Tanderup Kari, Hellebust Taran Paulsen, Honoré Henriette Benedicte, Nielsen Søren Kynde, Olsen Dag Rune, Grau Cai, Lindegaard Jacob Christian
Department of Oncology, Aarhus University Hospital, Aarhus, Denmark.
Radiother Oncol. 2006 Oct;81(1):105-11. doi: 10.1016/j.radonc.2006.08.021. Epub 2006 Sep 26.
Brachytherapy dose distributions can be optimised by modulation of source dwell times. In this study dose optimisation in single planar interstitial implants was evaluated in order to quantify the potential benefit in patients.
In 14 patients, treated for recurrent rectal and cervical cancer, flexible catheters were sutured intra-operatively to the tumour bed in areas with compromised surgical margin. Both non-optimised, geometrically and graphically optimised CT -based dose plans were made. The overdose index (OI), homogeneity index (HI), conformal index (COIN), minimum target dose, and high dose volumes were evaluated. The dependence of OI, HI, and COIN on target volume and implant regularity was evaluated. In addition, 12 theoretical implant configurations were analyzed.
Geometrical and graphical optimisation improved the dose plans significantly with graphical optimisation being superior. Graphically optimised dose plans showed a significant decrease of 18%+/-9% in high dose volume (p<0.001). HI, COIN, and OI were significantly improved from 0.50+/-0.05 to 0.60+/-0.05, from 0.65+/-0.04 to 0.71+/-0.04, and from 0.19+/-0.03 to 0.15+/-0.03, respectively (p<0.001 for all). Moreover, minimum target dose increased significantly from 71%+/-5% to 80%+/-5% (p<0.001). The improvement in OI and HI obtained by optimisation depended on the regularity of the implant, such that the benefit of optimisation was larger for irregular implants. OI and HI correlated strongly with target volume limiting the usability of these parameters for comparison of dose plans between patients.
Dwell time optimisation significantly improved the dose distribution regarding homogeneity, conformity, minimum target dose, and size of high dose volumes. Graphical optimisation is fast, reproducible and superior to geometric optimisation.
近距离放射治疗的剂量分布可通过调节源驻留时间来优化。在本研究中,对单平面组织间植入的剂量优化进行了评估,以量化其对患者的潜在益处。
对14例复发性直肠癌和宫颈癌患者,术中将柔性导管缝合至手术切缘受损区域的肿瘤床。制定了基于CT的非优化、几何优化和图形优化的剂量计划。评估了过量指数(OI)、均匀性指数(HI)、适形指数(COIN)、最小靶剂量和高剂量体积。评估了OI、HI和COIN对靶体积和植入规则性的依赖性。此外,分析了12种理论植入配置。
几何优化和图形优化显著改善了剂量计划,图形优化更具优势。图形优化的剂量计划显示高剂量体积显著降低了18%±9%(p<0.001)。HI、COIN和OI分别从0.50±0.05显著改善至0.60±0.05、从0.65±0.04显著改善至0.71±0.04、从0.19±0.03显著改善至0.15±0.03(均p<0.001)。此外,最小靶剂量从71%±5%显著增加至80%±5%(p<0.001)。通过优化获得的OI和HI的改善取决于植入的规则性,因此对于不规则植入,优化的益处更大。OI和HI与靶体积密切相关,限制了这些参数在患者间剂量计划比较中的可用性。
驻留时间优化在均匀性、适形性、最小靶剂量和高剂量体积大小方面显著改善了剂量分布。图形优化快速、可重复且优于几何优化。
