Estimation of breast dose saving potential using a breast positioning technique for organ-based tube current modulated CT

SPIE Medical Imaging Pub Date : 2016-05-03 DOI:10.1117/12.2217239

Wanyi Fu, X. Tian, G. Sturgeon, G. Agasthya, W. Segars, M. Goodsitt, E. Kazerooni, E. Samei

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引用次数: 2

Abstract

In thoracic CT, organ-based tube current modulation (OTCM) reduces breast dose by lowering the tube current in the 120° anterior dose reduction zone of patients. However, in practice the breasts usually expand to an angle larger than the dose reduction zone. This work aims to simulate a breast positioning technique (BPT) to constrain the breast tissue to within the dose reduction zone for OTCM and to evaluate the corresponding potential reduction in breast dose. Thirteen female anthropomorphic computational phantoms were studied (age range: 27-65 y.o., weight range: 52-105.8 kg). Each phantom was modeled in the supine position with and without application of the BPT. Attenuation-based tube current (ATCM, reference mA) was generated by a ray-tracing program, taking into account the patient attenuation change in the longitudinal and angular plane (CAREDose4D, Siemens Healthcare). OTCM was generated by reducing the mA to 20% between ± 60° anterior of the patient and increasing the mA in the remaining projections correspondingly (X-CARE, Siemens Healthcare) to maintain the mean tube current. Breast tissue dose was estimated using a validated Monte Carlo program for a commercial scanner (SOMATOM Definition Flash, Siemens Healthcare). Compared to standard tube current modulation, breast dose was significantly reduced using OTCM by 19.8±4.7%. With the BPT, breast dose was reduced by an additional 20.4±6.5% to 37.1±6.9%, using the same CTDIvol. BPT was more effective for phantoms simulating women with larger breasts with the average breast dose reduction of 30.2%, 39.2%, and 49.2% from OTCMBP to ATCM, using the same CTDIvol for phantoms with 0.5, 1.5, and 2.5 kg breasts, respectively. This study shows that a specially designed BPT improves the effectiveness of OTCM.

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基于器官管电流调制CT的乳房定位技术对乳腺剂量节约潜力的估计

在胸部CT中，基于器官的导管电流调制(OTCM)通过降低患者120°前剂量减少区的导管电流来降低乳房剂量。然而，在实践中，乳房通常扩大到比剂量减少区更大的角度。本工作旨在模拟乳房定位技术(BPT)，将乳房组织限制在OTCM的剂量减少区域内，并评估相应的乳房剂量减少潜力。研究了13个女性拟人化计算模型(年龄27 ~ 65岁，体重52 ~ 105.8 kg)。在使用和不使用BPT的情况下，每个幻体都在仰卧位建模。通过射线追踪程序生成基于衰减的管电流(ATCM，参考mA)，同时考虑到患者在纵向和角平面上的衰减变化(CAREDose4D, Siemens Healthcare)。通过将患者正前方±60°之间的mA降低至20%，并相应增加剩余投影处的mA来产生OTCM (X-CARE, Siemens Healthcare)，以维持平均管电流。使用商用扫描仪(SOMATOM Definition Flash, Siemens Healthcare)的经过验证的蒙特卡罗程序估计乳腺组织剂量。与标准管电流调制相比，使用OTCM可显著降低乳房剂量19.8±4.7%。使用BPT，使用相同的CTDIvol，乳房剂量额外减少20.4±6.5%至37.1±6.9%。BPT对于模拟乳房较大的女性的幻影更有效，从OTCMBP到ATCM的平均乳房剂量分别减少了30.2%，39.2%和49.2%，对乳房为0.5,1.5和2.5 kg的幻影使用相同的CTDIvol。本研究表明，特殊设计的BPT可以提高OTCM的有效性。

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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SPIE Medical Imaging

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