Machine Learning-assisted Quantitative Mapping of Intracortical Axonal Plasticity Following a Focal Cortical Stroke in Rodents.

IF 1.8 4区 医学 Q3 MEDICINE, RESEARCH & EXPERIMENTAL
Hyung Soon Kim, Hyo Gyeong Seo, Jong Ho Jhee, Chang Hyun Park, Hyang Woon Lee, Bumhee Park, Byung Gon Kim
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引用次数: 1

Abstract

Stroke destroys neurons and their connections leading to focal neurological deficits. Although limited, many patients exhibit a certain degree of spontaneous functional recovery. Structural remodeling of the intracortical axonal connections is implicated in the reorganization of cortical motor representation maps, which is considered to be an underlying mechanism of the improvement in motor function. Therefore, an accurate assessment of intracortical axonal plasticity would be necessary to develop strategies to facilitate functional recovery following a stroke. The present study developed a machine learning-assisted image analysis tool based on multi-voxel pattern analysis in fMRI imaging. Intracortical axons originating from the rostral forelimb area (RFA) were anterogradely traced using biotinylated dextran amine (BDA) following a photothrombotic stroke in the mouse motor cortex. BDA-traced axons were visualized in tangentially sectioned cortical tissues, digitally marked, and converted to pixelated axon density maps. Application of the machine learning algorithm enabled sensitive comparison of the quantitative differences and the precise spatial mapping of the post-stroke axonal reorganization even in the regions with dense axonal projections. Using this method, we observed a substantial extent of the axonal sprouting from the RFA to the premotor cortex and the peri-infarct region caudal to the RFA. Therefore, the machine learningassisted quantitative axonal mapping developed in this study can be utilized to discover intracortical axonal plasticity that may mediate functional restoration following stroke.

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机器学习辅助的啮齿动物局灶性脑卒中后皮层内轴突可塑性定量映射。
中风破坏神经元及其连接,导致局灶性神经功能缺损。虽然有限,但许多患者表现出一定程度的自发功能恢复。皮层内轴突连接的结构重塑与皮层运动表征图的重组有关,这被认为是运动功能改善的潜在机制。因此,准确评估皮质内轴突可塑性对于制定促进中风后功能恢复的策略是必要的。本研究开发了一种基于功能磁共振成像中多体素模式分析的机器学习辅助图像分析工具。使用生物素化右旋糖酐胺(BDA)在小鼠运动皮质光血栓性中风后顺行追踪源自吻侧前肢区(RFA)的皮质内轴突。bda追踪的轴突在切线切片的皮质组织中可视化,进行数字标记,并转换为像素化轴突密度图。应用机器学习算法,即使在具有密集轴突投影的区域,也可以对中风后轴突重组的数量差异进行敏感的比较和精确的空间映射。使用这种方法,我们观察到从RFA到运动前皮层和RFA尾侧梗死周围区域的大量轴突萌芽。因此,本研究中开发的机器学习辅助定量轴突映射可以用来发现可能介导中风后功能恢复的皮质内轴突可塑性。
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来源期刊
Experimental Neurobiology
Experimental Neurobiology Neuroscience-Cellular and Molecular Neuroscience
CiteScore
4.30
自引率
4.20%
发文量
29
期刊介绍: Experimental Neurobiology is an international forum for interdisciplinary investigations of the nervous system. The journal aims to publish papers that present novel observations in all fields of neuroscience, encompassing cellular & molecular neuroscience, development/differentiation/plasticity, neurobiology of disease, systems/cognitive/behavioral neuroscience, drug development & industrial application, brain-machine interface, methodologies/tools, and clinical neuroscience. It should be of interest to a broad scientific audience working on the biochemical, molecular biological, cell biological, pharmacological, physiological, psychophysical, clinical, anatomical, cognitive, and biotechnological aspects of neuroscience. The journal publishes both original research articles and review articles. Experimental Neurobiology is an open access, peer-reviewed online journal. The journal is published jointly by The Korean Society for Brain and Neural Sciences & The Korean Society for Neurodegenerative Disease.
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