Durrleman S, Pennec X, Trouvé A, Braga J, Gerig G, Ayache N
Scientific Computing and Imaging (SCI) Institute, 72 S. Central Drive, Salt Lake City, UT 84112, USA.
Int J Comput Vis. 2013 May;103(1):22-59. doi: 10.1007/s11263-012-0592-x.
This paper proposes an original approach for the statistical analysis of longitudinal shape data. The proposed method allows the characterization of typical growth patterns and subject-specific shape changes in repeated time-series observations of several subjects. This can be seen as the extension of usual longitudinal statistics of scalar measurements to high-dimensional shape or image data. The method is based on the estimation of continuous subject-specific growth trajectories and the comparison of such temporal shape changes across subjects. Differences between growth trajectories are decomposed into morphological deformations, which account for shape changes independent of the time, and time warps, which account for different rates of shape changes over time. Given a longitudinal shape data set, we estimate a mean growth scenario representative of the population, and the variations of this scenario both in terms of shape changes and in terms of change in growth speed. Then, intrinsic statistics are derived in the space of spatiotemporal deformations, which characterize the typical variations in shape and in growth speed within the studied population. They can be used to detect systematic developmental delays across subjects. In the context of neuroscience, we apply this method to analyze the differences in the growth of the hippocampus in children diagnosed with autism, developmental delays and in controls. Result suggest that group differences may be better characterized by a different speed of maturation rather than shape differences at a given age. In the context of anthropology, we assess the differences in the typical growth of the endocranium between chimpanzees and bonobos. We take advantage of this study to show the robustness of the method with respect to change of parameters and perturbation of the age estimates.
本文提出了一种用于纵向形状数据统计分析的原创方法。所提出的方法能够在对多个受试者的重复时间序列观测中,对典型生长模式和受试者特定的形状变化进行表征。这可以看作是将标量测量的常规纵向统计扩展到高维形状或图像数据。该方法基于对连续的受试者特定生长轨迹的估计以及对不同受试者间此类时间形状变化的比较。生长轨迹之间的差异被分解为形态变形(它解释了与时间无关的形状变化)和时间扭曲(它解释了随时间变化的不同形状变化速率)。给定一个纵向形状数据集,我们估计一个代表总体的平均生长情况,以及该情况在形状变化和生长速度变化方面的差异。然后,在时空变形空间中导出内在统计量,它表征了所研究总体内形状和生长速度的典型变化。它们可用于检测不同受试者间的系统性发育延迟。在神经科学背景下,我们应用此方法分析被诊断为患有自闭症、发育迟缓的儿童以及对照组儿童海马体生长的差异。结果表明,群体差异可能更好地由不同的成熟速度而非给定年龄时的形状差异来表征。在人类学背景下,我们评估黑猩猩和倭黑猩猩颅内膜典型生长的差异。我们利用这项研究来展示该方法在参数变化和年龄估计扰动方面的稳健性。