Optimal threshold of a control parameter for tomotherapy respiratory tracking: A phantom study

Sano, Keisuke; Okada, Wataru; Tanooka, Masao; Takaki, Haruyuki; Shibata, Mayuri; Nakamura, Kenji; Sakai, Yusuke; Suzuki, Hitomi; Takahashi, Kanae; Tanaka, Masahiro; Yamakado, Koichiro

doi:10.1002/acm2.13901

Cited by 2 publications

(2 citation statements)

References 19 publications

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“…The latest TomoTherapy unit, Radixact, has equipped with Synchrony system, which enables to track tumors affected by respiratory motion. The Synchrony system in Radixact utilizes a model‐based approach to predict the target position based on the correlation between the internal target position obtained from two‐dimensional kV x‐ray radiographs and the motion of light‐emitting diode markers placed on the patient's chest 5 . In addition, the treatment time can be shortened due to the high dose rate (1000 MU/min) of Radixact compared with the older units 6 .…”

Section: Introductionmentioning

confidence: 99%

“…The Synchrony system in Radixact utilizes a model‐based approach to predict the target position based on the correlation between the internal target position obtained from two‐dimensional kV x‐ray radiographs and the motion of light‐emitting diode markers placed on the patient's chest. 5 In addition, the treatment time can be shortened due to the high dose rate (1000 MU/min) of Radixact compared with the older units. 6 Since shorter treatment times can reduce both patient motion and the baseline shift of the target during irradiation, 7 providing more accurate treatment.…”

Section: Introductionmentioning

confidence: 99%

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Dosimetric evaluation in Helical TomoTherapy for lung SBRT using Monte Carlo‐based independent dose verification software

Kosaka,

Takatsu,

Inoue

et al. 2024

J Applied Clin Med Phys

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PurposeTo elucidate the dosimetric errors caused by a model‐based algorithm in lung stereotactic body radiation therapy (SBRT) with Helical TomoTherapy (HT) using Monte Carlo (MC)‐based dose verification software.MethodsFor 38 plans of lung SBRT, the dose calculation accuracy of a treatment planning system (TPS) of HT was compared with the results of DoseCHECK, the commercial MC‐based independent verification software. The following indices were extracted to evaluate the correlation of dosimetric errors: (1) target volume, (2) average computed tomography (CT) value of the planning target volume (PTV) margin, and (3) average CT value of surrounding 2‐mm area of the PTV (PTV ring). Receiver operating characteristic (ROC) analyses determined the threshold for 5% of differences in PTV D95%. Then, the 38 plans were classified into two groups using the cutoff values of ROC analysis for these three indices. Dosimetric differences between groups were statistically compared using the Mann–Whitney U test.ResultsTPS of HT overestimated by more than 5% in the PTV D95% in 16 of 38 plans. The PTV ring showed the strongest correlation with dosimetric differences. The cutoff value for the target volume, the PTV margin, and the PTV ring was 14.7 cc, −754 HU, and −708 HU, respectively. The area under the curve (AUC) for the target volume, the PTV margin, and the PTV ring were 0.835, 0.878, and 0.932, respectively. Dosimetric errors more than 5% were observed when the PTV volume was less than 15 cc or when the CT value around the target was less than −700 HU.ConclusionThe TPS of HT might overestimate the PTV dose by more than 5% if any the three indices in this study were below threshold. Therefore, independent verification with an MC‐based algorithm should be strongly recommended for lung SBRT in HT.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dosimetric evaluation in Helical TomoTherapy for lung SBRT using Monte Carlo‐based independent dose verification software

Kosaka,

Takatsu,

Inoue

et al. 2024

J Applied Clin Med Phys

View full text Add to dashboard Cite

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Optimal threshold of a control parameter for tomotherapy respiratory tracking: A phantom study

Sano

Okada

Tanooka

et al. 2023

J Applied Clin Med Phys

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Background: Radixact Synchrony ® , a real-time motion tracking and compensating modality, is used for helical tomotherapy. Control parameters are used for the accurate application of irradiation. Radixact Synchrony ® uses the potential difference, which is an index of the accuracy of the prediction model of target motion and is represented by a statistical prediction of the 3D distance error. Although there are several reports on Radixact Synchrony ® , few have reported the appropriate settings of the potential difference threshold. Purpose: This study aims to determine the optimal threshold of the potential difference of Radixact Synchrony ® during respiratory tumor-motion-tracking irradiation. Methods: The relationship among the dosimetric accuracy, motion tracking accuracy,and control parameter was evaluated using a moving platform,a phantom with a basic respiratory model (the fourth power of a sinusoidal wave), and several irregular respiratory model waveforms. The dosimetric accuracy was evaluated by gamma analysis (3%, 1 mm, 10% dose threshold). The tracking accuracy was measured by the distance error of the difference between the tracked and driven positions of the phantom. The largest potential difference for 95% of treatment time was evaluated, and its correlation with the gamma-pass ratio and distance error was investigated. The optimal threshold of the potential difference was determined by receiver operating characteristic (ROC) analysis. Results: A linear correlation was identified between the potential difference and the gamma-pass ratio (R = -0.704). A linear correlation was also identified between the potential difference and distance error (R = 0.827). However, as the potential difference increased, it tended to underestimate the distance error. The ROC analysis revealed that the appropriate cutoff value of the potential difference was 3.05 mm. Conclusion:The irradiation accuracy with motion tracking by Radixact Synchrony ® could be predicted from the potential difference, and the threshold of the potential difference should be set to ∼3 mm.

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Optimal threshold of a control parameter for tomotherapy respiratory tracking: A phantom study

Cited by 2 publications

References 19 publications

Dosimetric evaluation in Helical TomoTherapy for lung SBRT using Monte Carlo‐based independent dose verification software

Dosimetric evaluation in Helical TomoTherapy for lung SBRT using Monte Carlo‐based independent dose verification software

Optimal threshold of a control parameter for tomotherapy respiratory tracking: A phantom study

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