A comprehensive evaluation of the accuracy of CBCT and deformable registration based dose calculation in lung proton therapy

Veiga, Catarina; Janssens, Guillaume; Baudier, Thomas; Hotoiu, L.; Brousmiche, Sébastien; McClelland, Jamie R.; Teng, Ching-Ling; Yin, Lingshu; Royle, G.; Teo, Boon-Keng

doi:10.1088/2057-1976/3/1/015003

Cited by 24 publications

(40 citation statements)

References 41 publications

(66 reference statements)

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“…Similar results were also found for virtual CT derived from megavoltage CT scans . The evaluation of a water equivalent thickness (WET) uncertainty as a measure of the impact of DIR inaccuracies on dose calculation was also recently proposed for the use of virtual CT in passive scattering proton therapy of lung tumors . The WET is the thickness of water needed to cause a proton beam to lose the same amount of energy as in a given thickness of a different medium.…”

Section: The Dosimetric Accuracy Paradigmsupporting

confidence: 57%

“…The WET is the thickness of water needed to cause a proton beam to lose the same amount of energy as in a given thickness of a different medium. When comparing tumor margins of lung treatment plans as defined on the virtual and re‐planning CTs, the resulting root mean squared uncertainty in WET was 3.3 ± 1.8 mm . The WET metric is limited to particle therapy applications, but can provide a quantitative evaluation in these kind of treatments.…”

Section: The Dosimetric Accuracy Paradigmmentioning

confidence: 99%

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“Patient‐specific validation of deformable image registration in radiation therapy: Overview and caveats”

et al. 2018

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Over the last few decades, deformable image registration (DIR) has gained popularity in image-guided radiation therapy for a number of applications, such as contour propagation, dose warping, and accumulation. Although this raises promising perspectives for the improvement of treatment outcomes and quality of radiotherapy clinical practice, the variety of proposed DIR algorithms, combined with the lack of an effective quantitative quality control metric of the registration, is slowing the transfer of DIR into the clinical routine. Recently, a task group (AAPM TG132) report was published outlining the essential aspects of DIR for image guidance in radiotherapy. However, an accurate and efficient patient-specific validation is not yet defined, and appropriate metrics should be identified to achieve the definition of both geometric and dosimetric accuracy. In this respect, the use of a dense set of anatomical landmarks, along with additional evaluations on contours or deformation field analysis, are likely to drive patient-specific DIR validation in clinical image-guided radiotherapy applications to account for geometric inaccuracies. Automatic and efficient strategies able to provide spatial information of DIR uncertainties and to evaluate monomodal and multimodal image registration, as well as to describe homogenous and un-contrasted regions are believed to represent the future direction in DIR validation. But especially in the case of DIR applications for dose mapping and accumulation, the need of accurate patient-specific validation is not only limited to the evaluation of geometric accuracy. In fact, the need to account for dosimetric inaccuracies due to DIR represents another important area in the field of adaptive treatments. Different approaches are currently being investigated to quantify the effect of DIR error on dose analysis, mainly relying on clinically relevant dose metrics, or on the study of deformation field properties for a voxel-by-voxel evaluation. However, novel research is required for the definition of dedicated and personalized measures capable to relate the geometric and dosimetric inaccuracies, thus bearing useful information for a safe use of DIR by clinical end users. In this paper we provide insights on DIR results evaluation on a patient-specific basis, facing the issues of both geometric and dosimetric paradigms. Challenges on DIR validation are overviewed and discussed, in order to push preliminary clinical guidelines forward on this fundamental topic and boost the implementation of more robust and reliable patient-specific evaluation metrics.

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Section: The Dosimetric Accuracy Paradigmsupporting

confidence: 57%

Section: The Dosimetric Accuracy Paradigmmentioning

confidence: 99%

“Patient‐specific validation of deformable image registration in radiation therapy: Overview and caveats”

et al. 2018

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“…The advantage of range‐based registration over adaptive planning for IMPT is its fast calculation for the patient on couch. Adaptive planning can better improve the dose coverage but often takes longer time from gathering the information to generating a new plan, including the computation time on the deformable registration of the CBCT to planning CT . The new plan may need quality assurance.…”

Section: Discussionmentioning

confidence: 99%

Feasibility study of range‐based registration using daily cone beam CT for intensity‐modulated proton therapy

et al. 2018

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“…For example, the SAD/SID is 200/300 cm for Varian ProBeam systems and 288.4/347 cm for IBA Proteus systems. 12,13,19 Although the scatter effect theoretically becomes less severe as the cone angle decreases and the patient-to-imager distance increases, as in many gantry-mounted systems, the sensitivity to mechanical accuracy and stability also plays an important part in the resultant image quality. The larger SID of gantry-mounted CBCT systems may also place a greater burden on the X-ray tube if the same photon flux to the detector is expected as in the C-arm CBCT system with a smaller SID; even in the absence of an anti-scatter grid, the mAs exposure is typically much higher.…”

Section: Discussionmentioning

confidence: 99%

“…This CBCT system design is different from the mobile C-arm CBCT system used in interventional radiology and surgery, 9,10 the existing robotic C-arm imaging systems used in some particle therapy centres, 11 and the 360° gantry-mounted CBCT systems. 12,13 The use of standalone robot arms on ceiling rails provides flexibility in imaging locations (at or off the treatment isocentre) in the room. Having the imaging equipment decoupled from the proton gantry and nozzle makes it easier to upgrade the system as technology advances than would otherwise be the case.…”

mentioning

confidence: 99%

A robotic C-arm cone beam CT system for image-guided proton therapy: design and performance

Hua

Yao

Kidani

et al. 2017

The British Journal of Radiology

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A comprehensive evaluation of the accuracy of CBCT and deformable registration based dose calculation in lung proton therapy

Cited by 24 publications

References 41 publications

“Patient‐specific validation of deformable image registration in radiation therapy: Overview and caveats”

“Patient‐specific validation of deformable image registration in radiation therapy: Overview and caveats”

Feasibility study of range‐based registration using daily cone beam CT for intensity‐modulated proton therapy

A robotic C-arm cone beam CT system for image-guided proton therapy: design and performance

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