Philips Research North America, Briarcliff Manor, NY, USA.
Med Image Anal. 2011 Aug;15(4):426-37. doi: 10.1016/j.media.2011.01.006. Epub 2011 Feb 12.
In this paper, we introduce a novel and efficient approach for inferring articulated 3D spine models from operative images. The problem is formulated as a Markov Random Field which has the ability to encode global structural dependencies to align CT volume images. A personalized geometrical model is first reconstructed from preoperative images before surgery, and subsequently decomposed as a series of intervertebral transformations based on rotation and translation parameters. The shape transformation between the standing and lying poses is achieved by optimizing the deformations applied to the intervertebral transformations. Singleton and pairwise potentials measure the support from the data and geometrical dependencies between neighboring vertebrae respectively, while higher-order cliques (groups of vertebrae) are introduced to integrate consistency in regional curves. Local vertebra modifications are achieved through a constrained mesh relaxation technique. Optimization of model parameters in a multimodal context is achieved using efficient linear programming and duality. Experimental and clinical evaluation of the vertebra model alignment obtained from the proposed method gave promising results. Quantitative comparison to expert identification yields an accuracy of 1.8±0.7mm based on the localization of surgical landmarks.
在本文中,我们介绍了一种新颖而有效的方法,用于从手术图像推断关节 3D 脊柱模型。该问题被表述为马尔可夫随机场(MRF),它具有编码全局结构依赖关系以对齐 CT 体图像的能力。个性化的几何模型首先从前手术图像重建,然后根据旋转和平移参数分解为一系列椎间变换。通过优化施加到椎间变换的变形来实现站立和仰卧姿势之间的形状变换。单峰和双峰势分别测量来自数据和相邻椎体之间的几何依赖关系的支持,而高阶团块(一组椎体)被引入以整合区域曲线的一致性。通过受约束的网格松弛技术实现局部椎体修改。通过有效的线性规划和对偶性实现多峰模型参数的优化。对所提出方法获得的椎体模型配准的实验和临床评估给出了有希望的结果。基于手术标记的定位,与专家识别的定量比较产生了 1.8±0.7mm 的精度。
