Feasibility study of 3D time‐reversal reconstruction of proton‐induced acoustic signals for dose verification in the head and the liver: A simulation study

Yu, Yalan; Qi, Pengyuan; Peng, Hao

doi:10.1002/mp.15046

Cited by 8 publications

(12 citation statements)

References 33 publications

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“…Therefore, the BP position and relative dose can be inferred from the reconstruction of the initial pressure, whereas the absolute dose reconstruction requires an accurate knowledge of the medium properties (density and Grünensein parameter). Recent simulation studies have investigated the accuracy of ionoacoustics-based dose reconstruction for clinical scenarios using a linear array (van Dongen et al 2019) or sparse two and three dimensional sensor arrays positioned around the patient (Yu et al 2019(Yu et al , 2021. Assuming exact knowledge of the medium, they showed that the BP can be located with millimeter or sub-millimeter accuracy, depending on the proton pulse time profile.…”

Section: Introductionmentioning

confidence: 99%

Investigating the accuracy of co-registered ionoacoustic and ultrasound images in pulsed proton beams

et al. 2021

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The sharp spatial and temporal dose gradients of pulsed ion beams result in an acoustic emission (ionoacoustics), which can be used to reconstruct the dose distribution from measurements at different positions. The accuracy of range verification from ionoacoustic images measured with an ultrasound linear array configuration is investigated both theoretically and experimentally for monoenergetic proton beams at energies relevant for pre-clinical studies (20 and 22 MeV). The influence of the linear sensor array arrangement (length up to 4 cm and number of elements from 5 to 200) and medium properties on the range estimation accuracy are assessed using time-reversal reconstruction. We show that for an ideal homogeneous case, the ionoacoustic images enable a range verification with a relative error lower than 0.1%, however, with limited lateral dose accuracy. Similar results were obtained experimentally by irradiating a water phantom and taking into account the spatial impulse response (geometry) of the acoustic detector during the reconstruction of pressures obtained by moving laterally a single-element transducer to mimic a linear array configuration. Finally, co-registered ionoacoustic and ultrasound images were investigated using silicone inserts immersed in the water phantom across the proton beam axis. By accounting for the sensor response and speed of sound variations (deduced from co-registration with ultrasound images) the accuracy is improved to a few tens of micrometers (relative error less than to 0.5%), confirming the promise of ongoing developments for ionoacoustic range verification in pre-clinical and clinical proton therapy applications.

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Section: Introductionmentioning

confidence: 99%

Investigating the accuracy of co-registered ionoacoustic and ultrasound images in pulsed proton beams

et al. 2021

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“…Moreover, the accuracy will be increased if we create a dictionary of IA waves before the treatment to match the measured signals 22,31 . The use of multiple (or array‐type) sensors will further increase the accuracy as the three‐dimensional dose distributions can be obtained using iterative time‐reversal reconstruction methods 20,32,33,34 . Particularly, a novel array OH sensor reported by van der Heiden et al 52 .…”

Section: Discussionmentioning

confidence: 99%

“…22,31 The use of multiple (or array-type) sensors will further increase the accuracy as the three-dimensional dose distributions can be obtained using iterative time-reversal reconstruction methods. 20,32,33,34 Particularly, a novel array OH sensor reported by van der Heiden et al 52 is expected to realize the very accurate localization of BP with a minimal footprint. This line of research will significantly enhance the possibility of realizing IA range verification in clinics.…”

Section: Discussionmentioning

confidence: 99%

“…Because hydrophones must be placed on a patient's surface, the detector should be as small as possible to avoid narrowing the range of available beam angles and disturbing the real‐time images during beam delivery such as in X‐ray fluoroscopy. In fact, several researchers proposed the use of multiple detectors (from four to more than 200) to increase the estimated range reliability and/or to reconstruct dose distributions 31–35 . When these techniques are used, the range of available beam angles that do not overlap with the detectors may be reduced as the detector size becomes larger.…”

Section: Introductionmentioning

confidence: 99%

“…In fact, several researchers proposed the use of multiple detectors (from four to more than 200) to increase the estimated range reliability and/or to reconstruct dose distributions. [31][32][33][34][35] When these techniques are used, the range of available beam angles that do not overlap with the detectors may be reduced as the detector size becomes larger. In addition, PH could make larger shadows in the fluoroscopy images compared to the OH (see Figure S1 in the Supplemental Material), indicating that when these devices are used for range verification during the treatment of respiratory-moving tumors, it can be an obstacle to tracking tumors or fiducial markers when the projected images of hydrophones overlap with the images of tumors or markers.…”

Section: Introductionmentioning

confidence: 99%

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Ionoacoustic application of an optical hydrophone to detect proton beam range in water

et al. 2023

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Background Proton range uncertainty has been the main factor limiting the ability of proton therapy to concentrate doses to tumors to their full potential. Ionoacoustic (IA) range verification is an approach to reducing this uncertainty by detecting thermoacoustic waves emitted from an irradiated volume immediately following a pulsed proton beam delivery; however, the signal weakness has been an obstacle to its clinical application. To increase the signal‐to‐noise ratio (SNR) with the conventional piezoelectric hydrophone (PH), the detector‐sensitive volume needs to be large, but it could narrow the range of available beam angles and disturb real‐time images obtained during beam delivery. Purpose To prevent this issue, we investigated a millimeter‐sized optical hydrophone (OH) that exploits the laser interferometric principle. For two types of IA waves [γ‐wave emitted from the Bragg peak (BP) and a spherical IA wave with resonant frequency (SPIRE) emitted from the gold fiducial marker (GM)], comparisons were made with PH in terms of waveforms, SNR, range detection accuracy, and signal intensity robustness against the small detector misalignment, particularly for SPIRE. Methods A 100‐MeV proton beam with a 27 ns pulse width and 4 mm beam size was produced using a fixed‐field alternating gradient accelerator and was irradiated to the water phantom. The GM was set on the beam's central axis. Acrylic plates of various thicknesses, up to 12 mm, were set in front of the phantoms to shift the proton range. OH was set distal and lateral to the beam, and the range was estimated using the time‐of‐flight method for γ‐wave and by comparing with the calibration data (SPIRE intensity versus the distance between the GM and BP) derived from an IA wave transport simulation for SPIRE. The BP dose per pulse was 0.5–0.6 Gy. To measure the variation in SPIRE amplitude against the hydrophone misalignment, the hydrophone was shifted by ± 2 mm at a maximum in lateral directions. Results Despite its small size, OH could detect γ‐wave with a higher SNR than the conventional PH (diameter, 29 mm), and a single measurement was sufficient to detect the beam range with a submillimeter accuracy in water. In the SPIRE measurement, OH was far more robust against the detector misalignment than the focused PH (FPH) used in our previous study [5%/mm (OH) versus 80%/mm (FPH)], and the correlation between the measured SPIRE intensity and the distance between the GM and BP agreed well with the simulation results. However, the OH sensitivity was lower than the FPH sensitivity, and about 5.6‐Gy dose was required to decrease the intensity variation among measurements to less than 10%. Conclusion The miniature OH was found to detect weak IA signals produced by proton beams with a BP dose used in hypofractionated regimens. The OH sensitivity improvement at the MHz regime is worth exploring as the next step.

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Technical note: Application of an optical hydrophone to ionoacoustic range detection in a tissue‐mimicking agar phantom

Sueyasu,

Kasamatsu,

Takayanagi

et al. 2023

Medical Physics

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BackgroundIonoacoustics is a promising approach to reduce the range uncertainty in proton therapy. A miniature‐sized optical hydrophone (OH) was used as a measuring device to detect weak ionoacoustic signals with a high signal‐to‐noise ratio in water. However, further development is necessary to prevent wave distortion because of nearby acoustic impedance discontinuities while detection is conducted on the patient's skin.PurposeA prototype of the probe head attached to an OH was fabricated and the required dimensions were experimentally investigated using a 100‐MeV proton beam from a fixed‐field alternating gradient accelerator and k‐Wave simulations. The beam range of the proton in a tissue‐mimicking phantom was estimated by measuring γ‐waves and spherical ionoacoustic waves with resonant frequency (SPIRE).MethodsFour sizes of probe heads were fabricated from agar blocks for the OH. Using the prototype, the γ‐wave was detected at distal and lateral positions to the Bragg peak on the phantom surface for proton beams delivered at seven positions. For SPIRE, independent measurements were performed at distal on‐ and off‐axis positions. The range positions were estimated by solving the linear equation using the sensitive matrix for the γ‐wave and linear fitting of the correlation curve for SPIRE; they were compared with those measured using a film.ResultsThe first peak of the γ‐wave was undistorted with the 3 × 3 × 3‐cm3 probe head used at the on‐axis and 3‐cm off‐axis positions. The range positions estimated by the γ‐wave agreed with the film‐based range in the depth direction (the maximum deviation was 0.7 mm), although a 0.6–2.1 mm deviation was observed in the lateral direction. For SPIRE, the deviation was <1 mm for the two measurement positions.ConclusionsThe attachment of a relatively small‐sized probe head allowed the OH to measure the beam range on the phantom surface.

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Feasibility study of 3D time‐reversal reconstruction of proton‐induced acoustic signals for dose verification in the head and the liver: A simulation study

Cited by 8 publications

References 33 publications

Investigating the accuracy of co-registered ionoacoustic and ultrasound images in pulsed proton beams

Investigating the accuracy of co-registered ionoacoustic and ultrasound images in pulsed proton beams

Ionoacoustic application of an optical hydrophone to detect proton beam range in water

Technical note: Application of an optical hydrophone to ionoacoustic range detection in a tissue‐mimicking agar phantom

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