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    Innovative Materials For Novel Devices: Contact Us For More Information

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    comsian
    The Institute for Superconducting and Electronic Materials (ISEM) is researching advanced materials with over 100 researchers for applications in medical devices, imaging, and more. ISEM is developing materials for non-invasive medical sensors, superconductors for new MRI machines, and ceramics for cancer treatment and radiation protection. ISEM turns research successes into commercial products using facilities at the Australian Institute for Innovative Materials.

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    Innovative Materials For Novel Devices: Contact Us For More Information

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    comsian
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    The Institute for Superconducting and Electronic Materials (ISEM) is researching advanced materials with over 100 researchers for applications in medical devices, imaging, and more. ISEM is developing materials for non-invasive medical sensors, superconductors for new MRI machines, and ceramics for cancer treatment and radiation protection. ISEM turns research successes into commercial products using facilities at the Australian Institute for Innovative Materials.

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    UOW ISME

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    The Institute for Superconducting and Electronic Materials (ISEM) is researching advanced materials with over 100 researchers for applications in medical devices, imaging, and more. ISEM is developing materials for non-invasive medical sensors, superconductors for new MRI machines, and ceramics for cancer treatment and radiation protection. ISEM turns research successes into commercial products using facilities at the Australian Institute for Innovative Materials.

    Copyright:

    © All Rights Reserved
    Download as PDF, TXT or read online from Scribd
    Download as pdf or txt
    33 views2 pages

    Innovative Materials For Novel Devices: Contact Us For More Information

    Uploaded by

    comsian
    The Institute for Superconducting and Electronic Materials (ISEM) is researching advanced materials with over 100 researchers for applications in medical devices, imaging, and more. ISEM is developing materials for non-invasive medical sensors, superconductors for new MRI machines, and ceramics for cancer treatment and radiation protection. ISEM turns research successes into commercial products using facilities at the Australian Institute for Innovative Materials.

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    © All Rights Reserved
    Download as PDF, TXT or read online from Scribd
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    Advanced materials for

    better medical technologies The Institute for Superconducting and Electronic Materials (ISEM) is a world-class cooperative
    research team working on the fields of energy, superconductivity and electronic material science and
    technology.

    Led by Professor Shi Xue Dou, an internationally renowned expert in the fields of advanced materials,
    ISEM has been instrumental in advancing these technologies in Australia.

    ISEM has a team of more than 100 researchers and postgraduate students with a track record of
    research breakthroughs that are helping to redefine the applications of advanced materials science.

    Innovative materials for novel devices

    Innovative new materials developed using thin


    film technologies can be applied in new and
    innovative ways to help create non-invasive
    medical diagnostic tools such as wearable
    pulsimeters that can measure blood pressure
    and heart rate quickly and easily. Image courtesy of collaborators at Sangji University, Korea

    Superconducting technology can also be used


    in the next generation of magnetic resonance
    imaging (MRI) machines.

    ISEM’s teams are working on innovative


    materials that have applications in medical
    devices, biomedical applications and
    telecommunications technologies.

    From research success to commercial


    success

    ISEM’s research programs are focussed on


    turning research success into the devices and
    materials that will change the way we go about
    our daily activities.

    The state-of-the-art facilities at the Australian


    Institute for Innovative Materials (AIIM) will
    allow breakthrough lab-based experiments to be
    transformed into commercial reality.

    Contact us for more information

    For more information on ISEM’s advanced materials research and commercial opportunities contact
    Professor Shi Xue Dou on +61 2 4221 5730 or via email at shi@uow.edu.au or visit ISEM’s website at
    www.isem.uow.edu.au
    Projects in advanced materials research for medical applications being undertaken at ISEM include:

    Project New MRI design using Magnesium Diboride superconducting coils

    Aims An alternative superconductor for Magnetic Resonance Imaging (MRI).

    Description MRI is a powerful diagnostic tool to visualise soft tissue and the superconducting magnet is the most
    expensive component of the system.
    ISEM has had a leading role in developing of commercially available inexpensive magnesium diboride
    wire in close collaboration with its industry partner, Hyper Tech Research Inc (HTR). Through
    optimisation and nano-doping ISEM has acquired patented technology for fabrication of MgB2 wire with
    record performance in critical current in magnetic field, satisfactory to commercial exploitation. HTR is
    capable of manufacture of multi-kilometre long wire with high reproducibility.

    Project Development of oriental medical pulsimeter using magnetic field sensing thin films

    Aims This project will develop a non-invasive medical pulsimeter to increase the reliability of the sensors,
    improve the ease of operation and reduce the cost of production.

    Description The pulsimeter sensor will use magnetic field sensing thin films with the pulse-sensing part array
    consisting of Giant Magneto Resistance-Spin Valve or Hall Effect Semiconductor devices that will detect
    changes in the magnetic field on contact with the skin, allowing the pulse to be measured through the
    detection of changes in the magnetic field.

    Project Advanced nano-ceramics for protective, diagnostic and therapeutic uses

    Aims These projects are aimed and the development of new materials for nano-theranostic use, radiation
    protection and UV blockers for sun protection.

    Description New ceramic-based materials are being developed include:


    Inorganic UV blockers to more efficiently and effective reduce UV expose across the entire UV range
    Metal oxides or carbon-based materials to deliver muntifunctionality and improved therapeutic and
    diagnostic nano-composites at a lower cost
    Researchers at ISEM are working collaboratively with the Illawarra Health and Medical Research Institute
    and the Centre for Medical Radiation Physics to develop ceramic composites for use in cancer therapy
    and to develop radiation protection drugs.
    Testing has shown a reduction of up to 50 per cent in cancer cell survival rates after 72 hours using these
    technologies. This is a substantial improvement on most chemotherapy drugs which typically reduce cell
    survival rates by 14 per cent over the same period.

    Project Novel multifunctional magnetic nano-composites for cancer diagnosis and hyperthermia therapies

    Aims To develop and study novel multifunctional magnetic nano-composite particles combining the
    improvements of the medical sensing of cancer MRI diagnosis and the efficiency of cancer magnetic
    hyperthermia therapies.

    Description Magnetic nanoparticles have been advocated for use in magnetic resonance image (MRI) enhancement
    and as bio-carriers in biological systems. However, it is only in recent years that the fields of
    nanotechnology, materials science, and cell biology have combined to enable us to fully comprehend
    the potential uses of such nanoparticles for more biomedical applications, such as magnetic fluid cancer
    hyperthermia (MFH).
    Researchers at ISEM have developed effective nanostructured materials production techniques that
    will allow a better understanding of methods to improve the efficacy of magnetic cancer diagnosis and
    therapies.

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