The Size of a Cortical Representation

皮质表征的大小

• 批准号: 7380340
• 负责人: RON D FROSTIG
• 金额: $ 32.12万
• 依托单位: UNIVERSITY OF CALIFORNIA-IRVINE
• 依托单位国家: 美国
• 财政年份: 2007
• 资助国家: 美国
• 起止时间: 2007-12-15 至 2012-11-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7380340
• 关键词: Accounting; Action Potentials; Address; Adult; Animal Model; Animals; Area; Auditory area; Brain; Clinical Research; Data; Electrodes; Epithelium; Event; Face; Flowers; Functional Imaging; Histology; Human; Image; Lead; Location; Maps; Measures; Metaphor; Methods; Neurons; Rattus; Reliance; Research; Resolution; Sensory; Signal Transduction; Somatosensory Cortex; Stimulus; Structure-Activity Relationship; Synaptic Potentials; Testing; Vibrissae; barrel cortex; base; experience; hemodynamics; interest; optical imaging; research study; response; sensory cortex; size; somatosensory; tool

DESCRIPTION (provided by applicant): Our research interests focus on the topographical mapping of sensory epithelia in sensory cortex and their plasticity. We are particularly interested in delineating the spatial extent of cortical activation (e.g., the spatial spread of all the responding neurons) to small (point) stimulation because it is fundamental to our understanding of cortical maps. Functional imaging methods are advantageous for characterizing the spatial extent because of their ability to provide quick, high spatial resolution assessment of activity from large cortical regions. However, one limitation of most of the functional imaging methods is that they rely on hemodynamic events that follow brain activation and therefore provide only an indirect means for assessing the spatial extent of the underlying neuronal evoked activation and thus imagers lack the means to assess the spread of neuronal activation using imaging. Because there is no direct way to verify the spatial extent of the underlying neuronal activation area in humans, imagers typically apply conservative thresholds for analysis that typically emphasize peak, or near peak activation areas. Such practice, however, may lead to a biased and possibly distorted view of cortical function because it may underestimate the real size of cortical activation. To address these issues, it is proposed to directly relate the spread of neuronal activation to the spread imaged by functional imaging of the same cortical area with the same stimulation. The point stimulation is either a whisker or a pure tone, and the spread of cortical activation is imaged by intrinsic signal optical imaging in the adult rat somatosensory and auditory cortex, respectively. Imaging results will be directly compared to post-imaging neuronal recording using electrode arrays within the imaged cortex. Imaging and neuronal results, in turn, will also be superimposed on the anatomical maps of the same areas to highlight cortical structure-function relationship related to the spread of activity. Because functional imaging methods can detect both suprathreshold (action potentials) and subthreshold (local field potentials), the spread of both types of neuronal activations will be recorded and compared with imaging results. Once the rules of mapping neuronal spread to imaging spread are quantified, it will enable unbiased, direct, imaging-based description of the entire somatosensory and auditory cortices using such rules.

描述（由申请人提供）：我们的研究兴趣集中在感觉皮层中感觉上皮的地形图及其可塑性。我们特别感兴趣的是描绘皮层激活的空间范围（例如，所有响应神经元的空间分布）到小（点）刺激，因为它是我们理解皮层地图的基础。功能成像方法是有利的表征的空间范围，因为它们的能力，提供快速，高空间分辨率的评估活动从大皮层区域。然而，大多数功能成像方法的一个局限性在于，它们依赖于脑激活之后的血液动力学事件，因此仅提供用于评估潜在神经元诱发激活的空间范围的间接手段，因此成像器缺乏使用成像来评估神经元激活的扩散的手段。因为没有直接的方法来验证人体内潜在神经元激活区域的空间范围，所以成像器通常应用保守阈值进行分析，其通常强调峰值或接近峰值的激活区域。然而，这种做法可能会导致对皮层功能的偏见和扭曲，因为它可能低估了皮层激活的真实的大小。为了解决这些问题，建议将神经元激活的扩散直接与通过具有相同刺激的相同皮层区域的功能成像成像而成像的扩散相关联。点刺激是胡须或纯音，和皮质激活的传播成像的内在信号光学成像在成年大鼠的体感和听觉皮层，分别。成像结果将直接与使用成像皮层内的电极阵列的成像后神经元记录进行比较。反过来，成像和神经元结果也将叠加在相同区域的解剖图上，以突出与活动扩散相关的皮质结构-功能关系。由于功能成像方法可以检测阈上（动作电位）和阈下（局部场电位），因此将记录两种类型的神经元激活的扩散并与成像结果进行比较。一旦神经元扩散映射到成像扩散的规则被量化，它将使得使用这些规则对整个体感和听觉皮层进行无偏的、直接的、基于成像的描述成为可能。