A miniature X‐ray tube approach to measuring lead in bone using L‐XRF |
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Authors: | David E. B. Fleming Mihai R. Gherase Kevin M. Alexander |
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Affiliation: | Physics Department, Mount Allison University, 67 York Street, Sackville, New Brunswick, Canada E4L 1E6 |
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Abstract: | Using a miniature X‐ray tube and silicon PiN diode detector, an approach to measuring lead (Pb) in bone phantoms was tested. The X‐ray tube was used to excite L‐line X‐ray fluorescence (L‐XRF) of lead in bone phantoms. The bone phantoms were made from plaster of Paris and dosed with varying quantities of lead. Phantoms were made in two sets with different shapes to model different bone surfaces. One set of bone phantoms was circular in cross‐section (2.5‐cm diameter), the other square in cross‐section (2.2 cm × 2.2 cm). Using an irradiation time of 180 s (real time), five trials were run for each bone phantom. Analysis was performed for both Lα and Lβ lead X‐rays. Based on these calibration trials, (3σ0/slope) minimum detection limits of 7.4 ± 0.3 µg Pb g?1 (circular cross‐section) and 8.6 ± 0.6 µg Pb g?1 (square cross‐section) were determined for the bare bone phantoms. To simulate a more realistic in vivo scenario with soft tissue overlying bone, further trials were performed with a resin material placed between the experimental system and the bone phantom. For the square cross‐section bone phantoms, a layer of resin with a thickness of 1.2 mm was used, and a minimum detection limit of 17 ± 3 µg Pb g?1 determined. For the circular cross‐section phantoms, a layer of resin with an average thickness of 2.7 mm was used. From these, a more realistic minimum detection limit for in vivo applications (43 ± 7 µg Pb g?1) was determined. Copyright © 2011 John Wiley & Sons, Ltd. |
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