网格/格子疗法:考虑小场剂量测定。

IF 1.8 4区 医学 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Indra J Das, Ahtesham Ullah Khan, Serpil K Dogan, Mariaconcetta Longo
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引用次数: 0

摘要

伽玛刀、赛博刀、断层治疗、IMRT 和 VMAT 等特殊手术中使用的小场剂量测定方法,由于对剂量测定方法理解不深,在发生几起辐射事故后出现了非常大的误差(70%),因此小场剂量测定方法一直在不断发展。IAEA-TRS-483 和 AAPM-TG-155 在操作规范和相对剂量测定方面提供了有关小场剂量测定的全面信息。详细阐述了各种探测器和条件下的数据。结果表明,使用合适的探测器,6 MV 射束的剂量测量精度可以合理地达到(±3%),场 > 1x1 cm2。对于栅格疗法,尽管治疗是通过定制块、多叶准直器(MLC)或专用设备产生的小场来进行的,但却是多个小场形成了联合治疗。因此,了解小场集合孔的剂量测定是需要解决的另一个难题。更关键的是要了解形成治疗网格场的多个小孔的散射条件。散射会改变光束能量(更柔和),因此需要对剂量测定方案进行适当检查,以获得合适的剂量测定参数。在物理栅格设备中无法获得射束参数的情况下,基于 MLC 的正向和反向规划是治疗大体积肿瘤的另一条途径。在小场测量中,探测器的选择至关重要,而在散射条件下产生的混合光束中,这一点更为关键。本文探讨了网格疗法中使用的小场概念,以及散射条件的主要考虑因素。尽管这篇综述文章主要侧重于低能量兆伏特光子束(6 MV)的剂量测定,但高能量光子束也可采用类似的程序。为了消除小场问题,借助 MLC 进行晶格疗法是一种可取的选择。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Grid/lattice therapy: consideration of small field dosimetry.

Small-field dosimetry used in special procedures such as gamma knife, Cyberknife, Tomotherapy, IMRT, and VMAT has been in evolution after several radiation incidences with very significant (70%) errors due to poor understanding of the dosimetry. IAEA-TRS-483 and AAPM-TG-155 have provided comprehensive information on small-fields dosimetry in terms of code of practice and relative dosimetry. Data for various detectors and conditions have been elaborated. It turns out that with a suitable detectors dose measurement accuracy can be reasonably (±3%) achieved for 6 MV beams for fields >1×1 cm2. For grid therapy, even though the treatment is performed with small fields created by either customized blocks, multileaf collimator (MLC), or specialized devices, it is multiple small fields that creates combined treatment. Hence understanding the dosimetry in collection of holes of small field is a separate challenge that needs to be addressed. It is more critical to understand the scattering conditions from multiple holes that form the treatment grid fields. Scattering changes the beam energy (softer) and hence dosimetry protocol needs to be properly examined for having suitable dosimetric parameters. In lieu of beam parameter unavailability in physical grid devices, MLC-based forward and inverse planning is an alternative path for bulky tumours. Selection of detectors in small field measurement is critical and it is more critical in mixed beams created by scattering condition. Ramification of small field concept used in grid therapy along with major consideration of scattering condition is explored. Even though this review article is focussed mainly for dosimetry for low-energy megavoltage photon beam (6 MV) but similar procedures could be adopted for high energy beams. To eliminate small field issues, lattice therapy with the help of MLC is a preferrable choice.

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来源期刊
British Journal of Radiology
British Journal of Radiology 医学-核医学
CiteScore
5.30
自引率
3.80%
发文量
330
审稿时长
2-4 weeks
期刊介绍: BJR is the international research journal of the British Institute of Radiology and is the oldest scientific journal in the field of radiology and related sciences. Dating back to 1896, BJR’s history is radiology’s history, and the journal has featured some landmark papers such as the first description of Computed Tomography "Computerized transverse axial tomography" by Godfrey Hounsfield in 1973. A valuable historical resource, the complete BJR archive has been digitized from 1896. Quick Facts: - 2015 Impact Factor – 1.840 - Receipt to first decision – average of 6 weeks - Acceptance to online publication – average of 3 weeks - ISSN: 0007-1285 - eISSN: 1748-880X Open Access option
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