Experimental observation of acoustic emissions generated by a pulsed proton beam from a hospital‐based clinical cyclotron

Jones, Kevin C.; Stappen, F. Vander; Bawiec, Christopher R.; Janssens, Guillaume; Lewin, Peter A.; Prieels, D.; Solberg, Timothy D.; Sehgal, Chandra M.; Avery, Stephen

doi:10.1118/1.4935865

Cited by 62 publications

(82 citation statements)

References 32 publications

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“…In addition to the aforementioned approaches, in vivo range/dose verification utilizing proton‐induced acoustic (protoacoustic) signals is a very promising alternative solution. Since the concept was initially proposed by Askaryan, many groups have worked on a number of aspects including both numerical simulations and experimental measurements . Sulak et al experimentally detected acoustic signals produced by proton beams in fluid media and successfully demonstrated a thermal expansion model for this phenomenon .…”

Section: Introductionmentioning

confidence: 99%

Simulation studies of time reversal‐based protoacoustic reconstruction for range and dose verification in proton therapy

Yu¹,

Li²,

Zhang³

et al. 2019

Medical Physics

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Purpose In vivo range verification in proton therapy is a critical step to help minimize range and dose uncertainty. We propose to employ a time reversal (TR)‐based approach using proton‐induced acoustics (protoacoustics) to reconstruct pressure/dose distribution in heterogeneous tissues. Methods The dose distribution of mono‐energetic proton pencil beam in a CT‐based patient phantom was calculated by Monte Carlo simulation. K‐wave toolbox was used to investigate protoacoustic pressurization, propagation and reconstruction in 2D. To address the tissue heterogeneity effect, a number of physical parameters, including mass density (ρ), speed of sound (c), volumetric thermal expansion coefficient (αV), isobaric specific heat capacity (Cp) and attenuation power law prefactor (α0), were empirically converted from CT number. The performance was evaluated using two figures of merit: mean square error (MSE) of pressure profiles and Bragg peak localization error (ΔBP). The impact of six parameters of the TR inversion was examined, including number of sensors, sampling duration, sampling timestep, spill time, noise level and number of iterations. Results The quantitative accuracy of TR reconstruction and its dependency on the selected parameters is presented. Under optimum conditions, the positioning accuracy of the Bragg peak can be controlled below 1 mm. For instance, MSE is 0.0123 and ΔBP is 0.59 mm under the following conditions (32 sensors, sampling duration: 600 µs, sampling timestep: 40 ns, spill time: 1 µs, no noise). Conclusions The feasibility of TR‐based protoacoustic reconstruction in 2D for proton range verification was first demonstrated. The approach is not only applicable to pencil beam, but also has potential to be extended to passive scattering systems.

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Section: Introductionmentioning

confidence: 99%

Simulation studies of time reversal‐based protoacoustic reconstruction for range and dose verification in proton therapy

Yu¹,

Li²,

Zhang³

et al. 2019

Medical Physics

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“…The newest clinical sources, synchrocyclotrons, clinically deliver approximately 3.5 μs FWHM Gaussian proton pulses, which are predicted to be ideal for acoustic wave generation . To experimentally characterize proton‐induced thermoacoustics, researchers have first used accessible non‐clinical proton sources, and modified others . To generate detectable acoustic signals using a clinical IBA 230 cyclotron, Jones et al .…”

Section: Proton Therapy Range Verificationmentioning

confidence: 99%

“…62 To experimentally characterize proton-induced thermoacoustics, researchers have first used accessible nonclinical proton sources, 64,65 and modified others. 66 To generate detectable acoustic signals using a clinical IBA 230 cyclotron, Jones et al modified the proton pulse output by modulating the proton current entering the cyclotron with a function generator. 66 With this method, they were able to generate approximately Gaussian proton pulses of roughly 17 ls FWHM, and the arrival times of the hydrophonedetected pressure waves were proportional to detector distance from the beam.…”

Section: B Recent Workmentioning

confidence: 99%

Ionizing radiation‐induced acoustics for radiotherapy and diagnostic radiology applications

et al. 2018

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Acoustic waves are induced via the thermoacoustic effect in objects exposed to a pulsed beam of ionizing radiation. This phenomenon has interesting potential applications in both radiotherapy dosimetry and treatment guidance as well as low-dose radiological imaging. After initial work in the field in the 1980s and early 1990s, little research was done until 2013 when interest was rejuvenated, spurred on by technological advances in ultrasound transducers and the increasing complexity of radiotherapy delivery systems. Since then, many studies have been conducted and published applying ionizing radiation-induced acoustic principles into three primary research areas: Linear accelerator photon beam dosimetry, proton therapy range verification, and radiological imaging. This review article introduces the theoretical background behind ionizing radiation-induced acoustic waves, summarizes recent advances in the field, and provides an outlook on how the detection of ionizing radiationinduced acoustic waves can be used for relative and in vivo dosimetry in photon therapy, localization of the Bragg peak in proton therapy, and as a low-dose medical imaging modality. Future prospects and challenges for the clinical implementation of these techniques are discussed.

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“…In pencil beam scanning mode, macro pulses with a minimal duration of 1 ms are delivered. The pulse duration in double scattering mode is more than 20 ms. 1 The beam of the recently clinically introduced synchrocyclotron S2C2 of IBA has a different time structure with 7 µs pulse duration. 2 In preclinical studies, other time structures of the proton beam are also used, e.g., a modulated cyclotron C230 beam with pulse durations of about 20 µs.…”

Section: Introductionmentioning

confidence: 99%

“…2 In preclinical studies, other time structures of the proton beam are also used, e.g., a modulated cyclotron C230 beam with pulse durations of about 20 µs. 1 Furthermore, new accelerator technologies like laser plasma accelerators are under development to be introduced in therapy facilities. These laser accelerators deliver very short particle pulses with a pulse duration of few ps and low pulse repetition frequency of few Hz, i.e., pulse spacing of few hundred ms. 3 To limit the irradiation time to an acceptable maximum value, a high pulse dose in the order of 100 mGy is required.…”

Section: Introductionmentioning

confidence: 99%

Derivation of formulas to calculate the saturation correction of ionization chambers in pulsed beams of short, nonvanishing pulse durations

Karsch

2016

Medical Physics

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Experimental observation of acoustic emissions generated by a pulsed proton beam from a hospital‐based clinical cyclotron

Cited by 62 publications

References 32 publications

Simulation studies of time reversal‐based protoacoustic reconstruction for range and dose verification in proton therapy

Simulation studies of time reversal‐based protoacoustic reconstruction for range and dose verification in proton therapy

Ionizing radiation‐induced acoustics for radiotherapy and diagnostic radiology applications

Derivation of formulas to calculate the saturation correction of ionization chambers in pulsed beams of short, nonvanishing pulse durations

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