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Adaptation of the Egs4 Monte Carlo Fode for the Design of a Polarized Source for X-Ray Fluorescence Analysis of Platinum and Other Heavy Metals In Vivo

Published online by Cambridge University Press:  06 March 2019

D.G. Lewis ,
G. Lewis  and
C.A. Oggt
D.G. Lewis
Affiliation:
Swansea In Vivo Analysis Research Group Department of Physics, University of Wales, Swansea SA2 8PP, UK
G. Lewis
Affiliation:
Swansea In Vivo Analysis Research Group Department of Physics, University of Wales, Swansea SA2 8PP, UK
C.A. Oggt
Affiliation:
Swansea In Vivo Analysis Research Group Department of Medical Physics, Singleton Hospital, Swansea SA2 8QA, UK
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Extract

X-ray fluorescence (XRF) has become a well established technique for the measurement of trace levels of toxic heavy metals in vivo, including cadmium, platinum, mercury and lead (Mattsson et al.. 1987). The clinical motivation for the measurement of platinum (Pt) is the need to investigate the kinetics of Pt-based cancer chemotherapy drugs such as cisplatin and paraplatin. Currently the main research interest in Swansea lies in the study of the uptake and distribution of Pt administered during chemotherapy of patients with tumours in the head and neck region.

Information

Type
VIII. In Vivo Applications of XRS
Information
Advances in X-Ray Analysis , Volume 38: Forty-third Annual Conference on Applications of X-ray Analysis , 1994 , pp. 579 - 585
Copyright
Copyright © International Centre for Diffraction Data 1994

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References

Ali, PA, Lewis, DG, El-Sharkawi, AM, Al-Sadhan, FA, Evans, CJ, Hancock, DA and Dutton, J 1993 Initial measurements of platinum concentration in head and neck tumours using X-ray fluorescence, Human body composition ; in vivo methods, models and assessment eds. KJ Ellis and JD Eas:man (New York: Plenum) 281-84.Google Scholar
Birch, R and Marshall, M 1979 Computation of bremsstrahlung X-ray spectra and comparison with spectra measured with a Ge(Li) detector Phys. Med. Biol 24 505-17.Google Scholar
Borjesson, J, Alpsten, M, Huang, S, Jonson, R, Mattsson, S and Thornberg, C 1993 In vivo X-ray fluorescence analysis with applications to platinum, gold and mercury in man - experiments, improvements and patient measurements Human body composition : in vivo methods, models and assessment eds. KJ Ellis and JD Eastman (New York: Plenum) 275-80.Google Scholar
Hanson, AL 1986 The calculation of scattering cross-sections for polarized X-rays Nucl. Instr. Meth. Phys. Res. A243 583-98.Google Scholar
Jonson, R, Mattsson, S and Unsgaard, B 1988 A method for in vivo analysis of platinum after chemotherapy with cisplatin Phys. Med Biol 33 847857.Google Scholar
Lewis, DG 1994 Optimization of a polarized source for in vivo X-ray fluorescence analysis of platinum and other heavy metals Phys. Med. Biol. 34 197206.Google Scholar
Mattsson, S, Christofferson, JO, Jonson, R and Nilsson, U 1987 X-ray fluorescence technique for in vivo analysis of natural and administered trace elements In Vivo Body Composition Studies eds. KJ Ellis, S Yasamura and WD Morgan (London: IPSM) 318-24.Google Scholar
Namito, Y, Ban, S and Hirayama, H 1993 Implementation of linearly-polarized photon scattering into the EGS4 code Nucl. Instr. Meth. Phys. Res. A332 277-83.Google Scholar
Nelson, WR, Hirayama, H and Rogers, DWO 1985 SLAC-265 (Stanford Linear Accelerator Centre).Google Scholar
Ryon, RW and Zahrt, JD 1978 Improved X-ray fluorescence capabilities by excitation with high intensity polarized X-rays Adv. X-Ray Analysis 22 453-60.Google Scholar