一种新型的用于 4D PET/CT 成像和同时整合增敏放疗的 3D 打印 phantom 插入物。
A novel 3D-printed phantom insert for 4D PET/CT imaging and simultaneous integrated boost radiotherapy.
机构信息
Department of Radiation Medicine and Applied Sciences, University of California San Diego, La Jolla, CA, 92093, USA.
Department of Radiation Oncology, Virginia Commonwealth University, Richmond, VA, 23298, USA.
出版信息
Med Phys. 2017 Oct;44(10):5467-5474. doi: 10.1002/mp.12495. Epub 2017 Aug 31.
PURPOSE
To construct a 3D-printed phantom insert designed to mimic the variable PET tracer uptake seen in lung tumor volumes and a matching dosimetric insert to be used in simultaneous integrated boost (SIB) phantom studies, and to evaluate the design through end-to-end tests.
METHODS
A set of phantom inserts was designed and manufactured for a realistic representation of gated radiotherapy steps from 4D PET/CT scanning to dose delivery. A cylindrical phantom (φ80 × 120 mm) holds inserts for PET/CT scanning. The novel 3D printed insert dedicated to 4D PET/CT mimics high PET tracer uptake in the core and low uptake in the periphery. This insert is a variable density porous cylinder (φ44.5 × 70.0 mm), ABS-P430 thermoplastic, 3D printed by fused deposition modeling an inner (φ11 × 42 mm) cylindrical void. The square pores (1.8 × 1.8 mm each) fill 50% of outer volume, resulting in a 2:1 PET tracer concentration ratio in the void volume with respect to porous volume. A matching cylindrical phantom insert is dedicated to validate gated radiotherapy. It contains eight peripheral holes and one central hole, matching the location of the porous part and the void part of the 3D printed insert, respectively. These holes accommodate adaptors for Farmer-type ion chamber and cells vials. End-to-end tests were designed for imaging, planning, and dose measurements.
RESULTS
End-to-end test were performed from 4D PET/CT scanning to transferring data to the planning system, target volume delineation, and dose measurements. 4D PET/CT scans were acquired of the phantom at different respiratory motion patterns and gating windows. A measured 2:1 18F-FDG concentration ratio between inner void and outer porous volume matched the 3D printed design. Measured dose in the dosimetric insert agreed well with planned dose on the imaging insert, within 3% for the static phantom and within 5% for most breathing patterns.
CONCLUSIONS
The novel 3D printed phantom insert mimics variable PET tracer uptake typical of tumors. Obtained 4D PET/CT scans are suitable for segmentation and treatment planning and delivery in SIB gated treatments. Our experiments demonstrate the feasibility of this set of phantom inserts serving as end-to-end quality-assurance phantoms of SIB radiotherapy.
目的
构建一个 3D 打印的模体插入物,旨在模拟肺肿瘤体积中可见的可变 PET 示踪剂摄取,并构建一个匹配的剂量学插入物,用于同时进行集成增强(SIB)模体研究,并通过端到端测试对设计进行评估。
方法
设计并制造了一组模体插入物,以真实地再现从 4D PET/CT 扫描到剂量传递的门控放射治疗步骤。一个圆柱形模体(φ80×120mm)容纳用于 PET/CT 扫描的插入物。新型 3D 打印的 4D PET/CT 专用插入物模拟了核心区域高 PET 示踪剂摄取和外围低摄取。该插入物是一个可变密度多孔圆柱体(φ44.5×70.0mm),采用熔融沉积建模的 ABS-P430 热塑性塑料 3D 打印,内部有一个(φ11×42mm)圆柱形空腔。正方形孔(每个 1.8×1.8mm)填充 50%的外体积,导致空腔体积与多孔体积的 PET 示踪剂浓度比为 2:1。一个匹配的圆柱形模体插入物专门用于验证门控放射治疗。它包含八个外围孔和一个中央孔,分别与 3D 打印插入物的多孔部分和空腔部分的位置相对应。这些孔容纳适用于 Farmer 型电离室和细胞小瓶的适配器。设计了端到端测试,用于成像、计划和剂量测量。
结果
进行了从 4D PET/CT 扫描到将数据传输到计划系统、靶区勾画和剂量测量的端到端测试。对不同呼吸运动模式和门控窗下的模体进行了 4D PET/CT 扫描。测量的内空腔和外多孔体积之间的 18F-FDG 浓度比为 2:1,与 3D 打印设计相匹配。剂量学插入物中的测量剂量与成像插入物中的计划剂量非常吻合,静态模体的误差在 3%以内,大多数呼吸模式的误差在 5%以内。
结论
新型 3D 打印的模体插入物模拟了肿瘤中常见的可变 PET 示踪剂摄取。获得的 4D PET/CT 扫描适用于 SIB 门控治疗中的分割和治疗计划以及传递。我们的实验证明了这组模体插入物作为 SIB 放射治疗端到端质量保证模体的可行性。
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