Berthonnaud E, Hilmi R, Dimnet J
Centre Hospitalier de Villefranche/Saône, Villefranche-sur-Saône Cedex, France.
Surg Radiol Anat. 2009 Jul;31(6):461-70. doi: 10.1007/s00276-009-0468-0. Epub 2009 Feb 4.
The radiographic photogrammetry is applied, for locating anatomical landmarks in space, from their two projected images. The goal of this paper is to define a personalized geometric model of bones, based uniquely on photogrammetric reconstructions. The personalized models of bones are obtained from two successive steps: their functional frameworks are first determined experimentally, then, the 3D bone representation results from modeling techniques. Each bone functional framework is issued from direct measurements upon two radiographic images. These images may be obtained using either perpendicular (spine and sacrum) or oblique incidences (pelvis and lower limb). Frameworks link together their functional axes and punctual landmarks. Each global bone volume is decomposed in several elementary components. Each volumic component is represented by simple geometric shapes. Volumic shapes are articulated to the patient's bone structure. The volumic personalization is obtained by best fitting the geometric model projections to their real images, using adjustable articulations. Examples are presented to illustrating the technique of personalization of bone volumes, directly issued from the treatment of only two radiographic images. The chosen techniques for treating data are then discussed. The 3D representation of bones completes, for clinical users, the information brought by radiographic images.
应用射线摄影测量法,通过骨骼的两个投影图像在空间中定位解剖标志点。本文的目的是仅基于摄影测量重建来定义个性化的骨骼几何模型。骨骼的个性化模型通过两个连续步骤获得:首先通过实验确定其功能框架,然后通过建模技术得到三维骨骼表示。每个骨骼功能框架来自于对两张射线图像的直接测量。这些图像可以使用垂直入射(脊柱和骶骨)或斜入射(骨盆和下肢)获得。框架将其功能轴和点状标志点连接在一起。每个整体骨骼体积被分解为几个基本组件。每个体积组件由简单的几何形状表示。体积形状与患者的骨骼结构相连接。通过使用可调节关节将几何模型投影与真实图像进行最佳拟合来实现体积个性化。文中给出了示例,以说明仅通过处理两张射线图像直接实现骨骼体积个性化的技术。随后讨论了处理数据所选用的技术。骨骼的三维表示为临床用户完善了射线图像所提供的信息。
