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重建皮质脊髓束的躯体感觉组织仍然是现代束追踪方法的一个挑战。

Reconstructing the somatotopic organization of the corticospinal tract remains a challenge for modern tractography methods.

机构信息

Institution of Information Processing and Automation, Zhejiang University of Technology, Hangzhou, China.

Department of Radiology, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts, USA.

出版信息

Hum Brain Mapp. 2023 Dec 1;44(17):6055-6073. doi: 10.1002/hbm.26497. Epub 2023 Oct 4.

DOI:10.1002/hbm.26497
PMID:37792280
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10619402/
Abstract

The corticospinal tract (CST) is a critically important white matter fiber tract in the human brain that enables control of voluntary movements of the body. The CST exhibits a somatotopic organization, which means that the motor neurons that control specific body parts are arranged in order within the CST. Diffusion magnetic resonance imaging (MRI) tractography is increasingly used to study the anatomy of the CST. However, despite many advances in tractography algorithms over the past decade, modern, state-of-the-art methods still face challenges. In this study, we compare the performance of six widely used tractography methods for reconstructing the CST and its somatotopic organization. These methods include constrained spherical deconvolution (CSD) based probabilistic (iFOD1) and deterministic (SD-Stream) methods, unscented Kalman filter (UKF) tractography methods including multi-fiber (UKF2T) and single-fiber (UKF1T) models, the generalized q-sampling imaging (GQI) based deterministic tractography method, and the TractSeg method. We investigate CST somatotopy by dividing the CST into four subdivisions per hemisphere that originate in the leg, trunk, hand, and face areas of the primary motor cortex. A quantitative and visual comparison is performed using diffusion MRI data (N = 100 subjects) from the Human Connectome Project. Quantitative evaluations include the reconstruction rate of the eight anatomical subdivisions, the percentage of streamlines in each subdivision, and the coverage of the white matter-gray matter (WM-GM) interface. CST somatotopy is further evaluated by comparing the percentage of streamlines in each subdivision to the cortical volumes for the leg, trunk, hand, and face areas. Overall, UKF2T has the highest reconstruction rate and cortical coverage. It is the only method with a significant positive correlation between the percentage of streamlines in each subdivision and the volume of the corresponding motor cortex. However, our experimental results show that all compared tractography methods are biased toward generating many trunk streamlines (ranging from 35.10% to 71.66% of total streamlines across methods). Furthermore, the coverage of the WM-GM interface in the largest motor area (face) is generally low (under 40%) for all compared tractography methods. Different tractography methods give conflicting results regarding the percentage of streamlines in each subdivision and the volume of the corresponding motor cortex, indicating that there is generally no clear relationship, and that reconstruction of CST somatotopy is still a large challenge. Overall, we conclude that while current tractography methods have made progress toward the well-known challenge of improving the reconstruction of the lateral projections of the CST, the overall problem of performing a comprehensive CST reconstruction, including clinically important projections in the lateral (hand and face areas) and medial portions (leg area), remains an important challenge for diffusion MRI tractography.

摘要

皮质脊髓束(CST)是人类大脑中至关重要的白质纤维束,能够控制身体的随意运动。CST 表现出一种躯体定位组织,这意味着控制特定身体部位的运动神经元按照顺序排列在 CST 中。扩散磁共振成像(MRI)示踪技术越来越多地用于研究 CST 的解剖结构。然而,尽管在过去十年中,示踪技术算法取得了许多进展,但现代最先进的方法仍然面临挑战。在这项研究中,我们比较了六种广泛使用的示踪方法重建 CST 及其躯体定位组织的性能。这些方法包括基于约束球分解(CSD)的概率(iFOD1)和确定性(SD-Stream)方法、无迹卡尔曼滤波(UKF)示踪方法,包括多纤维(UKF2T)和单纤维(UKF1T)模型、基于广义 q 采样成像(GQI)的确定性示踪方法以及 TractSeg 方法。我们通过将 CST 分为四个亚区,每个亚区起源于初级运动皮层的腿部、躯干、手部和面部区域,来研究 CST 的躯体定位组织。我们使用来自人类连接组计划的扩散 MRI 数据(N=100 个受试者)进行了定量和可视化比较。定量评估包括八个解剖亚区的重建率、每个亚区的流线百分比以及白质-灰质(WM-GM)界面的覆盖范围。通过比较每个亚区的流线百分比与腿部、躯干、手部和面部区域的皮质体积,进一步评估 CST 的躯体定位组织。总体而言,UKF2T 的重建率和皮质覆盖率最高。它是唯一一种与每个亚区流线百分比与相应运动皮层体积之间存在显著正相关的方法。然而,我们的实验结果表明,所有比较的示踪方法都偏向于生成许多躯干流线(在所有方法中,从 35.10%到 71.66%的流线都是躯干流线)。此外,对于所有比较的示踪方法,最大运动区域(面部)的 WM-GM 界面的覆盖范围通常较低(低于 40%)。不同的示踪方法在每个亚区的流线百分比和相应运动皮层的体积方面给出了相互矛盾的结果,表明通常没有明确的关系,并且 CST 躯体定位组织的重建仍然是扩散 MRI 示踪技术的一个重大挑战。总的来说,我们得出结论,尽管当前的示踪方法在改善 CST 外侧投影的重建方面取得了进展,但全面重建 CST 的总体问题,包括在外侧(手部和面部区域)和内侧部分(腿部区域)的临床重要投影,仍然是扩散 MRI 示踪技术的一个重要挑战。

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