Ciocca Mario, Piazzi Valeria, Lazzari Roberta, Vavassori Andrea, Luini Alberto, Veronesi Paolo, Galimberti Viviana, Intra Mattia, Guido Andrea, Tosi Giampiero, Veronesi Umberto, Orecchia Roberto
Department of Medical Physics, European Institute of Oncology, Milano, Italy.
Radiother Oncol. 2006 Feb;78(2):213-6. doi: 10.1016/j.radonc.2005.11.011. Epub 2005 Dec 15.
In a previous paper we reported the results of off-line in vivo measurements using radiochromic films in IOERT. In the present study, a further step was made, aiming at the improvement of the effectiveness of in vivo dosimetry, based on a real-time check of the dose.
Entrance dose was determined using micro-MOSFET detectors placed inside a thin, sterile, transparent catheter. The epoxy side of the detector was faced towards the beam to minimize the anisotropy. Each detector was plugged into a bias supply (standard sensitivity) and calibrated at 5 Gy using 6 MeV electrons produced by a conventional linac. Detectors were characterized in terms of linearity, precision and dose per pulse dependence. No energy and temperature dependence was found. The sensitivity change of detectors was about 1% per 20 Gy accumulated dose. Correction factors to convert surface to entrance dose were determined for each combination of energy and applicator. From November 2004 to May 2005, in vivo dosimetry was performed on 45 patients affected by early-stage breast cancer, who underwent IOERT to the tumour bed. IOERT was delivered using electrons (4-10 MeV) at high dose per pulse, produced by either a Novac7 or a Liac mobile linac.
The mean ratio between measured and expected dose was 1.006+/-0.035 (1 SD), in the range 0.92-1.1. The procedure uncertainty was 3.6%. Micro-MOSFETs appeared suitable for in vivo dosimetry in IOERT, although some unfavourable aspects, like the limited lifetime and the anisotropy with no build-up, were found. Prospectively, a real-time action level (+/-6%) on dose discrepancy was defined.
Excellent agreement between measured and expected doses was found. Real-time in vivo dosimetry appeared feasible, reliable and more effective than the method previously published.
在之前的一篇论文中,我们报告了在术中电子放射治疗(IOERT)中使用放射变色薄膜进行离线体内测量的结果。在本研究中,基于对剂量的实时检查,朝着提高体内剂量测定的有效性又迈进了一步。
使用置于细的、无菌的透明导管内的微型金属氧化物半导体场效应晶体管(micro-MOSFET)探测器来确定入射剂量。探测器的环氧面朝向射束,以将各向异性降至最低。每个探测器插入偏置电源(标准灵敏度),并使用传统直线加速器产生的6 MeV电子在5 Gy下进行校准。对探测器的线性、精度和每脉冲剂量依赖性进行了表征。未发现能量和温度依赖性。探测器的灵敏度变化约为每累积20 Gy剂量变化1%。针对每种能量和施源器组合,确定了将表面剂量转换为入射剂量的校正因子。2004年11月至2005年5月,对45例早期乳腺癌患者进行了体内剂量测定,这些患者在肿瘤床接受了IOERT。IOERT使用由Novac7或Liac移动直线加速器产生的高脉冲剂量电子(4 - 10 MeV)进行。
测量剂量与预期剂量的平均比值为1.006±0.035(1标准差),范围为0.92 - 1.1。程序不确定度为3.6%。微型MOSFET似乎适用于IOERT中的体内剂量测定,尽管发现了一些不利方面,如寿命有限和无剂量建成时的各向异性。前瞻性地,定义了剂量差异的实时行动水平(±6%)。
测量剂量与预期剂量之间具有良好的一致性。实时体内剂量测定似乎可行、可靠且比先前发表的方法更有效。
