Sympathetic neural discharge patterns, co-transmitters and neurovascular control

交感神经放电模式、共递质和神经血管控制

• 批准号: 217916-2008
• 负责人: Shoemaker, Kevin
• 金额: $ 3.28万
• 依托单位: University of Western Ontario
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2009
• 资助国家: 加拿大
• 起止时间: 2009-01-01 至 2010-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=424984
• 关键词: Sympathetic; neural; discharge; patterns; co

The sympathetic nervous system is an important regulator of moment-by-moment changes in blood pressure through changes in vascular contractile state. This system emits bursts of sympathetic nerve activity (SNA) consisting of multiple neurons discharging at more-or-less the same time. This research program tests the working hypothesis that the discharge patterns of SNA variously impact vasomotor control through the differential release of multiple neurotransmitters. The major objectives are: 1) Quantify the coded patterns of neuronal action potentials present within integrated bursts of SNA, their reflex-specificity, and their species-specificity. Wavelet denoising methods and other Matlab-based algorithms will be used to expose and characterize individual action potentials in the multi-unit nerve recordings. 2) Establish the receptor-based mechanisms that differentially affect the mechanical properties of the vascular tree in skeletal muscle. Using a modified Windkessel model, the lumped parameters of resistance, compliance, viscoelasticity and inertia will be measured in the skeletal muscle of the human forearm and the rat hindlimb during reflexive manoeuvres along with their receptor-based mechanism of control. 3) Quantify the impact of physiologically relevant SNA discharge patterns on vasomotor mechanics and their post-junctional receptor-based mechanism of control, emphasizing baroreflex versus muscle chemoreflex activation. We will simulate patterns of SNA action potentials that replicate SNA bursts of varying sizes, groupings, and inter-burst spacing. These will be played back into the femoral nerve of an anesthetized rodent and the impact on receptor-based changes in vascular resistance and compliance will be measured. The experiments will provide novel and innovative approaches to examine the manner in which sympathetic neurons communicate with blood vessels to exert short-, and longer-term vascular control. These studies embrace integrative animal physiology and offer a unique opportunity for scientific discovery and for training of highly qualified personnel.

交感神经系统通过血管收缩状态的改变，是血压每时每刻变化的重要调节器。这个系统发出交感神经活动(SNA)的爆发，由多个神经元或多或少同时放电组成。这个研究项目测试了SNA的放电模式通过多种神经递质的不同释放而不同地影响血管运动控制的工作假说。主要目标是：1)量化SNA综合爆发中神经元动作电位的编码模式、它们的反射特异性和它们的物种特异性。小波去噪方法和其他基于MatLab的算法将被用来揭示和表征多单位神经记录中的个体动作电位。2)建立以受体为基础的机制，不同地影响骨骼肌血管树的力学特性。使用改进的Windkesel模型，将测量人类前臂和大鼠后肢骨骼肌在反射性动作中的阻力、顺应性、粘弹性和惯性的集中参数以及它们基于受体的控制机制。3)量化生理上相关的SNA放电模式对血管运动机制的影响及其基于连接后受体的控制机制，强调压力反射与肌肉化学反射的激活。我们将模拟复制不同大小、分组和突发间隔的SNA突发的SNA动作电位模式。这些将被回放到麻醉的啮齿类动物的股神经中，并将测量对血管阻力和顺应性的基于受体的变化的影响。这些实验将提供新的和创新的方法来检查交感神经元与血管沟通的方式，以实施短期和长期的血管控制。这些研究涵盖了综合动物生理学，并为科学发现和高素质人才的培训提供了独特的机会。