Calibration of the delayed-gamma neutron activation facility

Ma, R; Zhao, X; Rarback, H M; Yasumura, S; Dilmanian, F A; Moore, R I; Lo Monte, A F; Vodopia, K A; Liu, H B; Economos, C D; Nelson, M E; Aloia, J F; Vaswani, A N; Weber, D A; Pierson, Jr, R N; Joel, D D

doi:10.1118/1.597718

Title: Calibration of the delayed-gamma neutron activation facility

Journal Article · Thu Feb 01 00:00:00 EST 1996 · Medical Physics

DOI:https://doi.org/10.1118/1.597718· OSTI ID:278675

Ma, R; Zhao, X; Rarback, H M; Yasumura, S; Dilmanian, F A; Moore, R I; Lo Monte, A F; Vodopia, K A; Liu, H B; Economos, C D; Nelson, M E; Aloia, J F; Vaswani, A N; Weber, D A; Pierson, Jr, R N; Joel, D D ^[1]

Medical Department, Brookhaven National Laboratory, Upton, New York 11973 (United States)

The delayed-gamma neutron activation facility at Brookhaven National Laboratory was originally calibrated using an anthropomorphic hollow phantom filled with solutions containing predetermined amounts of Ca. However, 99{percent} of the total Ca in the human body is not homogeneously distributed but contained within the skeleton. Recently, an artificial skeleton was designed, constructed, and placed in a bottle phantom to better represent the Ca distribution in the human body. Neutron activation measurements of an anthropomorphic and a bottle (with no skeleton) phantom demonstrate that the difference in size and shape between the two phantoms changes the total body calcium results by less than 1{percent}. To test the artificial skeleton, two small polyethylene jerry-can phantoms were made, one with a femur from a cadaver and one with an artificial bone in exactly the same geometry. The femur was ashed following the neutron activation measurements for chemical analysis of Ca. Results indicate that the artificial bone closely simulates the real bone in neutron activation analysis and provides accurate calibration for Ca measurements. Therefore, the calibration of the delayed-gamma neutron activation system is now based on the new bottle phantom containing an artificial skeleton. This change has improved the accuracy of measurement for total body calcium. Also, the simple geometry of this phantom and the artificial skeleton allows us to simulate the neutron activation process using a Monte Carlo code, which enables us to calibrate the system for human subjects larger and smaller than the phantoms used as standards. {copyright} {ital 1996 American Association of Physicists in Medicine.}

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Research Organization:: Brookhaven National Lab. (BNL), Upton, NY (United States)

DOE Contract Number:: AC02-76CH00016

OSTI ID:: 278675

Journal Information:: Medical Physics, Vol. 23, Issue 2; Other Information: PBD: Feb 1996

Country of Publication:: United States

Language:: English

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56 BIOLOGY AND MEDICINE
APPLIED STUDIES
NEUTRON ACTIVATION ANALYZERS
CALIBRATION
ACCURACY
CALCIUM
DELAYED GAMMA RADIATION
DELAYED NEUTRON ANALYSIS
MONTE CARLO METHOD
PHANTOMS
SIMULATION
SKELETON
TISSUE-EQUIVALENT MATERIALS

Title: Calibration of the delayed-gamma neutron activation facility

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