图像引导放疗治疗左侧乳腺癌患者:心脏的几何不确定性。
Image-guided radiotherapy for left-sided breast cancer patients: geometrical uncertainty of the heart.
机构信息
Radiotherapy Department, The Netherlands Cancer Institute/Antoni van Leeuwenhoek Huis, Amsterdam, The Netherlands.
出版信息
Int J Radiat Oncol Biol Phys. 2012 Mar 15;82(4):e647-55. doi: 10.1016/j.ijrobp.2011.08.024. Epub 2012 Jan 21.
PURPOSE
To quantify the geometrical uncertainties for the heart during radiotherapy treatment of left-sided breast cancer patients and to determine and validate planning organ at risk volume (PRV) margins.
METHODS AND MATERIALS
Twenty-two patients treated in supine position in 28 fractions with regularly acquired cone-beam computed tomography (CBCT) scans for offline setup correction were included. Retrospectively, the CBCT scans were reconstructed into 10-phase respiration correlated four-dimensional scans. The heart was registered in each breathing phase to the planning CT scan to establish the respiratory heart motion during the CBCT scan (σ(resp)). The average of the respiratory motion was calculated as the heart displacement error for a fraction. Subsequently, the systematic (Σ), random (σ), and total random (σ(tot)=σ(2)+σ(resp)(2)) errors of the heart position were calculated. Based on the errors a PRV margin for the heart was calculated to ensure that the maximum heart dose (D(max)) is not underestimated in at least 90% of the cases (M(heart) = 1.3Σ-0.5σ(tot)). All analysis were performed in left-right (LR), craniocaudal (CC), and anteroposterior (AP) directions with respect to both online and offline bony anatomy setup corrections. The PRV margin was validated by accumulating the dose to the heart based on the heart registrations and comparing the planned PRV D(max) to the accumulated heart D(max).
RESULTS
For online setup correction, the cardiac geometrical uncertainties and PRV margins were ∑ = 2.2/3.2/2.1 mm, σ = 2.1/2.9/1.4 mm, and M(heart) = 1.6/2.3/1.3 mm for LR/CC/AP, respectively. For offline setup correction these were ∑ = 2.4/3.7/2.2 mm, σ = 2.9/4.1/2.7 mm, and M(heart) = 1.6/2.1/1.4 mm. Cardiac motion induced by breathing was σ(resp) = 1.4/2.9/1.4 mm for LR/CC/AP. The PRV D(max) underestimated the accumulated heart D(max) for 9.1% patients using online and 13.6% patients using offline bony anatomy setup correction, which validated that PRV margin size was adequate.
CONCLUSION
Considerable cardiac position variability relative to the bony anatomy was observed in breast cancer patients. A PRV margin can be used during treatment planning to take these uncertainties into account.
目的
定量左侧乳腺癌患者放射治疗过程中心脏的几何不确定性,并确定和验证危及器官(PRV)的计划边界。
方法和材料
共纳入 22 例接受 28 分次常规采集锥形束 CT(CBCT)扫描的仰卧位患者,用于离线摆位校正。回顾性地,将 CBCT 扫描重建为 10 个相位呼吸相关的四维扫描。将心脏在每个呼吸相位与计划 CT 扫描配准,以建立 CBCT 扫描期间的呼吸心脏运动(σ(resp))。将各分次的平均呼吸运动计算为心脏位移误差。随后,计算心脏位置的系统(Σ)、随机(σ)和总随机(σ(tot)=σ(2)+σ(resp)(2))误差。基于这些误差,计算了心脏的 PRV 边界,以确保在至少 90%的情况下不会低估最大心脏剂量(D(max))(M(heart)=1.3Σ-0.5σ(tot))。所有分析均在左右(LR)、前后(AP)和头脚(CC)方向上,针对在线和离线骨性解剖学摆位校正进行。通过基于心脏配准来累积心脏剂量,并将计划的 PRV D(max)与累积的心脏 D(max)进行比较,验证了 PRV 边界的有效性。
结果
对于在线摆位校正,心脏的几何不确定性和 PRV 边界分别为∑=2.2/3.2/2.1mm、σ=2.1/2.9/1.4mm和 M(heart)=1.6/2.3/1.3mm,用于 LR/CC/AP。对于离线摆位校正,这些值分别为∑=2.4/3.7/2.2mm、σ=2.9/4.1/2.7mm和 M(heart)=1.6/2.1/1.4mm。呼吸引起的心脏运动为σ(resp)=1.4/2.9/1.4mm,用于 LR/CC/AP。使用在线骨性解剖学摆位校正,9.1%的患者的 PRV D(max)低估了累积的心脏 D(max),使用离线骨性解剖学摆位校正,13.6%的患者的 PRV D(max)低估了累积的心脏 D(max),这验证了 PRV 边界大小是足够的。
结论
在乳腺癌患者中,观察到心脏相对于骨性解剖结构的位置有相当大的变化。在治疗计划中可以使用 PRV 边界来考虑这些不确定性。
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