Maria Agnese Pirozzi, Valeria Gaudieri, Anna Prinster, Mario Magliulo, Alberto Cuocolo, Arturo Brunetti, Bruno Alfano, Mario Quarantelli
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引用次数: 0
摘要
本文描述了一种创新的多室解剖脑模型(StepBrain),用于模拟灰质、白质和纹状体的体内示踪剂摄取,克服了现有模型的局限性。方法:StepBrain 是利用融合沉积建模三维打印技术的潜力制作的,通过对健康志愿者的磁共振图像进行特别处理来复制大脑各区的真实解剖结构。结果:使用为人体 PET 研究开发的部分容积效应校正工具进行后处理的结果证实了这些方法在恢复目标活性浓度方面的准确性。结论StepBrain分区(灰质、白质和纹状体)可同时填充,实现不同的浓度比,并可模拟不同的(如淀粉样蛋白、tau或6-氟-l-多巴)示踪剂分布,对多中心PET协调研究具有潜在的价值。
StepBrain: A 3-Dimensionally Printed Multicompartmental Anthropomorphic Brain Phantom to Simulate PET Activity Distributions.
An innovative multicompartmental anatomic brain phantom (StepBrain) is described to simulate the in vivo tracer uptake of gray matter, white matter, and striatum, overcoming the limitations of currently available phantoms. Methods: StepBrain was created by exploiting the potential of fused deposition modeling 3-dimensional printing to replicate the real anatomy of the brain compartments, as modeled through ad hoc processing of healthy-volunteer MR images. Results: A realistic simulation of 18F-FDG PET brain studies, using target activity to obtain the real concentration ratios, was obtained, and the results of postprocessing with partial-volume effect correction tools developed for human PET studies confirmed the accuracy of these methods in recovering the target activity concentrations. Conclusion: StepBrain compartments (gray matter, white matter, and striatum) can be simultaneously filled, achieving different concentration ratios and allowing the simulation of different (e.g., amyloid, tau, or 6-fluoro-l-dopa) tracer distributions, with a potentially valuable role for multicenter PET harmonization studies.