Proton beam range verification by means of ionoacoustic measurements at clinically relevant doses using a correlation-based evaluation

Jannis Schauer; Hans-Peter Wieser; Yuanhui Huang; Heinrich Ruser; Julie Lascaud; Matthias Würl; Andriy Chmyrov; Marie Vidal; Joel Herault; Vasilis Ntziachristos; Walter Assmann; Katia Parodi; Günther Dollinger

doi:10.3389/fonc.2022.925542

Proton beam range verification by means of ionoacoustic measurements at clinically relevant doses using a correlation-based evaluation

Front Oncol. 2022 Nov 3:12:925542. doi: 10.3389/fonc.2022.925542. eCollection 2022.

Authors

Jannis Schauer¹, Hans-Peter Wieser², Yuanhui Huang^{3

4}, Heinrich Ruser¹, Julie Lascaud², Matthias Würl², Andriy Chmyrov^{3

4}, Marie Vidal⁵, Joel Herault⁵, Vasilis Ntziachristos^{3

4}, Walter Assmann², Katia Parodi², Günther Dollinger¹

Affiliations

¹ Institute for Applied Physics and Metrology, Bundeswehr University Munich, Neubiberg, Germany.
² Faculty of Physics, Chair of Medical and Experimental Physics, Ludwig-Maximilians-University, München, Germany.
³ Institute of Biological and Medical Imaging (IBMI), Helmholtz Zentrum München, Neuherberg, Germany.
⁴ Chair of Biological Imaging for Translational Cancer Research (TranslaTUM), School of Medicine, Technical University of Munich, Munich, Germany.
⁵ Centre Antoine Lacassagne (CAL), Department of Radiation Oncology, Nice, France.

Abstract

Purpose: The Bragg peak located at the end of the ion beam range is one of the main advantages of ion beam therapy compared to X-Ray radiotherapy. However, verifying the exact position of the Bragg peak within the patient online is a major challenge. The goal of this work was to achieve submillimeter proton beam range verification for pulsed proton beams of an energy of up to 220 MeV using ionoacoustics for a clinically relevant dose deposition of typically 2 Gy per fraction by i) using optimal proton beam characteristics for ionoacoustic signal generation and ii) improved signal detection by correlating the signal with simulated filter templates.

Methods: A water tank was irradiated with a preclinical 20 MeV proton beam using different pulse durations ranging from 50 ns up to 1 μs in order to maximise the signal-to-noise ratio (SNR) of ionoacoustic signals. The ionoacoustic signals were measured using a piezo-electric ultrasound transducer in the MHz frequency range. The signals were filtered using a cross correlation-based signal processing algorithm utilizing simulated templates, which enhances the SNR of the recorded signals. The range of the protons is evaluated by extracting the time of flight (ToF) of the ionoacoustic signals and compared to simulations from a Monte Carlo dose engine (FLUKA).

Results: Optimised SNR of 28.0 ± 10.6 is obtained at a beam current of 4.5 μA and a pulse duration of 130 ns at a total peak dose deposition of 0.5 Gy. Evaluated ranges coincide with Monte Carlo simulations better than 0.1 mm at an absolute range of 4.21 mm. Higher beam energies require longer proton pulse durations for optimised signal generation. Using the correlation-based post-processing filter a SNR of 17.8 ± 5.5 is obtained for 220 MeV protons at a total peak dose deposition of 1.3 Gy. For this clinically relevant dose deposition and proton beam energy, submillimeter range verification was achieved at an absolute range of 303 mm in water.

Conclusion: Optimal proton pulse durations ensure an ideal trade-off between maximising the ionoacoustic amplitude and minimising dose deposition. In combination with a correlation-based post-processing evaluation algorithm, a reasonable SNR can be achieved at low dose levels putting clinical applications for online proton or ion beam range verification into reach.

Keywords: cross-correlation; in-vivo range verification; ionoacoustics; matched filtering; protoacoustics; proton therapy; range verification in proton therapy; signal-to-noise ratio.