Inter-institutional protocol describing the use of three-dimensional printing for surgical planning in a patient with childhood epilepsy: From 3D modeling to neuronavigation

C. Rondinoni, V. Souza, R. Matsuda, A. Peres, M. Santos, O. B. Filho, A. C. Santos, H. Machado, P. Noritomi, Jorge Silva
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引用次数: 6

Abstract

This study is the first step in an effort to develop three-dimensional (3D) printing for use in pediatric surgical planning. In order to accomplish this, we established an effective collaboration between Ribeirao Preto Clinics Hospital (HCRP) and Renato Archer Center for Information Technology (CTI). Printed biomodels can be used to support discussions, decision-making, and neuronavigation before surgery. The main purpose of 3D printing for specific case handling is to reduce damage by enhancing knowledge of orientation during surgical planning and personnel training before surgery. Here, we produced an object that represented the brain and face segment of a patient via additive manufacturing technology based on magnetic resonance imaging (MRI) data. Specific landmarks were measured by three distinct methods: manual caliper, an InVesalius software measurement tool, and neuronavigation coordinate detection. The mean coefficient of variation was 7.17% between all methods and landmarks measured. Our results validate the combined use of biomodels with InVesalius software tools for the assessment of individual brain anatomy facilitating manual handling and visualization of 3D models. The establishment of communication protocols between the teams involved, as well as navigation protocols for quality control, presents the possibility of developing long term training programs, and promotes the congregation of individuals from research areas in Medical Physics, Medical Sciences, and Neuroscience.
描述在儿童癫痫患者手术计划中使用三维打印的机构间协议:从3D建模到神经导航
这项研究是开发用于儿科手术计划的三维(3D)打印技术的第一步。为了实现这一目标,我们在里贝罗普雷图诊所医院(HCRP)和雷纳托阿彻信息技术中心(CTI)之间建立了有效的合作关系。打印的生物模型可用于在手术前支持讨论、决策和神经导航。3D打印用于具体病例处理的主要目的是通过增强手术计划期间的定向知识和术前人员培训来减少损伤。在这里,我们通过基于磁共振成像(MRI)数据的增材制造技术制作了一个代表患者大脑和面部部分的物体。通过三种不同的方法测量特定的地标:手动卡尺,InVesalius软件测量工具和神经导航坐标检测。所有方法与测量的标志之间的平均变异系数为7.17%。我们的研究结果验证了生物模型与InVesalius软件工具的结合使用,以评估个体大脑解剖结构,促进手动处理和3D模型的可视化。在相关团队之间建立通信协议,以及质量控制的导航协议,提供了开发长期培训计划的可能性,并促进了来自医学物理学、医学科学和神经科学研究领域的个人的聚集。
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