内囊前缘切口的可重复管道。

Karianne Sretavan, Henry Braun, Zoe Liu, Daniel Bullock, Tara Palnitkar, Remi Patriat, Jayashree Chandrasekaran, Samuel Brenny, Matthew D Johnson, Alik S Widge, Noam Harel, Sarah R Heilbronner
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引用次数: 0

摘要

背景:内囊前肢(ALIC)是连接前额叶皮质(PFC)与脑干、丘脑和丘脑下核的白质结构。它是治疗强迫症的脑深部刺激(DBS)靶点。人们对通过使用弥散束成像技术重建和定位特定的 ALIC 纤维通路来改善 DBS 定位有浓厚的兴趣,但这种方法容易出错,而且缺乏验证。为了解决这些局限性,我们开发了一种新型扩散束成像管道,可生成可靠且经过生物学验证的 ALIC 白质重建:在算法开发和改进之后,我们分析了 43 名对照组受试者的 2 组 3T MRI 数据,以及 5 名对照组受试者的子集,这些数据来自人类连接组计划的 7T 数据。我们根据感兴趣的前额叶 PFC 区域生成了 22 个分段 ALIC 纤维束(每个半球 11 个),并分析了纤维束之间的关系:结果:我们利用 3T 和 7T 获取的图像,成功地再现了先前解剖学工作所建立的拓扑图。定量评估结果表明,除一个前脑功能区外,测试组和复测组的受试者内变异性明显小于受试者间变异性。我们检查了来自不同 PFC 区域的纤维与强迫症深部脑刺激反应束之间的重叠情况,并使用我们管道的改进版本重建了 PFC 超直达通路:我们的 dMRI 算法能可靠地生成经过生物学验证的 ALIC 白质重建,从而为神经调控疗法提供更精确的纤维建模。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Reproducible Pipeline for Parcellation of the Anterior Limb of the Internal Capsule.

Background: The anterior limb of the internal capsule (ALIC) is a white matter structure that connects the prefrontal cortex (PFC) to the brainstem, thalamus, and subthalamic nucleus. It is a target for deep brain stimulation for obsessive-compulsive disorder. There is strong interest in improving deep brain stimulation targeting by using diffusion tractography to reconstruct and target specific ALIC fiber pathways, but this methodology is susceptible to errors and lacks validation. To address these limitations, we developed a novel diffusion tractography pipeline that generates reliable and biologically validated ALIC white matter reconstructions.

Methods: Following algorithm development and refinement, we analyzed 43 control participants, each with 2 sets of 3T magnetic resonance imaging data and a subset of 5 control participants with 7T data from the Human Connectome Project. We generated 22 segmented ALIC fiber bundles (11 per hemisphere) based on PFC regions of interest, and we analyzed the relationships among bundles.

Results: We successfully reproduced the topographies established by previous anatomical work using images acquired at both 3T and 7T. Quantitative assessment demonstrated significantly smaller intraparticipant variability than interparticipant variability for both test and retest groups across all but one PFC region. We examined the overlap between fibers from different PFC regions and a response tract for obsessive-compulsive disorder deep brain stimulation, and we reconstructed the PFC hyperdirect pathway using a modified version of our pipeline.

Conclusions: Our diffusion magnetic resonance imaging algorithm reliably generates biologically validated ALIC white matter reconstructions, thereby allowing for more precise modeling of fibers for neuromodulation therapies.

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