2019
DOI: 10.3791/58372
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Proton Therapy Delivery and Its Clinical Application in Select Solid Tumor Malignancies

Abstract: Radiation therapy is a frequently used modality for the treatment of solid cancers. Although the mechanisms of cell kill are similar for all forms of radiation, the in vivo properties of photon and proton beams differ greatly and maybe exploited to optimize clinical outcomes. In particular, proton particles lose energy in a predictable manner as they pass through the body. This property is used clinically to control the depth at which the proton beam is terminated, and to limit radiation dose beyond the target… Show more

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Cited by 7 publications
(6 citation statements)
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“…The mechanisms of cell-kill for all forms of radiation are similar, but proton particles predictably lose energy as they pass through the body compared with photon beams; this property could be exploited to optimize clinical outcomes. 43 Consequently, the depth of the termination of the proton beam is controllable, and the radiation dose beyond the target region can be restricted. Due to the esophagus's central location near several OARs of lymphopenia, including the heart, lungs, and spine, the ability of PBT to conform high radiation dose to the tumor volume while reducing the unintentional radiation dose to adjacent healthy tissues has the potential to decrease RIL.…”
Section: Radiation Technology-proton Beam Therapymentioning
confidence: 99%
“…The mechanisms of cell-kill for all forms of radiation are similar, but proton particles predictably lose energy as they pass through the body compared with photon beams; this property could be exploited to optimize clinical outcomes. 43 Consequently, the depth of the termination of the proton beam is controllable, and the radiation dose beyond the target region can be restricted. Due to the esophagus's central location near several OARs of lymphopenia, including the heart, lungs, and spine, the ability of PBT to conform high radiation dose to the tumor volume while reducing the unintentional radiation dose to adjacent healthy tissues has the potential to decrease RIL.…”
Section: Radiation Technology-proton Beam Therapymentioning
confidence: 99%
“…Nevertheless, the electron beam remains superior to brachytherapy for skin lesions because its excellent dose distribution results in a lower risk of internal organ exposure. 13,14 Thus, at present, the electron beam is the most effective and safest postoperative radiotherapy for keloids. However, it should be emphasised that despite the tremendous efficacy of postoperative radiotherapy in keloids, it is essential to maintain stringent safety standards.…”
Section: Introductionmentioning
confidence: 99%
“…The FLASH-RT effect may be achieved under various beam characteristic conditions vs. conventional electron beam irradiation, as summarized in Table 1. Typically, the FLASH-RT effect should provide a dose > 1 Gy, which is many orders of magnitude greater than the usual conventional electron pulse (<1 mGy/pulse) [11,12].…”
Section: Flash-rt Conditionsmentioning
confidence: 99%