Jean M. Moran scite author profile

Purpose: Patient-specific IMRT QA measurements are important components of processes designed to identify discrepancies between calculated and delivered radiation doses. Discrepancy tolerance limits are neither well defined nor consistently applied across centers. The AAPM TG-218 report provides a comprehensive review aimed at improving the understanding and consistency of these processes as well as recommendations for methodologies and tolerance limits in patient-specific IMRT QA. Methods: The performance of the dose difference/distance-to-agreement (DTA) and c dose distribution comparison metrics are investigated. Measurement methods are reviewed and followed by a discussion of the pros and cons of each. Methodologies for absolute dose verification are discussed and new IMRT QA verification tools are presented. Literature on the expected or achievable agreement between measurements and calculations for different types of planning and delivery systems are reviewed and analyzed. Tests of vendor implementations of the c verification algorithm employing benchmark cases are presented. Results: Operational shortcomings that can reduce the c tool accuracy and subsequent effectiveness for IMRT QA are described. Practical considerations including spatial resolution, normalization, dose threshold, and data interpretation are discussed. Published data on IMRT QA and the clinical experience of the group members are used to develop guidelines and recommendations on tolerance and action limits for IMRT QA. Steps to check failed IMRT QA plans are outlined. Conclusion: Recommendations on delivery methods, data interpretation, dose normalization, the use of c analysis routines and choice of tolerance limits for IMRT QA are made with focus on detecting differences between calculated and measured doses via the use of robust analysis methods and an in-depth understanding of IMRT verification metrics. The recommendations are intended to improve the IMRT QA process and establish consistent, and comparable IMRT QA criteria among institutions.

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Development and Validation of a Heart Atlas to Study Cardiac Exposure to Radiation Following Treatment for Breast Cancer

Feng

Moran

Koelling

et al. 2011

International Journal of Radiation Oncology*Biology*Physics

619

448

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Purpose Cardiac toxicity is an important sequela of breast radiotherapy. However, the relationship between dose to cardiac structures and subsequent toxicity has not been well defined, partially due to variation in substructure delineation, which can lead to inconsistent dose reporting and the failure to detect potential correlations. Here we have developed a heart atlas and evaluated its effect on contour accuracy and concordance. Methods and Materials A detailed cardiac CT atlas was developed jointly by cardiology, cardiac radiology, and radiation oncology. Seven radiation oncologists were recruited to delineate the whole heart (WH), left main (LM), left anterior descending interventricular branch (LAD), and right coronary arteries (RCA) on four cases before and after studying the atlas. Contour accuracy was assessed by percent overlap with gold standard (GS) atlas volumes. The concordance index (CI) was also calculated. Standard radiation fields were applied. Doses to observer-contoured cardiac (OC) structures were calculated, and compared with GS contour doses. Pre- and post- atlas values were analyzed using a paired t-test. Results The cardiac atlas significantly improved contour accuracy and concordance. Percent overlap and CI of OC and GS volumes improved for all structures, by up to 2.3-fold (p<0.002). After application of the atlas, reported WH, LM, LAD, and RCA mean doses were within 0.1, 0.9, 2.6, and 0.6 Gy of GS doses. Conclusions This validated University of Michigan cardiac atlas may serve as a useful tool in future studies assessing cardiac toxicity and in clinical trials which include dose volume constraints to the heart.

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Radiation therapy for the whole breast: Executive summary of an American Society for Radiation Oncology (ASTRO) evidence-based guideline

Smith

Bellon

Blitzblau

et al. 2018

Practical Radiation Oncology

493

323

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Dosimetry tools and techniques for IMRT

et al. 2011

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Intensity modulated radiation therapy ͑IMRT͒ poses a number of challenges for properly measuring commissioning data and quality assurance ͑QA͒ radiation dose distributions. This report provides a comprehensive overview of how dosimeters, phantoms, and dose distribution analysis techniques should be used to support the commissioning and quality assurance requirements of an IMRT program. The proper applications of each dosimeter are described along with the limitations of each system. Point detectors, arrays, film, and electronic portal imagers are discussed with respect to their proper use, along with potential applications of 3D dosimetry. Regardless of the IMRT technique utilized, some situations require the use of multiple detectors for the acquisition of accurate commissioning data. The overall goal of this task group report is to provide a document that aids the physicist in the proper selection and use of the dosimetry tools available for IMRT QA and to provide a resource for physicists that describes dosimetry measurement techniques for purposes of IMRT commissioning and measurement-based characterization or verification of IMRT treatment plans. This report is not intended to provide a comprehensive review of commissioning and QA procedures for IMRT. Instead, this report focuses on the aspects of metrology, particularly the practical aspects of measurements that are unique to IMRT. The metrology of IMRT concerns the application of measurement instruments and their suitability, calibration, and quality control of measurements. Each of the dosimetry measurement tools has limitations that need to be considered when incorporating them into a commissioning process or a comprehensive QA program. For example, routine quality assurance procedures require the use of robust field dosimetry systems. These often exhibit limitations with respect to spatial resolution or energy response and need to themselves be commissioned against more established dosimeters. A chain of dosimeters, from secondary standards to field instruments, is established to assure the quantitative nature of the tests. This report is intended to describe the characteristics of the components of these systems; dosimeters, phantoms, and dose evaluation algorithms. This work is the report of AAPM Task Group 120.

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Variability of Target and Normal Structure Delineation for Breast Cancer Radiotherapy: An RTOG Multi-Institutional and Multiobserver Study

Tai

Arthur

et al. 2009

International Journal of Radiation Oncology*Biology*Physics

338

204

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Purpose To quantify the multi-institutional and multi-observer variability of target and organ-at-risk (OAR) delineation for breast-cancer radiotherapy (RT), and its dosimetric impacts, as the first step of a RTOG effort to establish a breast cancer atlas. Methods and Materials Nine radiation oncologists specializing in breast RT from eight institutions independently delineated targets (e.g., lumpectomy cavity, boost planning target volume, breast, supraclavicular, axillary and internal mammary nodes, and chest wall) and OARs (e.g., heart, lung) on the same CT images of three representative patients with breast cancer. Inter-observer differences in structure delineation were quantified with regard to volume, distance between centers of mass, percent overlap, and average surface distance. The mean, median and standard deviation for these quantities were calculated for all possible combinations. To asses the impact of these variations on treatment planning, representative dosimetric plans based on observer-specific contours were generated. Results The variability in contouring the targets and OARs between the institutions/observers was substantial. The structure overlaps were as low as 10% and the volume variations had standard deviations up to 60%. The large variability was related both to differences in opinion regarding target and OAR boundaries as well as approach to incorporation of setup uncertainty and dosimetric limitations in target delineation. These inter-observer differences result in substantial variations in dosimetric planning for breast RT. Conclusions The differences in target and OAR delineation for breast irradiation between institutions/observers appear to be clinically and dosimetrically significant. A systematic consensus is highly desirable, particularly in the era of IMRT/IGRT.

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Jean M. Moran

Tolerance limits and methodologies forIMRTmeasurement‐based verificationQA:Recommendations ofAAPMTask Group No. 218

Development and Validation of a Heart Atlas to Study Cardiac Exposure to Radiation Following Treatment for Breast Cancer

Radiation therapy for the whole breast: Executive summary of an American Society for Radiation Oncology (ASTRO) evidence-based guideline

Dosimetry tools and techniques for IMRT

Variability of Target and Normal Structure Delineation for Breast Cancer Radiotherapy: An RTOG Multi-Institutional and Multiobserver Study

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