1. Where’s the Physics in Medicine?
Richard Watts
Director of MR Research, Van der Veer Institute
Dept. of Physics and Astronomy
University of Canterbury
6th July 2009, NZIP

2. Therapy Diagnostic Imaging Therapy MRI Nuclear Imaging X-Ray
6th July 2009, NZIP

3. X-Ray Imaging Contrast: Density, Atomic Number
source
Object
Detector
December 22nd, 1895
Wilhelm Roentgen
“Builder survives nailgun accident”
Phil and Anthony Butler, UC and MARS Bioimaging

4. Pneumoencephalography
Pneumoencephalogram from Moore et al (1935) 'Encephalographic studies in mental disease' - American Journal of Psychiatry
6th July 2009, NZIP

5. Medipix – Spectroscopic X-ray Imaging (CERN) Separate Density and Atomic Number
“Colour X-ray Imaging”
6th July 2009, NZIP

6. Computed Tomography (CT) 3D X-Ray Imaging
6th July 2009, NZIP

7. Computed Tomography (CT) 3D X-Ray Imaging
6th July 2009, NZIP

8. Computed Tomography (CT) 3D X-Ray Imaging
Prototype MARS Spectroscopic
CT scanner
6th July 2009, NZIP
CT Scanner rotating

9. Nuclear Imaging, Gamma Camera (1957) Contrast: Concentration of radiopharmaceutical
6th July 2009, NZIP

10. Radiopharmaceuticals for Nuclear Imaging
Parent
Decay Mode
Half-life
Daughter
Decay Product
69Ge
Germanium EC
271 days
68Ga
Gallium
β+, EC
68 min
68Zn
Zinc
81Rb
Rubidium
4.5 hr
81mKr
Krypton IT
13.5 s
81Kr
82St
Strontium
25.5 days
82Rb β+
75 s
82Kr
99Mo
Molybdenum β-
67 hr
99mTc
Technetium
6 hr
99Tc
EC = Electron capture, IT = Isometric transition
6th July 2009, NZIP

11. Single Photon Emission Computed Tomography, SPECT 3D Nuclear Imaging
6th July 2009, NZIP
Bushberg, Essential Physics of Medical Imaging

12. Positron Emission Tomography (PET)
6th July 2009, NZIP
18F-FDG, T1/2 ~ 2 hours

13. Magnetic Resonance Imaging, (n)MRI
“You know, what these people do is really clever. They put little spies into molecules and send radio signals to them, and then they have to radio back what they are seeing.”
Niels Bohr
Hydrogen Nuclei are aligned by a big Magnetic Field
Resonant frequency given by Larmor equation
Nuclei absorb radiofrequency energy at that frequency and then re-emit energy
Magnetic field gradient coils allow the field (and resonant frequency) to vary with location in x,y,z – Imaging
6th July 2009, NZIP

14. Guess who?
6th July 2009, NZIP

15. Structural Brain Imaging with MRI
T2 FLAIR
Apparent Diffusion Coefficient
Fractional Anisotropy
T2*
6th July 2009, NZIP

16. Functional MRI of Language – Passive Listening, Rhyming
Magnetic properties of oxyhemoglobin and deoxyhemoglobin
L. Pauling and C. Coryell, PNAS USA 22: (1936)
6th July 2009, NZIP

17. Normal tissue complication probability Tumour control probability
Radiation therapy
Normal tissue complication probability
Tumour control probability
Cure
Response
Dose
6th July 2009, NZIP

18. Linear Accelerator (linac)
6th July 2009, NZIP

19. Intensity-Modulated Radiotherapy (IMRT)
High
Dose
Region
Constrained inverse problem
Tumour
Inverse planning
Optimization
Ill-posed problem
-> find best trade-off
Patient
Intensity Modulated
Cross -
section
Beam
Profiles
6th July 2009, NZIP
Linear Accelerator (linac)
Juergen Meyer, UC

20. Summary
Physics has made, and continues to make essential contributions to modern medicine
Imaging
X-ray imaging (Medipix/MARS)
Nuclear imaging
MRI (Functional imaging)
Radiation therapy
Accelerator physics
Treatment planning, Monte Carlo modeling
“Blue sky” research results in important unexpected technology (e.g. PET)
Medical physics
Excellent career prospects
Using physics to improve health
6th July 2009, NZIP