Nanoscale measurements of proton tracks using fluorescent nuclear track detectors

Sawakuchi, Gabriel O.; Ferreira, Felisberto Alves; McFadden, Conor H.; Hallacy, Timothy M.; Granville, D; Akselrod, M.S.

doi:10.1118/1.4947128

Cited by 21 publications

(33 citation statements)

References 22 publications

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“…In addition to solid‐state microdosimeters and tissue equivalent proportional counters, there are other detectors that have been used to perform measurements of LET, such as OSLDs and Fluorescent Nuclear Track detectors, for example. These detectors have an LET‐dependent response that can be calibrated to a known LET and then employed for LET measurements.…”

Section: Discussionmentioning

confidence: 99%

Microdosimetric measurements of a clinical proton beam with micrometer‐sized solid‐state detector

et al. 2017

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Purpose: Microdosimetry is a vital tool for assessing the microscopic patterns of energy deposition by radiation, which ultimately govern biological effect. Solid-state, silicon-on-insulator microdosimeters offer an approach for making microdosimetric measurements with high spatial resolution (on the order of tens of micrometers). These high-resolution, solid-state microdosimeters may therefore play a useful role in characterizing proton radiotherapy fields, particularly for making highly resolved measurements within the Bragg peak region. In this work, we obtain microdosimetric measurements with a solid-state microdosimeter (MicroPlus probe) in a clinical, spot-scanning proton beam of small spot size. Methods: The MicroPlus probe had a 3D single sensitive volume on top of silicon oxide. The sensitive volume had an active cross-sectional area of 250 lm 9 10 lm and thickness of 10 lm. The proton facility was a synchrotron-based, spot-scanning system with small spot size (r % 2 mm). We performed measurements with the clinical beam current (%1 nA) and had no detected pulse pile-up. Measurements were made in a water-equivalent phantom in water-equivalent depth (WED) increments of 0.25 mm or 1.0 mm along pristine Bragg peaks of energies 71.3 MeV and 159.9 MeV, respectively. For each depth, we measured lineal energy distributions and then calculated the dose-weighted mean lineal energy, y D . The measurements were repeated for two field sizes: 4 9 4 cm 2 and 20 9 20 cm Conclusions: We performed microdosimetric measurements with a novel solid-state, silicon-oninsulator microdosimeter in a clinical spot-scanning proton beam of small spot size and unmodified beam current. For all of the proton field sizes and energies considered, the measurements of y D were in agreement with expected trends. Furthermore, we obtained measurements with a spatial resolution of 10 lm in the beam direction. This spatial resolution greatly exceeded that possible with a conventional gaseous tissue-equivalent proportional counter and allowed us to perform a high-resolution investigation within the Bragg peak region. The MicroPlus probe is therefore suitable for applications in proton radiotherapy.

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Section: Discussionmentioning

confidence: 99%

Microdosimetric measurements of a clinical proton beam with micrometer‐sized solid‐state detector

et al. 2017

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“…Prior to incorporating a biophysical model into the treatment planning process, accurate measurements of the beam parameters need to be made. Verifying simulated LET values using, for example, nuclear track detectors might be warranted. Since LET may become an optimization parameter that will determine the plan quality, we may want to include LET measurements in patient‐specific QA in addition to dose …”

Section: Assessment Of Clinical Impact When Revising Current Practicementioning

confidence: 99%

Report of the AAPM TG‐256 on the relative biological effectiveness of proton beams in radiation therapy

et al. 2019

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The biological effectiveness of proton beams relative to photon beams in radiation therapy has been taken to be 1.1 throughout the history of proton therapy. While potentially appropriate as an average value, actual relative biological effectiveness (RBE) values may differ. This Task Group report outlines the basic concepts of RBE as well as the biophysical interpretation and mathematical concepts. The current knowledge on RBE variations is reviewed and discussed in the context of the current clinical use of RBE and the clinical relevance of RBE variations (with respect to physical as well as biological parameters). The following task group aims were designed to guide the current clinical practice: Assess whether the current clinical practice of using a constant RBE for protons should be revised or maintained. Identifying sites and treatment strategies where variable RBE might be utilized for a clinical benefit. Assess the potential clinical consequences of delivering biologically weighted proton doses based on variable RBE and/or LET models implemented in treatment planning systems. Recommend experiments needed to improve our current understanding of the relationships among in vitro, in vivo, and clinical RBE, and the research required to develop models. Develop recommendations to minimize the effects of uncertainties associated with proton RBE for well‐defined tumor types and critical structures.

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“…Other detectors, such as thermoluminescence detectors, plastic nuclear track detectors, and other solid state detectors, also can measure LET . Fluorescence nuclear track detectors can determine the LET of individual proton tracks . Although these detectors are capable of measuring LET, none can do so in real time, and their designs are too complex for use in daily quality assurance measurements.…”

Section: Introductionmentioning

confidence: 99%

A real‐time method to simultaneously measure linear energy transfer and dose for proton therapy using organic scintillators

et al. 2018

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Nanoscale measurements of proton tracks using fluorescent nuclear track detectors

Cited by 21 publications

References 22 publications

Microdosimetric measurements of a clinical proton beam with micrometer‐sized solid‐state detector

Microdosimetric measurements of a clinical proton beam with micrometer‐sized solid‐state detector

Report of the AAPM TG‐256 on the relative biological effectiveness of proton beams in radiation therapy

A real‐time method to simultaneously measure linear energy transfer and dose for proton therapy using organic scintillators

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