Biomechanics of the Semicircular Canals

半规管的生物力学

• 批准号: 6872804
• 负责人: RICHARD D RABBITT
• 金额: $ 38.91万
• 依托单位: UNIVERSITY OF UTAH
• 依托单位国家: 美国
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-12-15 至 2007-11-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6872804
• 关键词: Osteichthyes; behavioral /social science research tag; biological signal transduction; biomechanics; calcium carbonate; computer simulation; ear hair cell; electrical impedance; electrophysiology; endolymph; mathematical model; mechanical pressure; mechanoreceptors; membrane potentials; motion perception; organ of Corti; otocyst /otolith; semicircular duct; sensory mechanism; vertigo

DESCRIPTION (provided by applicant): The present work seeks to advance quantitative understanding of semicircular canal biomechanics under both physiological and pathological conditions with the goals of 1) improving the assessment and treatment of benign paroxysmal positional vertigo (BPPV) and 2) furthering the basic understanding of micromechanical and hair cell electro-mechanical factors in the process of angular motion sensation. Specifically, the work aims to: quantify the three-dimensional substrates of canalolithiasis and its relationship to BPPV, determine micromechanical contributions to spatial diversity in hair-cell activation and afferent response dynamics and, establish the role of hair-cell electro-mechanical feedback in the crista ampullaris. The first aim will detail biomechanical and neural responses under conditions of experimentally induced canalolithiasis during provocative diagnostic tests and during canalith repositioning procedures. The second aim will determine micromechanical and hair cell transduction current contributions to the diverse neural code transmitted from the semicircular canals to the brain. Regional differences in cupula motion will be measured during sinusoidal and step stimuli using a laser interferometer. The spatial distribution of haircell transduction currents will be mapped across the sensory epithelium and compared to micromechanical data to determine the relative contributions of each. Experiments to investigate the role of hair cell/bundle electro-motility will be included. The third aim will investigate the influence of activation of the efferent vestibular system and, separately, electrical polarization of the endolymph on hair-cell and micromechanical responses. Detailed mathematical models will be used extensively to interpret results and direct the experimental studies. Computer models and animations showing responses to clinical diagnostic tests and canalith repositioning procedures will be generated. Results are expected to have immediate relevance to health and the human condition through the assessment and treatment of classical and non-classical BPPV as well as long-term significance enhancing basic understanding of semicircular canal micro-mechanics, haircell transduction and electro-mechanical feedback.

描述（由申请人提供）：本工作旨在促进对生理和病理条件下半规管生物力学的定量理解，目标是 1) 改进良性阵发性位置性眩晕 (BPPV) 的评估和治疗，2) 进一步推进基础研究了解角运动感觉过程中的微机械和毛细胞机电因素。具体来说，这项工作的目的是：量化管道结石的三维基质及其与 BPPV 的关系，确定微机械对毛细胞激活和传入反应动力学空间多样性的贡献，并建立毛细胞机电反馈在壶腹嵴。第一个目标将详细描述在刺激性诊断测试和耳管重新定位过程中实验诱发耳管结石条件下的生物力学和神经反应。第二个目标将确定微机械和毛细胞转导电流对从半规管传输到大脑的不同神经代码的贡献。将使用激光干涉仪在正弦和阶跃刺激期间测量顶盖运动的区域差异。毛细胞转导电流的空间分布将被绘制在感觉上皮上，并与微机械数据进行比较，以确定每个电流的相对贡献。将包括研究毛细胞/毛束电动性作用的实验。第三个目标将分别研究传出前庭系统激活以及内淋巴电极化对毛细胞和微机械反应的影响。详细的数学模型将被广泛使用来解释结果并指导实验研究。将生成显示对临床诊断测试和耳道重新定位程序的反应的计算机模型和动画。通过经典和非经典 BPPV 的评估和治疗，结果预计将与健康和人类状况产生直接相关性，并具有长期意义，增强对半规管微观力学、毛细胞转导和机电反馈的基本理解。