Pollmann Stephan, Toussaint André, Flentje Michael, Wegener Sonja, Lewitzki Victor
University Hospital Würzburg, Würzburg, Germany.
Front Oncol. 2022 Aug 10;12:881439. doi: 10.3389/fonc.2022.881439. eCollection 2022.
Boluses are routinely used in radiotherapy to modify surface doses. Nevertheless, considerable dose discrepancies may occur in some cases due to fit inaccuracy of commercially available standard flat boluses. Moreover, due to the simple geometric design of conventional boluses, also surrounding healthy skin areas may be unintentionally covered, resulting in the unwanted dose buildup. With the fused deposition modeling (FDM) technique, there is a simple and possibly cost-effective way to solve these problems in routine clinical practice. This paper presents a procedure of self-manufacturing bespoke patient-specific silicone boluses and the evaluation of buildup and fit accuracy in comparison to standard rectangular commercially available silicone boluses.
3D-conformal silicone boluses were custom-built to cover the surgical scar region of 25 patients who received adjuvant radiotherapy of head and neck cancer at the University Hospital Würzburg. During a standard CT-based planning procedure, a 5-mm-thick 3D bolus contour was generated to cover the radiopaque marked surgical scar with an additional safety margin. From these digital contours, molds were 3D printed and poured with silicone. Dose measurements for both types of boluses were performed with radiochromic films (EBT3) at three points per patient-at least one aimed to be in the high-dose area (scar) and one in the lower-dose area (spared healthy skin). Surface-bolus distance, which ideally should not be present, was determined from cone-beam CT performed for positioning control. The dosimetric influence of surface-bolus distance was also determined on slab phantom for different field sizes. The trial was performed with hardware that may be routinely available in every radiotherapy department, with the exception of the 3D printer. The required number of patients was determined based on the results of preparatory measurements with the help of the statistical consultancy of the University of Würzburg. The number of measuring points represents the total number of patients.
In the high-dose area of the scar, there was a significantly better intended dose buildup of 2.45% (95%CI 0.0014-0.0477, p = 0.038, N = 30) in favor of a 3D-conformal bolus. Median distances between the body surface and bolus differed significantly between 3D-conformal and commercially available boluses (3.5 vs. 7.9 mm, p = 0.001). The surface dose at the slab phantom did not differ between commercially available and 3D-conformal boluses. Increasing the surface-bolus distance from 5 to 10 mm decreased the surface dose by approximately 2% and 11% in the 6 × 6- and 3 × 3-cm fields, respectively. In comparison to the commercially available bolus, an unintended dose buildup in the healthy skin areas was reduced by 25.9% (95%CI 19.5-32.3, p < 0.01, N = 37) using the 3D-conformal bolus limited to the region surrounding the surgical scar.
Using 3D-conformal boluses allows a comparison to the commercially available boluses' dose buildup in the covered areas. Smaller field size is prone to a larger surface-bolus distance effect. Higher conformity of 3D-conformal boluses reduces this effect. This may be especially relevant for volumetric modulated arc therapy (VMAT) and intensity-modulated radiotherapy (IMRT) techniques with a huge number of smaller fields. High conformity of 3D-conformal boluses reduces an unintended dose buildup in healthy skin. The limiting factor in the conformity of 3D-conformal boluses in our setting was the immobilization mask, which was produced primarily for the 3D boluses. The mask itself limited tight contact of subsequently produced 3D-conformal boluses to the mask-covered body areas. In this respect, bolus adjustment before mask fabrication will be done in the future setting.
在放射治疗中,常规使用填充物来调整表面剂量。然而,由于市售标准扁平填充物的贴合不准确,在某些情况下可能会出现相当大的剂量差异。此外,由于传统填充物的几何设计简单,周围的健康皮肤区域也可能被无意覆盖,导致不必要的剂量累积。利用熔融沉积建模(FDM)技术,在常规临床实践中有一种简单且可能具有成本效益的方法来解决这些问题。本文介绍了一种自行制造定制患者专用硅胶填充物的方法,并与市售标准矩形硅胶填充物相比,评估了剂量累积和贴合精度。
为25例在维尔茨堡大学医院接受头颈癌辅助放疗的患者定制3D适形硅胶填充物,以覆盖手术瘢痕区域。在基于CT的标准治疗计划过程中,生成一个5毫米厚的3D填充物轮廓,以覆盖不透射线标记的手术瘢痕,并留有额外的安全 margin。根据这些数字轮廓,3D打印模具并注入硅胶。两种类型的填充物均使用放射变色胶片(EBT3)在每位患者的三个点进行剂量测量,至少一个点位于高剂量区域(瘢痕),一个点位于低剂量区域(未受照射的健康皮肤)。通过用于定位控制的锥形束CT确定理想情况下不应存在的表面与填充物之间的距离。还在平板体模上针对不同的射野大小确定了表面与填充物之间距离的剂量学影响。该试验使用的硬件除3D打印机外,每个放疗科可能都有。所需患者数量根据维尔茨堡大学统计咨询机构的预备测量结果确定。测量点数代表患者总数。
在瘢痕的高剂量区域,3D适形填充物的预期剂量累积明显更好,为2.45%(95%CI 0.0014 - 0.0477,p = 0.038,N = 30)。3D适形填充物与市售填充物之间体表与填充物的中位距离存在显著差异(3.5对7.9毫米,p = 0.001)。平板体模上的表面剂量在市售填充物和3D适形填充物之间没有差异。在6×6厘米和3×3厘米射野中,将表面与填充物之间的距离从5毫米增加到10毫米,表面剂量分别降低约2%和11%。与市售填充物相比,使用仅限于手术瘢痕周围区域的3D适形填充物,健康皮肤区域的意外剂量累积减少了25.9%(95%CI 19.5 - 32.3,p < 0.01,N = 37)。
使用3D适形填充物可以与市售填充物在覆盖区域的剂量累积进行比较。较小的射野大小更容易受到较大的表面与填充物之间距离效应的影响。3D适形填充物的更高适形性可降低这种效应。这对于具有大量较小射野的容积调强弧形放疗(VMAT)和调强放疗(IMRT)技术可能尤其重要。3D适形填充物的高适形性可减少健康皮肤中的意外剂量累积。在我们的研究中,3D适形填充物适形性的限制因素是固定面罩,其主要是为3D填充物制作的。面罩本身限制了随后制作的3D适形填充物与面罩覆盖的身体区域的紧密接触。在这方面,未来将在制作面罩之前进行填充物调整。
