Three-dimensional and Multiscale Organ of Corti Biomechanics

三维多尺度柯蒂氏器官生物力学

• 批准号: 7352734
• 负责人: CHARLES Richard STEELE
• 金额: $ 25.97万
• 依托单位: STANFORD UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2007
• 资助国家: 美国
• 起止时间: 2007-02-05 至 2011-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7352734
• 关键词: Acoustics; Affect; Air; Anatomy; Atomic Force Microscopy; Basilar Membrane; Behavior; Biomechanics; Biophysics; Bone Conduction; Cell physiology; Characteristics; Cilia; Clinic; Clinical; Cochlea; Cochlear duct; Complement; Complex; Computer Simulation; Confocal Microscopy; Data; Development; Dimensions; Ear; Environment; Foundations; Frequencies; Future; Goals; Hair Cells; Health; Hearing; In Vitro; Individual; Inner Hair Cells; Intervention; Knowledge; Laboratories; Lead; Light; Link; Liquid substance; Measurement; Measures; Mechanics; Methods; Microanatomy; Modeling; Motion; Natural regeneration; Noise; Numbers; Organ of Corti; Otolaryngology; Outcome; Outer Hair Cells; Pathologic; Pathology; Pathway interactions; Physiological; Physiology; Process; Property; Publishing; Range; Reporting; Research; Research Personnel; Resolution; Signal Transduction; Solutions; Stimulus; Structure; Structure-Activity Relationship; Testing; Therapeutic; Tissues; Travel; Vestibular membrane; Vestibule; Work; base; bone; cell motility; computer framework; electric impedance; genetic manipulation; improved; in vivo; inner ear diseases; innovation; middle ear; millimeter; nanomechanics; nanoscale; neuronal cell body; physical model; pressure; prevent; programs; receptor; relating to nervous system; response; sound; theories; three-dimensional modeling; transmission process

DESCRIPTION (provided by applicant): Our long-term goal is to understand the cochlear mechanisms that support the high sensitivity, high frequency resolution, and non-linear properties of normal hearing, which will then allow functional characterization of changes to these structures arising from a variety of cochlear pathologies, or from current interventions, or from future interventions such as regeneration of cochlear sub structures. Our approach is to develop physically based, three-dimensional, dynamic computational models that incorporate new and existing information on cochlear structures and properties, dimensions and geometry of structures in the organ of Corti and characteristics of the surrounding cellular and fluid environment to a degree of detail not previously achieved. Asymptotic and numerical methods will be combined for very fast and efficient calculations. Some eighty parameters of geometry and material properties will be used to define a comprehensive cross section of the cochlear structures, including the millimeter scale of the bony shelf and Reissner's membrane, micrometer scale of hair cell soma, and the nanometer scale of the tip links of cilia. This approach is necessary to integrate and understand the increasingly precise microanatomy measures reported by several laboratories including ours, to explain the dynamic biomechanical interaction of these structures and to resolve existing questions. In the first aim, a full model consideration will be given to linear effects including the incorporation of traveling waves and non-linear effects, including incorporation of electromotility of the outer hair cells. The second aim will be to use this modeling capability to investigate cochlear responses from bone conduction signals. Despite the importance of bone conducted stimulation in nearly all otolaryngology clinics, no current theory is widely accepted, recent measurements are difficult to interpret in light of existing theory, and no physically-based computational model has previously been made. The completion of this proposal will therefore form the core foundation that is expected to fundamentally alter our understanding of cochlear function, pathology and intervention. The results will be applicable to understanding the biomechanical effects of genetic manipulations of the organ of Corti cytoarchitecture and improving understanding of bone-conduction pathways to the cochlea in high noise environments where normal hearing protection is inadequate.

描述(申请人提供)：我们的长期目标是了解支持正常听力的高灵敏度、高频分辨率和非线性特性的耳蜗机制，这将使我们能够从功能上描述由各种耳蜗病理学、当前干预或未来干预(如耳蜗亚结构再生)引起的这些结构的变化。我们的方法是开发基于物理的、三维的、动态的计算模型，其中包含关于耳蜗器的结构和特性、尺寸和几何以及周围细胞和流体环境的特征的新的和现有的信息，达到以前没有达到的详细程度。渐近方法和数值方法将结合起来，以实现非常快速和有效的计算。约80个几何和材料特性参数将被用来定义耳蜗骨结构的全面横截面，包括骨架和Reissner膜的毫米尺度，毛细胞胞体的微米尺度，以及纤毛尖端连接的纳米尺度。这一方法对于整合和理解包括我们在内的几个实验室报道的日益精确的显微解剖测量，解释这些结构的动态生物力学相互作用和解决现有问题是必要的。在第一个目标中，模型将充分考虑线性效应，包括行波效应和非线性效应，包括外毛细胞的电动效应。第二个目标将是利用这种建模能力来研究来自骨传导信号的耳蜗反应。尽管骨传导刺激在几乎所有的耳鼻喉科临床中都很重要，但目前还没有被广泛接受的理论，最近的测量结果很难根据现有的理论来解释，以前也没有建立过基于物理的计算模型。因此，这一提议的完成将形成核心基础，有望从根本上改变我们对耳蜗功能、病理学和干预的理解。这些结果将适用于理解Corti细胞结构器官的遗传操作的生物力学效应，并提高对高噪声环境中正常听力保护不足的耳蜗骨传导路径的理解。