoacoustic Imaging Platform . The Vevo 2100 micro-ultrasound plus LAZR photoacoustic imaging platform: The Vevo/LAZR ultrasound/photoacoustic imaging facility will allow researchers to achieve multiple outcomes: to visualise and quantify, non-invasively, tissue and molecular structures; the movement and behaviour of cells; and the delivery patterns of administered imaging dyes and nanoparticles in mouse models and reconstructed tissues. This will enable researchers to obtain anatomical, functional, physiological and molecular data simultaneously and in real-time, with resolution down to 40 micrometres. This will translate into both user efficiency and laboratory cost effectiveness, but more significantly is expected to result in greater understanding of fundamental mechanisms regulating the body's cell and tissue functions.Read moreRead less
Seeing is believing: Microscopy-capable single-molecule bioelectronics. This project aims to create new biophysical tools for single-molecule sensing by advancing the state-of-the-art in nanoscale bioelectronic devices. The goal is to generate novel bioelectronic devices optimised for fabrication on microscope coverslip (170 micron glass) for compatibility with new low-cost platforms for advanced biological microscopy. Expected outcomes include the first organic electrochemical transistors inter ....Seeing is believing: Microscopy-capable single-molecule bioelectronics. This project aims to create new biophysical tools for single-molecule sensing by advancing the state-of-the-art in nanoscale bioelectronic devices. The goal is to generate novel bioelectronic devices optimised for fabrication on microscope coverslip (170 micron glass) for compatibility with new low-cost platforms for advanced biological microscopy. Expected outcomes include the first organic electrochemical transistors interfaced to constrained area lipid bilayers for studying membrane proteins at single-molecule level and nanoscale transistors for electrostatically detecting motile microtubules in in-vitro molecular motor assays for biocomputation. The intended benefit is innovation in capabilities and manufacturing of bioelectronics.Read moreRead less
Synergistic nanostimulation of nerve cells using atomic force microscopy technology. The research will develop multifunctional nanoelectrodes for neural prosthetic devices of the future. They will be smaller and more effective, enabling integration with single neural networks in the body, to improve the clinical treatment of severe neurological disorders and loss of sensory (hearing and vision) and motor functions.
Discovery Early Career Researcher Award - Grant ID: DE150100564
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Vascularized tumour models to elucidate the delivery of nanomedicine agents. This inter-disciplinary project aims to develop advances in in vitro models aimed at elucidating the delivery and transport of diagnostic and therapeutic nanomedicine agents in tumour tissues. The project aims to build on advanced tissue engineering principles and state-of-the-art micro-fabrication technologies to remove the limitation associated with animal studies and provide unprecedented mechanistic insights into th ....Vascularized tumour models to elucidate the delivery of nanomedicine agents. This inter-disciplinary project aims to develop advances in in vitro models aimed at elucidating the delivery and transport of diagnostic and therapeutic nanomedicine agents in tumour tissues. The project aims to build on advanced tissue engineering principles and state-of-the-art micro-fabrication technologies to remove the limitation associated with animal studies and provide unprecedented mechanistic insights into the delivery, transport and binding of nanomedicines into tumour tissues.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100295
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Computational modelling of nanostructures designed to mimic ion-selective biological channels. The project aims to design nanotubes (hollow tubes with nanometre diameters) constructed from various materials, such as carbon, to broadly mimic biological ion channels. This research will facilitate the development of efficient desalination membranes, potent antibiotics and pharmaceutical products for treatments of cancer and cystic fibrosis.