Abstract
BackgroundIschemia of intestinal organs is a main cause of complications in surgical intensive care patients. Changes in the tonus of arteries contributing to vascular resistance play an important role in the determination of blood flow and thus oxygen supply of various abdominal organs. It is generally acknowledged that hypoxia itself is able to alter arterial tonus and thus blood flow.MethodsThe present study compared the effects of various degrees of hypoxia on second-order mesenteric arteries from male C57BL/6J mice. After vessel isolation and preparation, we assessed vessel diameter using an arteriograph perfusion chamber. Investigating mechanisms promoting hypoxia-induced vasodilatation, we performed experiments in Ca2+-containing and Ca2+-free solutions, and furthermore, Ca2+-influx was inhibited by NiCl2, eNOS−/−-, and TASK1−/−-mice were investigated too.ResultsMild hypoxia 14.4% O2 induced, in 50% of mesenteric artery segments from wild-type (wt) mice, a vasodilatation; severe hypoxia recruited further segments responding with vasodilatation reaching 80% under anoxia. However, the extension of dilatation of luminal arterial diameter reduced from 1.96% ± 0.55 at 14.4% O2 to 0.68% ± 0.13 under anoxia. Arteries exposed to hypoxia in Ca2+-free solution responded to lower oxygen levels with increasing degree of vasodilatation (0.85% ± 0.19 at 14.4% O2 vs. 1.53% ± 0.42 at 2.7% O2). Inhibition of voltage-gated Ca2+-influx using NiCl2 completely diminished hypoxia-induced vasodilatation. Instead, all arterial segments investigated constricted. Furthermore, we did not observe altered hypoxia-induced vasomotion in eNOS−/−- or TASK1−/− mice compared to wt animals.ConclusionsThe present study demonstrated that hypoxic vasodilatation in mice mesenteric arteries is mediated by a NO-independent mechanism. In this experimental setting, we found evidence for Ca2+-mediated activation of ion channels causing hypoxic vasodilatation.
Highlights
Ischemia of intestinal organs is a main cause of complications in surgical intensive care patients
Direction of arterial vasomotion depends on oxygen concentration Sections of the second-order mesenteric arteries, which were kept under normoxia, responded in a dose-dependent manner to the application of Phe (10−8–10−3 M)
Phe achieved the maximum constriction at 10−3 M reducing the inner vessel diameter by 9.67%; the EC50 was determined at 1 0−6 M which was used in all subsequent experiments investigating the effects of low oxygen levels
Summary
Ischemia of intestinal organs is a main cause of complications in surgical intensive care patients. Changes in the tonus of arteries contributing to vascular resistance play an important role in the determination of blood flow and oxygen supply of various abdominal organs. Tissue hypoxia induced by mesenteric ischemia or hypoperfusion causes damage of the intestinal mucosa, consecutive translocation of pathogens, and the release of various inflammatory mediators [1]. This mechanism potentially results in the development of systemic. Changes in the tonus of arterial vessels determining vascular resistance play an important role in the regulation of blood flow and oxygen supply of the various organs.
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