Comprehensive evaluation of dosimetric impact against position errors in accelerator‐based BNCT under different treatment parameter settings

Kakino, Ryo; Hu, Naonori; Isohashi, Kayako; Aihara, Teruhito; Nihei, Keiji; Ono, Koji

doi:10.1002/mp.15823

Cited by 9 publications

(1 citation statement)

References 23 publications

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“…The study of Lee [7] showed the mean dose of deep-seated tumor changes by 1% and 5% for lateral and outward shifts from the source plane, respectively, while the mean dose of superficial tumor without significant variation by 1 cm shift or 15˚ tilt. The research of Kakino [8] illustrated a significant reduction of tumor dose due to increased distance from the collimator, and the smaller the collimator, the more severe the tumor dose reduction. However, they considered a cylindrical phantom to investigate the effect of placement deviation on dose distribution.…”

Section: Introductionmentioning

confidence: 99%

Automated Robotic-Assisted Patient Positioning for Boron Neutron Capture Therapy: Integration with NeuMANTA Treatment Planning System and Dosimetric Impact Analysis

Chen,

Shu,

Gong

et al. 2024

Preprint

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Boron Neutron Capture Therapy (BNCT) represents a revolutionary approach in targeted radiation treatment for cancer. While the therapy's potential in precise targeting is well-recognized, a critical bottleneck remains in the accurate positioning of patients for treatment delivery. This study proposes a novel automated robotic-assisted patient positioning system specifically engineered for BNCT applications. The system utilizes high-precision industrial robotics and is fully integrated with NeuMANTA, a proprietary treatment planning system designed for BNCT. Through a systematic workflow, the robotic arm algorithmically calculates and executes the patient's positioning based on the treatment plan, thus enhancing the accuracy and efficacy of the treatment. We validate the positioning system using an anthropomorphic phantom and evaluate the dosimetric impact of positional deviations. The results indicate that the system achieves high accuracy, with a maximum observational deviation of 3 mm in Source-to-Skin Distance (SSD) and 2 mm along the surface. Dosimetric analysis reveals that the resulting dose changes are less than 1% in surface orientation deviations and greater than 5% in SSD orientation deviations. The study concludes that the robotic patient positioning system substantially advances in BNCT treatment delivery. This work not only sets a new benchmark for patient positioning in BNCT, but also provides a comprehensive framework for integrating advanced robotics into radiotherapy, paving the way for more precise and effective cancer treatments.

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Section: Introductionmentioning

confidence: 99%

Automated Robotic-Assisted Patient Positioning for Boron Neutron Capture Therapy: Integration with NeuMANTA Treatment Planning System and Dosimetric Impact Analysis

Chen,

Shu,

Gong

et al. 2024

Preprint

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Comprehensive evaluation of dosimetric impact against position errors in accelerator‐based BNCT under different treatment parameter settings

Kakino

Isohashi

et al. 2022

Medical Physics

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Background Patients who undergo accelerator‐based (AB) boron neutron capture therapy (BNCT) for head and neck cancer in the sitting position are generally uncomfortably immobilized, and patient motion during this treatment may be greater than that in other radiotherapy techniques. Furthermore, the treatment time of BNCT is relatively long (up to approximately 1 h), which increases the possibility of patient movement during treatment. As most BNCT irradiations are performed in a single fraction, the dosimetric error due to patient motion is of greater consequence and needs to be evaluated and accounted for. Several treatment parameters are required for BNCT dose calculation. Purpose To investigate the dosimetric impacts (DIs) against position errors using a simple cylindrical phantom for an AB‐BNCT system under different treatment parameter settings. Methods The treatment plans were created in RayStation and the dose calculation was performed using the NeuCure® dose engine. A cylindrical phantom (16 cm diameter × 20 cm height) made of soft tissue was modeled. Dummy tumors in the form of a 3‐cm‐diameter sphere were arranged at depths of 2.5 and 6.5 cm (denoted by T2.5 and T6.5, respectively). Reference plans were created by setting the following parameters: collimator size = 10, 12, or 15 cm in diameter, collimator‐to‐surface distance (CSD) = 4.0 or 8.0 cm, tumor‐to‐blood ratio (T/B ratio) using 18F‐fluoro‐borono‐phenylalanine = 2.5 or 5.0, and 10B concentration in blood = 20, 25, or 30 ppm. The prescribed dose was D95% ≥ 20 Gy‐eq for both T2.5 and T6.5. Based on the reference plans, phantom‐shifted plans were created in 26 directions [all combinations of left–right (LR), anterior–posterior (AP), and superior–inferior (SI) directions) and three distances (1.0, 2.0, and 3.0 cm). The DIs were evaluated at D80% of the tumors. The shift direction dependency of the DI in the LR, AP, and SI directions was evaluated by conducting a multiple regression analysis (MRA) and other analyses where required. Results The coefficients of the MRA of the DIs for LR, AP, and SI shifts were −0.08, 2.16, and −0.04 (p‐values = 0.084, <0.01, and 0.334) for T2.5 and −0.05, 2.08, and 0.15 (p‐values = 0.526, <0.01, and 0.065) for T6.5, respectively. The analysis of variance showed that DIs due to the AP shift were significantly greater for smaller collimator sizes on T2.5 and smaller CSD on T6.5. Dose reduction due to SI or LR (lateral) shifts was significantly greater for smaller collimator sizes on both T2.5 and T6.5 and smaller CSD on T2.5, according to the Student's t‐test. There were no significant differences in the DIs against both the AP shift and the lateral shift between the different T/B ratios and 10B concentrations. Conclusion The DIs were largely affected by the shift in the AP direction and were influenced by the different treatment parameters.

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Biophysical modeling of low‐energy ion irradiations with NanOx

Alcocer‐Ávila,

Levrague,

Delorme

et al. 2024

Medical Physics

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BackgroundTargeted radiotherapies with low‐energy ions show interesting possibilities for the selective irradiation of tumor cells, a strategy particularly appropriate for the treatment of disseminated cancer. Two promising examples are boron neutron capture therapy (BNCT) and targeted radionuclide therapy with ‐particle emitters (TAT). The successful clinical translation of these radiotherapies requires the implementation of accurate radiation dosimetry approaches able to take into account the impact on treatments of the biological effectiveness of ions and the heterogeneity in the therapeutic agent distribution inside the tumor cells. To this end, biophysical models can be applied to translate the interactions of radiations with matter into biological endpoints, such as cell survival.PurposeThe NanOx model was initially developed for predicting the cell survival fractions resulting from irradiations with the high‐energy ion beams encountered in hadrontherapy. We present in this work a new implementation of the model that extends its application to irradiations with low‐energy ions, as the ones found in TAT and BNCT.MethodsThe NanOx model was adapted to consider the energy loss of primary ions within the sensitive volume (i.e., the cell nucleus). Additional assumptions were introduced to simplify the practical implementation of the model and reduce computation time. In particular, for low‐energy ions the narrow‐track approximation allowed to neglect the energy deposited by secondary electrons outside the sensitive volume, increasing significantly the performance of simulations. Calculations were performed to compare the original hadrontherapy implementation of the NanOx model with the present one in terms of the inactivation cross sections of human salivary gland cells as a function of the kinetic energy of incident ‐particles.ResultsThe predictions of the previous and current versions of NanOx agreed for incident energies higher than 1 MeV/n. For lower energies, the new NanOx implementation predicted a decrease in the inactivation cross sections that depended on the length of the sensitive volume.ConclusionsWe reported in this work an extension of the NanOx biophysical model to consider irradiations with low‐energy ions, such as the ones found in TAT and BNCT. The excellent agreement observed at intermediate and high energies between the original hadrontherapy implementation and the present one showed that NanOx offers a consistent, self‐integrated framework for describing the biological effects induced by ion irradiations. Future work will focus on the application of the latest version of NanOx to cases closer to the clinical setting.

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Comprehensive evaluation of dosimetric impact against position errors in accelerator‐based BNCT under different treatment parameter settings

Cited by 9 publications

References 23 publications

Automated Robotic-Assisted Patient Positioning for Boron Neutron Capture Therapy: Integration with NeuMANTA Treatment Planning System and Dosimetric Impact Analysis

Automated Robotic-Assisted Patient Positioning for Boron Neutron Capture Therapy: Integration with NeuMANTA Treatment Planning System and Dosimetric Impact Analysis

Comprehensive evaluation of dosimetric impact against position errors in accelerator‐based BNCT under different treatment parameter settings

Biophysical modeling of low‐energy ion irradiations with NanOx

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