Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100108
Funder
Australian Research Council
Funding Amount
$175,000.00
Summary
Ultra-high frequency non-contact vibrometry equipment for biomicrofluidics metrology. This equipment will enable experimental vibration measurement up to an unprecedented one billion cycles per second of motion smaller than the width of a helium atom (20 femtometres). Understanding and harnessing the phenomena unique to this regime, especially very large accelerations surpassing one billion times the acceleration of gravity, will enable the development of rapid protein crystallisation techniques ....Ultra-high frequency non-contact vibrometry equipment for biomicrofluidics metrology. This equipment will enable experimental vibration measurement up to an unprecedented one billion cycles per second of motion smaller than the width of a helium atom (20 femtometres). Understanding and harnessing the phenomena unique to this regime, especially very large accelerations surpassing one billion times the acceleration of gravity, will enable the development of rapid protein crystallisation techniques and constant-temperature organic chemical reaction enhancement for rapid development of new drugs, new devices for measuring the profile of surfaces at video speeds (videoAFM), new micro- and nano-devices for fluid pumping, mixing, colloidal separation and concentration, and new autonomous nanorobots for non-invasive microsurgery.Read moreRead less
Material boundaries in ultrasonics: New methods and in vitro studies in biomedical phantoms. Ultrasound is an indispensable part of healthcare worldwide. The next wave of applications will see ultrasound pulses used to closely probe suspected disease sites and to directly manipulate bioactive agents. For safe and effective use of such techniques it is essential to know the ultrasound field at the disease site. This project will develop simulation methods to achieve the fast, accurate and case-sp ....Material boundaries in ultrasonics: New methods and in vitro studies in biomedical phantoms. Ultrasound is an indispensable part of healthcare worldwide. The next wave of applications will see ultrasound pulses used to closely probe suspected disease sites and to directly manipulate bioactive agents. For safe and effective use of such techniques it is essential to know the ultrasound field at the disease site. This project will develop simulation methods to achieve the fast, accurate and case-specific results required. Community healthcare will benefit, through better diagnostic capabilities and customized treatment. Australia is well placed to profit further from this research, in view of the growing worldwide demand for more sophisticated, knowledge-based techniques in medicine.Read moreRead less
The effect of vessel wall structures on ultrasonic flow velocity measurements. The flow velocity within a nearly cylindrical vessel is often measured using an external ultrasound transducer via the Doppler principle. Thick vessel walls may present acoustically mismatched structures. This project aims to determine how such walls redistribute the energy in an interrogating ultrasound beam, and how this in turn affects the measurement of flow velocities. This is a fundamental issue, especially imp ....The effect of vessel wall structures on ultrasonic flow velocity measurements. The flow velocity within a nearly cylindrical vessel is often measured using an external ultrasound transducer via the Doppler principle. Thick vessel walls may present acoustically mismatched structures. This project aims to determine how such walls redistribute the energy in an interrogating ultrasound beam, and how this in turn affects the measurement of flow velocities. This is a fundamental issue, especially important in vascular disease where blood flow and blood vessels are affected by wall irregularities and lesions. The new knowledge generated by this project will have practical importance and, by identifying achievable outcomes, potentially major cost savings, in medical ultrasound.Read moreRead less