Medical Physics applies the concepts and methods of physics to the diagnosis and therapy of human disease.
Modern medicine relies heavily on physical tools, techniques and principles developed in the physical sciences.
The complexity and precision required in the operation of the related diagnostic and therapeutic equipment and the quest to improve them has led to the subspecialty of Medical Physics.
A medical physicist applies scientific knowledge and technological skills to help prevent, diagnose and treat many kinds of diseases and health conditions. They are a mix of research and clinical scientists who play a pivotal role in providing physics support to various areas of the health sector to provide better outcomes for patients. They also ensure the safety of staff and patients exposed to radiation.
A medical physicist is typically a member of multidisciplinary team and may be involved in several activities relating to diagnosis and/or treatment in radiology, nuclear medicine or radiation therapy.
This programme is the only one of its kind in New Zealand.
The range of qualifications in Medical Physics is extensive, reflecting the demand for skilled graduates.
- Postgraduate Diploma in Science - see diploma regulations for required courses.
- Bachelor of Science with Honours - see degree regulations for required courses.
- Master of Science - see degree regulations for required courses.
- Master of Science in Medical Physics (Clinical) - see degree regulations for required courses.
- Doctor of Philosophy - see the course.
- Doctor of Philosophy in Medical Physics (Clinical) - see the course.
UC has a long history of research in in medical imaging, biomedical engineering and in radiation therapy.
We have a number of collaborations with industry and work closely with the University of Washington, Canterbury District Health Board, The New Zealand Brain Research Institute, and the University of Otago's Christchurch Medical School.
Advance radiotherapy techniques
- Intensity-modulated radiation therapy (IMRT) plan optimisation strategies
- Lung tumour tracking, modelling and adaptation
- Proton mini-beam treatment development
- Interferometry-based dosimetry systems
X-ray detection and imaging
- Development of a Medipix All Resolution Scanner (MARS) for spectroscopic CT imaging
Magnetic resonance imaging
- MRI studies of patients with Parkinson's disease
- Quantitive susceptibility mapping and cognitive impairment in Parkinson's