Vascular smooth muscle, a multiply feedback-coupled system of high versatility, modulation and cell-signaling variability.

G Siegel, M Malmsten, D Klüssendorf, H W Hofer
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引用次数: 11

Abstract

Under normal conditions, the various vascular regulatory effector influences are interwoven in a dynamic, and not a static, circulatory system. The reaction of a smooth muscle cell is thus reflected only incompletely by the stationary activation curve 'developed tension versus membrane potential'. The missing time domain in this relationship is a reflection of our as yet limited understanding of the system's behavior in space and time. It should be emphasized that the rhythmogenic properties of vascular smooth muscle are closely coupled to a functioning circulation. The electrical and mechanical oscillations, which can be traced back to rhythmic activity of the active, electrogenic Na+/K+ pump, could originate in the allosteric qualities of the enzyme phosphofructokinase (PFK). Thus, PFK represents a rhythmogenic enzyme which may serve as an example of the connection between the biological properties on a molecular level and the spatiotemporal system's behavior. The cardiovascular system and its rhythmicity may be dominated by only a few control points, one of which is distinguished by the viscoelastic properties of a blood flow sensor macromolecule. Therefore, the three prominent control points - PFK, (Na+ + K+)-ATPase and flow sensor conformation - acting as negatively feedback-coupled, nonlinear synergetic order parameters, are sufficient to initiate the periodic events in the cardiovascular system and to provide a plausible explanation for their causal origin.

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血管平滑肌,多重反馈耦合系统的高通用性,调制和细胞信号变异性。
在正常情况下,各种血管调节效应相互交织在一个动态的循环系统中,而不是一个静态的循环系统。因此,平滑肌细胞的反应仅不完全反映在静止的激活曲线“发达的张力与膜电位”上。这种关系中缺失的时域反映了我们迄今为止对系统在空间和时间上的行为的有限理解。应该强调的是,血管平滑肌的节律性与循环功能密切相关。电振荡和机械振荡可以追溯到活性的电致Na+/K+泵的节律性活动,可能源于磷酸果糖激酶(PFK)酶的变构特性。因此,PFK代表了一种节律性酶,可以作为分子水平上的生物学特性与时空系统行为之间联系的一个例子。心血管系统及其节律性可能仅由几个控制点控制,其中一个控制点由血流传感器大分子的粘弹性特性来区分。因此,三个突出的控制点- PFK, (Na+ + K+)- atp酶和流量传感器构象-作为负反馈耦合的非线性协同序参量,足以启动心血管系统中的周期性事件,并为其因果起源提供了合理的解释。
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Measurement of blood perfusion in the dental pulp with laser Doppler flowmetry. Vascular smooth muscle, a multiply feedback-coupled system of high versatility, modulation and cell-signaling variability. Long-term registration of cutaneous microcirculation during general anesthesia. Synergetic interpretation of patterned vasomotor activity in microvascular perfusion: discrete effects of myogenic and neurogenic vasoconstriction as well as arterial and venous pressure fluctuations. Cardiovascular monitoring of elective aortic aneurysm repair using methods of chaos analysis.
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