Single Pulse Protoacoustic Range Verification Using a Clinical Synchrocyclotron

Overview

Journal Phys Med Biol

Publisher IOP Publishing

Specialties Biophysics
Nuclear Medicine
Radiology

Date 2023 Jan 12

PMID 36634371

Authors

Joseph Caron

Gilberto Gonzalez

Prabodh Kumar Pandey

Siqi Wang

Kiana Prather

Salahuddin Ahmad

Liangzhong Xiang

Yong Chen

Affiliations

Soon will be listed here.

Abstract

Proton therapy as the next generation radiation-based cancer therapy offers dominant advantages over conventional radiation therapy due to the utilization of the Bragg peak; however, range uncertainty in beam delivery substantially mitigates the advantages of proton therapy. This work reports using protoacoustic measurements to determine the location of proton Bragg peak deposition within a water phantom in real time during beam delivery.In protoacoustics, proton beams have a definitive range, depositing a majority of the dose at the Bragg peak; this dose is then converted to heat. The resulting thermoelastic expansion generates a 3D acoustic wave, which can be detected by acoustic detectors to localize the Bragg peak.Protoacoustic measurements were performed with a synchrocyclotron proton machine over the exhaustive energy range from 45.5 to 227.15 MeV in clinic. It was found that the amplitude of the acoustic waves is proportional to proton dose deposition, and therefore encodes dosimetric information. With the guidance of protoacoustics, each individual proton beam (7 pC/pulse) can be directly visualized with sub-millimeter (<0.7 mm) resolution using single beam pulse for the first time.The ability to localize the Bragg peak in real-time and obtain acoustic signals proportional to dose within tumors could enable precision proton therapy and hope to progress towardsmeasurements.

Citing Articles

Real-time tracking of the Bragg peak during proton therapy via 3D protoacoustic Imaging in a clinical scenario.

Wang S, Gonzalez G, Sun L, Xu Y, Pandey P, Chen Y Npj Imaging. 2025; 2(1):34.

PMID: 40078731 PMC: 11893450. DOI: 10.1038/s44303-024-00039-x.

3D protoacoustic radiography: A proof of principle study.

Pandey P, Gonzalez G, Bjegovic K, Sun L, Chen Y, Xiang L Appl Phys Lett. 2025; 126(7):074102.

PMID: 39991118 PMC: 11842120. DOI: 10.1063/5.0239878.

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

Wang S, Gonzalez G, Owen D, Sun L, Liu Y, Zwart T Med Phys. 2024; 51(11):8496-8505.

PMID: 39073707 PMC: 11530303. DOI: 10.1002/mp.17318.

Ionic-resolution protoacoustic microscopy: A feasibility study.

Pandey P, Gonzalez G, Cheong F, Chen C, Bettiol A, Chen Y Appl Phys Lett. 2024; 124(5):053702.

PMID: 38313557 PMC: 10838192. DOI: 10.1063/5.0188650.

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