Q-Sand (TM): Whispering Gallery Mode Detection System For Ultrasensitive And Label Free Testing In Biotechnology.
Funder
National Health and Medical Research Council
Funding Amount
$127,750.00
Summary
Quantum Dots, a type of nanocrystal, have been shown to emit light at a very precise wavelength. Quantum dots of approximately 5 nm in diameter have been conjugated to a silica microsphere and then coated with free silica, thus encasing the Quantum Dots in a small chamber surrounding the microsphere. This structure is analogous to a light globe under a lampshade. Just as one can change the nature of the lamplight by changing the lampshade, one can change the Quantum Dot emitted light by changing ....Quantum Dots, a type of nanocrystal, have been shown to emit light at a very precise wavelength. Quantum dots of approximately 5 nm in diameter have been conjugated to a silica microsphere and then coated with free silica, thus encasing the Quantum Dots in a small chamber surrounding the microsphere. This structure is analogous to a light globe under a lampshade. Just as one can change the nature of the lamplight by changing the lampshade, one can change the Quantum Dot emitted light by changing the surface of the microsphere. Since the scale is so small (each microsphere is about the size of a single bacterial cell), the amount and nature of the material needed to bind to the surface to effect a detectable change is also very small, on the order of just of few tens or hundreds of molecules. This project seeks to exploit this principle to create a new class of ultra sensitive detector which can be used in many sorts of applications such as medical diagnostics and biosensing.Read moreRead less
Our current understanding of cellular signalling and disease is based on ensemble measurements over a cellular or molecular population. While these measurements have provided valuable information on the molecular circuitry required for cellular function, there is a lack of detail on the spatio-temporal dynamics of signal initiation and propagation at the single molecule and single cellular level. Single particle (molecule or cell) approaches offer the advantage of being able to detect individual ....Our current understanding of cellular signalling and disease is based on ensemble measurements over a cellular or molecular population. While these measurements have provided valuable information on the molecular circuitry required for cellular function, there is a lack of detail on the spatio-temporal dynamics of signal initiation and propagation at the single molecule and single cellular level. Single particle (molecule or cell) approaches offer the advantage of being able to detect individual processes including rare events that would be lost in an ensemble measurement. Moreover single particle approaches provide dynamic-kinetic information that does not rely on synchronising a population of molecules or cells. In this proposal we aim to build on our combined expertise in EGF-EGFR signalling, biophysics, biosensors, quantum dot nanotechnology and single molecule spectroscopy to learn more about how EGFR cellular signalling works and how it is impaired in cancer. This project will provide basic information that could lead to the design of more effective drugs directed agaisnt this therapeutic target.Read moreRead less