血管紧张素 II-盐性高血压的神经机制:对靶向内脏循环神经控制的治疗方法的影响。
Neural mechanisms of angiotensin II-salt hypertension: implications for therapies targeting neural control of the splanchnic circulation.
机构信息
Department of Integrative Biology and Physiology, University of Minnesota, 6-125 Jackson Hall, Minneapolis, MN 55455, USA.
出版信息
Curr Hypertens Rep. 2011 Jun;13(3):221-8. doi: 10.1007/s11906-011-0188-9.
Abstract
Chronically elevated plasma angiotensin II (AngII) causes a salt-sensitive form of hypertension that is associated with a differential pattern of peripheral sympathetic outflow. This "AngII-salt sympathetic signature" is characterized by a transient reduction in sympathetic nervous system activity (SNA) to the kidneys, no change in SNA to skeletal muscle, and a delayed activation of SNA to the splanchnic circulation. Studies suggest that the augmented sympathetic influence on the splanchnic vascular bed increases vascular resistance and decreases vascular capacitance, leading to hypertension via translocation of blood volume from the venous to the arterial circulation. This unique sympathetic signature is hypothesized to be generated by a balance of central excitatory inputs and differential baroreceptor inhibitory inputs to sympathetic premotor neurons in the rostral ventrolateral medulla. The relevance of these findings to human hypertension and the future development of targeted sympatholytic therapies are discussed.
摘要
慢性升高的血浆血管紧张素 II(AngII)会导致一种盐敏感型高血压,这种高血压与外周交感神经输出的差异模式有关。这种“AngII-盐-交感神经特征”的特点是肾脏交感神经活动(SNA)短暂减少,骨骼肌 SNA 无变化,以及内脏循环的 SNA 延迟激活。研究表明,交感神经对内脏血管床的增强影响会增加血管阻力并降低血管容量,从而通过将血量从静脉转移到动脉循环来导致高血压。这种独特的交感神经特征被假设是通过延髓头侧腹外侧区交感节前神经元的中枢兴奋性输入和差异压力感受器抑制性输入的平衡产生的。讨论了这些发现对人类高血压和靶向交感神经溶解治疗的未来发展的相关性。
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