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SU‐F‐I‐56: High‐Precision Gamma‐Ray Analysis of Medical Isotopes
Author(s) -
Chopra N,
Chillery T,
McCutchan E,
Chowdhury P,
Smith C,
Lister C
Publication year - 2016
Publication title -
medical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.473
H-Index - 180
eISSN - 2473-4209
pISSN - 0094-2405
DOI - 10.1118/1.4955884
Subject(s) - isotope , physics , semiconductor detector , radiochemistry , nuclear physics , gamma ray , detector , nuclear medicine , chemistry , optics , medicine
Purpose: Advanced, time‐resolved, Compton‐suppressed gamma‐ray spectroscopy with germanium detectors is implemented for assaying medical isotopes to study the radioactive decay process leading to a more accurate appraisal of the received dose and treatment planning. Lowell's Array for Radiological Assay (LARA), a detector array that is comprised of six Compton‐suppressed high‐purity germanium detectors, is currently under development at UMass‐Lowell which combines Compton‐suppression and time‐and‐angle correlations to allow for highly efficient and highly sensitive measurements. Methods: Two isotopes produced Brookhaven Linac Isotope Producer (BLIP) were investigated. 82 Sr which is the parent isotope for producing 82 Rb is often used in cardiac PET. 82 Sr gamma‐ray spectrum is dominated by the 511keV photons from positron annihilation which prevent precise measurement of co‐produced contaminant isotopes. A second project was to investigate the production of platinum isotopes. Natural platinum was bombarded with protons from 53MeV to 200MeV. The resulting spectrum was complicated due to the large number of stable platinum isotopes in the target, the variety of open reaction channels (p,xn), (p,pxn), (p,axn). Results: By using face‐to‐face NaI(Tl) counters 90‐degrees to the Compton‐suppressed germaniums to detect the 511keV photons, a much cleaner and more sensitive measurement of 85 Sr and other contaminants was obtained. For the platinum target, we identified the production of 188–189–191–195 Pt, 191–192–193–194–195–196 Au and 186–188–189–190–192–194–189–190–192–194 Ir. For example, at the lower energies (53 and 65MeV), we measured 191 Pt production cross‐sections of 144mb and 157mb. Considerable care was needed in following the process of dissolving and diluting the samples to get consistent results. The new LARA array will help us better ascertain the absolute efficiency of the counting system and more reliable production cross‐sections. Conclusion: Modern HPGe spectroscopic techniques provide enhanced sensitivity, promising precise quantification of the quality of radioisotopes used in medical physics. Using new decay information may have non‐trivial impact on treatment planning and dose‐assessment.

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