区分脊髓运动神经元亚型以了解其回路的功能和障碍。
Distinguishing subtypes of spinal locomotor neurons to inform circuit function and dysfunction.
机构信息
Marion Murray Spinal Cord Research Center, Department of Neurobiology and Anatomy, Drexel University College of Medicine, Philadelphia, PA 19129, USA.
出版信息
Curr Opin Neurobiol. 2023 Oct;82:102763. doi: 10.1016/j.conb.2023.102763. Epub 2023 Aug 21.
Abstract
Locomotion is a complex motor task executed by spinal neurons. Given the diversity of spinal cord neurons, linking neuronal cell type to function is a challenge. Molecular identification of broad spinal interneuronal classes provided a great advance. Recent studies have used other classifiers, including location, electrophysiological properties, and connectivity, in addition to gene profiling, to narrow the acuity with which groups of neurons can be related to specific functions. However, there are also functional populations without a clear identifier, as exemplified by rhythm generating neurons. Other considerations, including experience or plasticity, add a layer of complexity to the definition of functional subpopulations of spinal neurons, but spinal cord injury may provide insight.
摘要
运动是由脊髓神经元执行的一项复杂的运动任务。鉴于脊髓神经元的多样性,将神经元细胞类型与功能联系起来是一个挑战。广泛的脊髓中间神经元类别的分子鉴定取得了重大进展。最近的研究除了基因分析外,还使用了其他分类器,包括位置、电生理特性和连接性,以提高将神经元群体与特定功能相关联的准确性。然而,也有一些功能群体没有明确的标识符,例如产生节律的神经元。其他因素,包括经验或可塑性,为脊髓神经元的功能亚群的定义增加了一层复杂性,但脊髓损伤可能提供一些启示。
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