Estimation of organ and effective doses of CBCT scans of radiotherapy using size-specific field of view (FOV): a Monte Carlo study.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
ACS Applied Bio Materials Pub Date : 2024-09-01 Epub Date: 2024-03-27 DOI:10.1007/s13246-024-01413-0
Abdullah Abuhaimed, Huda Mujammami, Khaled AlEnazi, Ahmed Abanomy, Yazeed Alashban, Colin J Martin
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引用次数: 0

Abstract

The kV cone beam computed tomography (CBCT) is one of the most common imaging modalities used for image-guided radiation therapy (IGRT) procedures. Additional doses are delivered to patients, thus assessment and optimization of the imaging doses should be taken into consideration. This study aimed to investigate the influence of using fixed and patient-specific FOVs on the patient dose. Monte Carlo simulations were performed to simulate kV beams of the imaging system integrated into Truebeam linear accelerator using BEAMnrc code. Organ and size-specific effective doses resulting from chest and pelvis scanning protocols were estimated with DOSXYZnrc code using a phantom library developed by the National Cancer Institute (NCI) of the US. The library contains 193 (100 male and 93 female) mesh-type computational human adult phantoms, and it covers a large ratio of patient sizes with heights and weights ranging from 150 to 190 cm and 40 to 125 kg. The imaging doses were assessed using variable FOV of three sizes, small (S), medium (M), and large (L) for each scan region. The results show that the FOV and the patient size played a major role in the scan dose. The average percentage differences (PDs) for doses of organs that were fully inside the different FOVs were relatively low, all within 11% for both protocols. However, doses to organs that were scanned partially or near the FOVs were affected significantly. For the chest protocol, the inclusion of the thyroid in the scan field could give a dose of 1-7 mGy/100 mAs to the thyroid, compared to 0.4-1 mGy/100 mAs when it was excluded. Similarly, on average, testes doses could be 6 mGy/100 mAs for the male pelvis protocol compared to 3 mGy/100 mAs when it did not lie in the field irradiated. These dose differences resulted in an average increase of up to 27% in the size-specific effective dose of the protocols. Since changing the field size is possible for CBCT scans, the results suggest that patient-specific scanning protocols could be applied for each scan area in a manner similar to that used for CT scans. Adjustment of the FOV size should be subject to the clinical needs, and assist in improving the treatment accuracy. The patient's height and weight might be considered as the main factors upon which, the selection of the appropriate patient-specific protocol is based. This approach should optimize the imaging doses used for IGRT procedures by minimizing doses of a large ratio of patients.

Abstract Image

使用特定尺寸视场(FOV)估算放疗 CBCT 扫描的器官和有效剂量:蒙特卡罗研究。
千伏锥形束计算机断层扫描(CBCT)是图像引导放射治疗(IGRT)过程中最常用的成像模式之一。患者会承受额外的剂量,因此应考虑对成像剂量进行评估和优化。本研究旨在探讨使用固定 FOV 和患者特定 FOV 对患者剂量的影响。使用BEAMnrc代码对集成在Truebeam直线加速器中的成像系统的千伏光束进行了蒙特卡罗模拟。利用美国国家癌症研究所(NCI)开发的模型库,使用 DOSXYZnrc 代码估算了胸部和骨盆扫描方案产生的器官和体型特异性有效剂量。该模型库包含 193 个(100 个男性和 93 个女性)网状计算人体成人模型,涵盖了身高和体重在 150 厘米到 190 厘米和 40 公斤到 125 公斤之间的各种病人尺寸。对每个扫描区域使用小(S)、中(M)、大(L)三种尺寸的可变 FOV 进行了成像剂量评估。结果表明,FOV 和患者体型对扫描剂量有很大影响。完全位于不同 FOV 内的器官剂量的平均百分比差异(PDs)相对较低,两种方案均在 11% 以内。然而,部分或靠近 FOV 的器官的扫描剂量则受到很大影响。就胸部方案而言,将甲状腺纳入扫描区域可使甲状腺受到的剂量为 1-7 mGy/100 mAs,而将甲状腺排除在外则为 0.4-1 mGy/100 mAs。同样,在男性骨盆方案中,睾丸的平均剂量为 6 mGy/100 mAs,而当睾丸不在照射区域内时,则为 3 mGy/100 mAs。这些剂量差异导致方案的特定尺寸有效剂量平均增加 27%。由于 CBCT 扫描可以改变视野大小,因此结果表明,可以采用与 CT 扫描类似的方式,对每个扫描区域实施针对患者的扫描方案。根据临床需要调整视野大小,有助于提高治疗的准确性。病人的身高和体重可能是选择适合病人的方案的主要因素。这种方法可以最大限度地减少大比例患者的剂量,从而优化 IGRT 手术的成像剂量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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