Osteoporosis & Bone Biology Division
The Garvan Institute is one of Australia’s leading medical research institutions with approximately 500 scientists, students and support staff working in research programs in Cancer, Diabetes & Obesity, Immunology & Inflammation, Osteoporosis, and Neuroscience.As part of a strategic initiative the Institute is seeking to expand and strengthen the Osteoporosis and Bone Biology Division through recruitment and investment.
We are now seeking a driven post - doctoral scientist with interests in genetics, and genome informatics to join the laboratory of Professor Peter Croucher. These positions will aim to address two critical areas in Bone Research. The first is in defining new molecular determinants of bone mass and developing new approaches to stimulating bone repair. The second is investigating the cellular and molecular mechanisms responsible for tumour development in the skeleton and the development of therapeutic approaches to preventing tumour growth and the associated bone destruction.
The laboratory utilises mouse genetics and mammalian models of disease coupled with contemporary imaging techniques, including multi-photon imaging to study these areas.
To find out more about this position please check out our website:
The Garvan Institute is one of Australia’s leading medical research institutions with approximately 500 scientists, students and support staff working in research programs in Cancer, Diabetes & Obesity, Immunology & Inflammation, Osteoporosis, and Neuroscience.As part of a strategic initiative the Institute is seeking to expand and strengthen the Osteoporosis and Bone Biology Division through recruitment and investment.
We are now seeking a driven post - doctoral scientist with interests in genetics, and genome informatics to join the laboratory of Professor Peter Croucher. These positions will aim to address two critical areas in Bone Research. The first is in defining new molecular determinants of bone mass and developing new approaches to stimulating bone repair. The second is investigating the cellular and molecular mechanisms responsible for tumour development in the skeleton and the development of therapeutic approaches to preventing tumour growth and the associated bone destruction.
The laboratory utilises mouse genetics and mammalian models of disease coupled with contemporary imaging techniques, including multi-photon imaging to study these areas.
To find out more about this position please check out our website: