AI Article Synopsis
- Tumor motion during respiration significantly impacts the accuracy of particle beam therapy for thoracic and abdominal lesions, necessitating a comprehensive review of dosimetric considerations and motion-management techniques.
- The report outlines current approaches to managing this motion, including passive scattering, uniform scanning, and pencil-beam scanning, while identifying the limitations associated with each method.
- Recommendations emphasize the need for thorough planning studies, the establishment of standard operating procedures, and a risk-based approach to quality assurance and continuous improvement in motion management during particle-beam therapy.
Article Abstract
Dose uncertainty induced by respiratory motion remains a major concern for treating thoracic and abdominal lesions using particle beams. This Task Group report reviews the impact of tumor motion and dosimetric considerations in particle radiotherapy, current motion-management techniques, and limitations for different particle-beam delivery modes (i.e., passive scattering, uniform scanning, and pencil-beam scanning). Furthermore, the report provides guidance and risk analysis for quality assurance of the motion-management procedures to ensure consistency and accuracy, and discusses future development and emerging motion-management strategies. This report supplements previously published AAPM report TG76, and considers aspects of motion management that are crucial to the accurate and safe delivery of particle-beam therapy. To that end, this report produces general recommendations for commissioning and facility-specific dosimetric characterization, motion assessment, treatment planning, active and passive motion-management techniques, image guidance and related decision-making, monitoring throughout therapy, and recommendations for vendors. Key among these recommendations are that: (1) facilities should perform thorough planning studies (using retrospective data) and develop standard operating procedures that address all aspects of therapy for any treatment site involving respiratory motion; (2) a risk-based methodology should be adopted for quality management and ongoing process improvement.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9306777 | PMC |
| http://dx.doi.org/10.1002/mp.15470 | DOI Listing |
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