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一种对白质纤维束进行聚类的方法。

A method for clustering white matter fiber tracts.

作者信息

O'Donnell L J, Kubicki M, Shenton M E, Dreusicke M H, Grimson W E L, Westin C F

机构信息

MIT Computer Science and AI Lab, Cambridge, MA 02139, USA.

出版信息

AJNR Am J Neuroradiol. 2006 May;27(5):1032-6.

PMID:16687538
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2768142/
Abstract

BACKGROUND/PURPOSE: Despite its potential for visualizing white matter fiber tracts in vivo, diffusion tensor tractography has found only limited applications in clinical research in which specific anatomic connections between distant regions need to be evaluated. We introduce a robust method for fiber clustering that guides the separation of anatomically distinct fiber tracts and enables further estimation of anatomic connectivity between distant brain regions.

METHODS

Line scanning diffusion tensor images (LSDTI) were acquired on a 1.5T magnet. Regions of interest for several anatomically distinct fiber tracts were manually drawn; then, white matter tractography was performed by using the Runge-Kutta method to interpolate paths (fiber traces) following the major directions of diffusion, in which traces were seeded only within the defined regions of interest. Next, a fully automatic procedure was applied to fiber traces, grouping them according to a pairwise similarity function that takes into account the shapes of the fibers and their spatial locations.

RESULTS

We demonstrated the ability of the clustering algorithm to separate several fiber tracts which are otherwise difficult to define (left and right fornix, uncinate fasciculus and inferior occipitofrontal fasciculus, and corpus callosum fibers).

CONCLUSION

This method successfully delineates fiber tracts that can be further analyzed for clinical research purposes. Hypotheses regarding specific fiber connections and their abnormalities in various neuropsychiatric disorders can now be tested.

摘要

背景/目的:尽管扩散张量纤维束成像在体内可视化白质纤维束方面具有潜力,但在需要评估远处区域之间特定解剖连接的临床研究中,其应用仍然有限。我们介绍一种强大的纤维聚类方法,该方法可指导解剖学上不同的纤维束分离,并能够进一步估计远处脑区之间的解剖连接性。

方法

在1.5T磁体上采集线扫描扩散张量图像(LSDTI)。手动绘制几个解剖学上不同的纤维束的感兴趣区域;然后,使用龙格-库塔方法沿扩散的主要方向内插路径(纤维轨迹)来进行白质纤维束成像,其中轨迹仅在定义的感兴趣区域内播种。接下来,对纤维轨迹应用全自动程序,根据考虑纤维形状及其空间位置的成对相似性函数对它们进行分组。

结果

我们证明了聚类算法能够分离出其他情况下难以定义的几个纤维束(左右穹窿、钩束和枕颞下束以及胼胝体纤维)。

结论

该方法成功描绘了可用于临床研究目的进行进一步分析的纤维束。现在可以测试关于各种神经精神疾病中特定纤维连接及其异常的假设。

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