Lesson 16 - Oregon State Universityoregonstate.edu/instruct/ch374/ch418518/lesson16.pdf · Special...
Transcript of Lesson 16 - Oregon State Universityoregonstate.edu/instruct/ch374/ch418518/lesson16.pdf · Special...
Lesson 16
Nuclear Medicine
What is Nuclear Medicine? • Diagnosis and Treatment of Disease using
small amounts of radio-nuclides (radiopharmaceuticals)
• In diagnosis (imaging) emitted radiation is detected by special detectors (cameras) from injected radio-nuclides to give real time 3 D images of the body.
• In treatment, radio-nuclides are injected into the body, concentrated in the organ of choice and damage the tissue.
Importance of Nuclear Medicine to students
• Combines nuclear and radiochemistry, pharmacy, medicine, and radiation biology.
• Nuclear medicine is a major employer of today’s nuclear and radiochemists, with an ever increasing demand for trained people.
• Six figure starting salaries
Special properties of 99Tcm
• 142.7 keV gamma ray just perfect for imaging
• 6 hour t1/2 minimizes radiation dose yet is tractable for hospital procedures
• 10 million procedures per year in the US
The 99Mo-> 99Tc decay is an example of transient equilibrium
Milking
Production of 99Mo
Details and Problems
• Currently AECL/MDS Nordion supply 40% of the world’s demand for 99Mo/99Tc.
• Chemistry is performed on the irradiated targets by AECL resulting in a 99Mo soln.
• The soln is shipped to MDS Nordion where it is loaded on the column and distributed.
• The US demand requires about 34,000-46,000 Ci are produced per week.
What is the Crisis? • These old reactors are nearing the end of
their lifetime and their operation is not reliable.
• Recently the Canadian and Dutch reactors underwent prolonged shutdowns
• US use of 99Mo was curtailed and rationed. • President Obama gave orders to Steven
Chu (Sec. of Energy) to “solve the problem.”
Special Problems for the US • We have no domestic supply of 99Mo. US
production was stopped in 1989. (It was claimed that non-US suppliers were subsidized and we could not compete.)
• High cost production facilities, risk of reactor operations, low market price
• The best techniques involve the use of HEU (19.7 % 235U) which poses a national security problem.
• The waste from the production is significant.
Positron Emission Tomography (PET)
• PET imaging provides quantitative information about biochemical and physiological processes, in vivo
• A tracer containing a positron emitter is injected, it decays emitting positrons and one detects the two 0.511 MeV photons resulting from the annihilation of the positron-electron interaction.
Special things you can do with PET
• Real time imaging of brain functions. Effect of drugs, Alzheimer’s disease, psychiatry.
• 90% of use in oncology • Pharmacology
Therapy • Oldest aspect of nuclear medicine • Idea is to use radiation to kill unhealthy cells • Problem is to do this without killing all the
healthy cells. • A problem is that cancer cells are less
oxygenated than normal cells and are more radiation resistant.
• One trick is physical location, ie, fix the radionuclide in a cancer cell so that the decay will preferentially damage the cancer cell.
Tricks • BNCT (Boron neutron cancer therapy) • Attach boron compounds to tumor
locations. • Boron has a very high thermal neutron
capture cross section • n+10B-> 11B->7Li + 4He
• Re-oxygenation
Bragg Curve Dosimetry
Thanks to