Simulation study of protoacoustics as a real‐time in‐line dosimetry tool for FLASH proton therapy

Kim, Kaitlyn; Pandey, Prabodh Kumar; Gonzalez, Gilberto; Chen, Yong; Xiang, Liangzhong

doi:10.1002/mp.16894

Cited by 5 publications

(1 citation statement)

References 72 publications

(125 reference statements)

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“…Based on the foregoing, simulation studies have already indicated the potential of RAI in capturing images of FLASH beams, applicable to both protons (Kim et al 2023) and electrons (Ba Sunbul et al 2021). Notably, recent experimental research has showcased the use of RAI with two linear arrays in an orthogonal setup for detecting the edges of FLASH electron beams up to 25 cGy, proving its feasibility (Oraiqat et al 2020).…”

Section: Introductionmentioning

confidence: 99%

4D in vivo dosimetry for a FLASH electron beam using radiation-induced acoustic imaging

Bjegovic,

Sun,

Pandey

et al. 2024

Phys. Med. Biol.

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Objective:The primary goal of this research is to demonstrate the feasibility of radiation-induced acoustic imaging (RAI) as a volumetric dosimetry tool for ultra-high dose rate FLASH electron radiotherapy (FLASH-RT) in real time. This technology aims to improve patient outcomes by accurate measurements of in vivo dose delivery to target tumor volumes.Approach:The study utilized the FLASH-capable eRT6 LINAC to deliver electron beams under various doses (1.2 Gy/pulse to 4.95 Gy/ pulse) and instantaneous dose rates (1.55×105 Gy/s to 2.75×106 Gy/s), for imaging the beam in water and in a rabbit cadaver with RAI. A custom 256-element matrix ultrasound array was employed for real-time, volumetric (4D) imaging of individual pulses. This allowed for the exploration of dose linearity by varying the dose per pulse and analyzing the results through signal processing and image reconstruction in RAI.Main Results:By varying the dose per pulse through changes in source-to-surface distance (SSD), a direct correlation was established between the peak-to-peak amplitudes of pressure waves captured by the RAI system and the radiochromic film dose measurements. This correlation demonstrated dose rate linearity, including in the FLASH regime, without any saturation even at an instantaneous dose rate up to 2.75×106 Gy/s. Further, the use of the 2D matrix array enabled 4D tracking of FLASH electron beam dose distributions on animal tissue for the first time.Significance:This research successfully shows that 4D in vivo dosimetry is feasible during FLASH-RT using a RAI system. It allows for precise spatial (~mm) and temporal (25 frames/s) monitoring of individual FLASH beamlets during delivery. This advancement is crucial for the clinical translation of FLASH-RT as enhancing the accuracy of dose delivery to the target volume the safety and efficacy of radiotherapeutic procedures will be improved.

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Section: Introductionmentioning

confidence: 99%

4D in vivo dosimetry for a FLASH electron beam using radiation-induced acoustic imaging

Bjegovic,

Sun,

Pandey

et al. 2024

Phys. Med. Biol.

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Toward real‐time, volumetric dosimetry for FLASH‐capable clinical synchrocyclotrons using protoacoustic imaging

Wang,

Gonzalez,

Owen

et al. 2024

Medical Physics

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BackgroundFast low angle shot hyperfractionation (FLASH) radiotherapy (RT) holds promise for improving treatment outcomes and reducing side effects but poses challenges in radiation delivery accuracy due to its ultra‐high dose rates. This necessitates the development of novel imaging and verification technologies tailored to these conditions.PurposeOur study explores the effectiveness of proton‐induced acoustic imaging (PAI) in tracking the Bragg peak in three dimensions and in real time during FLASH proton irradiations, offering a method for volumetric beam imaging at both conventional and FLASH dose rates.MethodsWe developed a three‐dimensional (3D) PAI technique using a 256‐element ultrasound detector array for FLASH dose rate proton beams. In the study, we tested protoacoustic signal with a beamline of a FLASH‐capable synchrocyclotron, setting the distal 90% of the Bragg peak around 35 mm away from the ultrasound array. This configuration allowed us to assess various total proton radiation doses, maintaining a consistent beam output of 21 pC/pulse. We also explored a spectrum of dose rates, from 15 Gy/s up to a FLASH rate of 48 Gy/s, by administering a set number of pulses. Furthermore, we implemented a three‐dot scanning beam approach to observe the distinct movements of individual Bragg peaks using PAI. All these procedures utilized a proton beam energy of 180 MeV to achieve the maximum possible dose rate.ResultsOur findings indicate a strong linear relationship between protoacoustic signal amplitudes and delivered doses (R2 = 0.9997), with a consistent fit across different dose rates. The technique successfully provided 3D renderings of Bragg peaks at FLASH rates, validated through absolute Gamma index values.ConclusionsThe protoacoustic system demonstrates effectiveness in 3D visualization and tracking of the Bragg peak during FLASH proton therapy, representing a notable advancement in proton therapy quality assurance. This method promises enhancements in protoacoustic image guidance and real‐time dosimetry, paving the way for more accurate and effective treatments in ultra‐high dose rate therapy environments.

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Imaging for ion beam therapy: current trends and future perspectives

Parodi

2024

Health Technol.

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Purpose Since the pioneering use of planar X-ray imaging in early experimental sites of proton and light ion cancer therapy, imaging has always been a cornerstone of ion beam therapy (IBT). This contribution highlights current trends and future perspectives of imaging in modern IBT. Methods Several flavours of image guidance are under investigation to enhance IBT. A first class of in-room imaging techniques aims at providing insights on updated patient anatomy prior to or ideally during treatment. Owing to the unique characteristics of IBT, these methods do not only target a correct localization of the tumour and critical structures as in photon therapy, but also aim at extracting the tissue stopping properties for accurate (re)planning. A second class of techniques, predominantly performed during beam delivery, aims at capturing different secondary emissions induced by the irradiation to identify the beam stopping position and ideally reconstruct the dose delivery for inter- or intra-fractional treatment adaptation. Finally, a third class of imaging techniques is being explored to provide novel insights on the underlying biological mechanisms to open new opportunities for more effective and better tolerated treatments. Results and conclusions 70 years after the worldwide first proton treatment, image guidance of IBT continues to be an evolving area which combines advanced instrumentation with progress in computational areas, including artificial intelligence, and beam delivery schemes. Especially on-site imaging opens new opportunities to innovate the IBT chain with daily treatment adaptation, real-time verification of in-vivo range and dose delivery along with biological guidance for treatment personalization.

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Simulation study of protoacoustics as a real‐time in‐line dosimetry tool for FLASH proton therapy

Cited by 5 publications

References 72 publications

4D in vivo dosimetry for a FLASH electron beam using radiation-induced acoustic imaging

4D in vivo dosimetry for a FLASH electron beam using radiation-induced acoustic imaging

Toward real‐time, volumetric dosimetry for FLASH‐capable clinical synchrocyclotrons using protoacoustic imaging

Imaging for ion beam therapy: current trends and future perspectives

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