On‐line monitoring of radiotherapy beams: Experimental results with proton beams

Litzenberg, Dale W.; Roberts, D. A.; Lee, M. Y.; Pham, Kevin; Molen, A. M. Vander; Ronningen, R. M.; Becchetti, F. D.

doi:10.1118/1.598491

Cited by 99 publications

(77 citation statements)

References 45 publications

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“…Proton and heavy ion radiotherapy is now utilized in the treatment of cancer [10]. These beams produce nuclear fragments, including short-lived isotopes such as 11 C, and these can contribute significant dosage.…”

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confidence: 99%

Reaction and proton-removal cross sections ofLi6,Be7
Warner¹,
Cârstoiu²,
Brown³
et al. 2006
Phys. Rev. C
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Excitation functions for total reaction cross sections, σR, were measured for the light, mainly proton-rich nuclei 6 Li, 7 Be, 10 B, 9,10,11 C, 12 N, 13,15 O, and 17 Ne incident on a Si telescope at energies between 15 and 53 MeV/nucleon. The telescope served as target, energy degrader and detector. Proton-removal cross sections, σ2p for 17 Ne and σp for most of the other projectiles, were also measured. The strong absorption model reproduces the A-dependence of σR, but not the detailed structure. Glauber multiple scattering theory and the JLM folding model provided improved descriptions of the measured σR values. rms radii, extracted from the measured σR using the optical limit of Glauber theory, are in good agreement with those obtained from high energy data. Oneproton removal reactions are described using an extended Glauber model, incorporating second order noneikonal corrections, realistic single particle densities, and spectroscopic factors from shell model calculations.

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confidence: 99%

Reaction and proton-removal cross sections ofLi6,Be7
Warner¹,
Cârstoiu²,
Brown³
et al. 2006
Phys. Rev. C
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39
2
37
0
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“…The human body comprises carbon, nitrogen, oxygen, and hydrogen, and the main composition is carbon and oxygen. 22 For 16 O and 12 C nuclei, positron emitter nuclei of 15 O and 11 C are generated by X ray beams of energies exceeding 15.7 and 18.7 MeV, respectively. These are summarized in the following equations.…”

Section: Methodsmentioning

confidence: 99%

“…[12][13][14][15][16] For high-energy photon treatment, the use of PET-CT at 50 MV was proposed; and experimental results [17][18][19][20] and Monte Carlo calculation results were also reported for in-beam PET imaging. 21 The purpose of this article is to show that 15 O and 11 C positron emitter nuclei can be detected using a commercial PET-CT in the photonuclear reaction with X-ray energy as low as 21 MV. Furthermore, the PET-CT image obtained from such activity can provide the area of X-ray beam irradiation in a phantom.…”

Section: Introductionmentioning

confidence: 99%

Experimental verification of the utility of positron emitter nuclei generated by photonuclear reactions for X-ray beam monitoring in a phantom

Nishio

Inaniwa

Inoue³

et al. 2007

Radiat Med

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“…This might also have applications in the PET imaging of β + emitters produced in proton-beam [12] or heavy-ion beam radiotherapy. Related to this is the possibility of using magnetic confinement in selected brachytherapy treatments where, again, one might be dealing with high-energy hence long-range charged, radioactivedecay particles (β − , β + , or α's).…”

Section: Future Workmentioning

confidence: 99%

Magnetic confinement of radiotherapy beam-dose profiles

Becchetti¹,

Litzenberg²,

Moran³

et al. 2001

AIP Conference Proceedings

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We have used electron and photon beams from the 50 MV electron microtron at UM Hospital together with a large-bore 3.5T superconducting solenoid to demonstrate the magnetic confinement of HE electron and photon beam-dose profiles for typical radiotherapy beams. The HE electron beams in particular exhibit a large reduction in penumbra when entering a tissueequivalent phantom and, in addition, confinement of the secondary electrons produced by the primary beam. Likewise photon beams show a similar confinement of the dose from secondary electrons. While the results resemble features predicted from Monte Carlo calculations, there are a number of anomalous details in the actual experimental data which serve to illustrate the problems associated with practical clinical implementations. However the data suggest that in certain cases HE electrons may provide a cost-effective alternate to proton or HI radiotherapy beams and, also, improve the dose profile for HE photon beams.

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On‐line monitoring of radiotherapy beams: Experimental results with proton beams

Cited by 99 publications

References 45 publications

Reaction and proton-removal cross sections ofLi6,Be7
Warner¹,
Cârstoiu²,
Brown³
et al. 2006
Phys. Rev. C
Self Cite
39
2
37
0
View full text Add to dashboard Cite

Reaction and proton-removal cross sections ofLi6,Be7
Warner¹,
Cârstoiu²,
Brown³
et al. 2006
Phys. Rev. C
Self Cite
39
2
37
0
View full text Add to dashboard Cite

Experimental verification of the utility of positron emitter nuclei generated by photonuclear reactions for X-ray beam monitoring in a phantom

Magnetic confinement of radiotherapy beam-dose profiles

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On‐line monitoring of radiotherapy beams: Experimental results with proton beams

Cited by 99 publications

References 45 publications

Reaction and proton-removal cross sections ofLi6,Be7Warner1, Cârstoiu2, Brown3 et al. 2006Phys. Rev. CSelf Cite392370View full textAdd to dashboardCite

Reaction and proton-removal cross sections ofLi6,Be7Warner1, Cârstoiu2, Brown3 et al. 2006Phys. Rev. CSelf Cite392370View full textAdd to dashboardCite

Experimental verification of the utility of positron emitter nuclei generated by photonuclear reactions for X-ray beam monitoring in a phantom

Magnetic confinement of radiotherapy beam-dose profiles

Contact Info

Product

Resources

About

Reaction and proton-removal cross sections ofLi6,Be7
Warner¹,
Cârstoiu²,
Brown³
et al. 2006
Phys. Rev. C
Self Cite
39
2
37
0
View full text Add to dashboard Cite

Reaction and proton-removal cross sections ofLi6,Be7
Warner¹,
Cârstoiu²,
Brown³
et al. 2006
Phys. Rev. C
Self Cite
39
2
37
0
View full text Add to dashboard Cite