Department of Radiation Oncology and Image-applied Therapy, Graduate School of Medicine, Kyoto University, 54 Kawahara-cho, Shogoin, Sakyo-ku, Kyoto 606-8507, Japan.
Department of Advanced Medical Physics, Graduate School of Medicine, Kyoto University, 53 Kawahara-cho, Shogoin, Sakyo-ku, Kyoto 606-8507, Japan.
Phys Med. 2023 Jun;110:102605. doi: 10.1016/j.ejmp.2023.102605. Epub 2023 May 9.
Quantifying intra-fractional six-degree-of-freedom (6DoF) residual errors or motion from approved patient setups is necessary for accurate beam delivery in spine stereotactic body radiotherapy. However, previously reported errors were not acquired during beam delivery. Therefore, we aimed to quantify the 6DoF residual errors and motions during arc beam delivery using a concurrent cone-beam computed tomography (CBCT) imaging technique, intra-irradiation CBCT.
Consecutive 15 patients, 19 plans for various treatment sites, and 199 CBCT images were analyzed. Pre-irradiation CBCT was performed to verify shifts from the initial patient setup using the ExacTrac system. During beam delivery by two or three co-planar full-arc rotations, CBCT imaging was performed concurrently. Subsequently, an intra-irradiation CBCT image was reconstructed. Pre- and intra-irradiation CBCT images were rigidly registered to a planning CT image based on the bone to quantify 6DoF residual errors.
6DoF residual errors quantified using pre- and intra-irradiation CBCTs were within 2.0 mm/2.0°, except for one measurement. The mean elapsed time (mean ± standard deviation [min:sec]) after pre-irradiation CBCT to the end of the last arc beam delivery was 6:08 ± 1:25 and 7:54 ± 2:14 for the 2- and 3-arc plans, respectively. Root mean squares of residual errors for several directions showed significant differences; however, they were within 1.0 mm/1.0°. Time-dependent analysis revealed that the residual errors tended to increase with elapsed time.
The errors represent the optimal intra-fractional error compared with those acquired using the pre-, inter-beam, and post-6DoF image guidance and can be acquired within a standard treatment timeslot.
在脊柱立体定向体部放疗中,为了实现精确的光束传输,需要定量分析已批准的患者摆位的分次内六自由度(6DoF)残余误差或运动。然而,之前报道的误差并非在光束传输过程中获得。因此,我们旨在使用同步锥形束计算机断层扫描(CBCT)成像技术(术中 CBCT)来定量测量弧形光束传输过程中的 6DoF 残余误差和运动。
对连续 15 名患者、19 个不同治疗部位的计划和 199 个 CBCT 图像进行了分析。使用 ExacTrac 系统对预照射 CBCT 进行了验证,以验证初始患者摆位的移位。在两个或三个共面全弧旋转过程中进行了同时的 CBCT 成像。随后,重建了一个术中 CBCT 图像。根据骨骼,将预照射和术中 CBCT 图像刚性配准到计划 CT 图像上,以定量 6DoF 残余误差。
使用预照射和术中 CBCT 测量的 6DoF 残余误差在 2.0mm/2.0°以内,除了一个测量值。在预照射 CBCT 后到最后一个弧形光束传输结束的时间(平均值±标准差[min:sec]),2 弧和 3 弧计划分别为 6:08±1:25 和 7:54±2:14。几个方向的残余误差的均方根显示出显著差异,但都在 1.0mm/1.0°以内。时间依赖性分析表明,残余误差随着时间的推移而增加。
与使用预、间、后 6DoF 图像引导获得的误差相比,这些误差代表了最佳的分次内误差,并且可以在标准的治疗时间窗内获得。
