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细胞外精氨酸通过一氧化氮机制迅速使体内肠动脉和小动脉扩张。

Extracellular arginine rapidly dilates in vivo intestinal arteries and arterioles through a nitric oxide mechanism.

作者信息

Pezzuto Laura, Bohlen H Glenn

机构信息

Department of Cellular and Integrative Physiology, Indiana University Medical School, Indianapolis, IN 46202, USA.

出版信息

Microcirculation. 2008 Feb;15(2):123-35. doi: 10.1080/10739680701447415.

DOI:10.1080/10739680701447415
PMID:18260003
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3042279/
Abstract

OBJECTIVE

Arginine used for nitric oxide formation can be from intracellular stores or transported into cells. The study evaluated the rapidity, and primary site of NO and vascular resistance responses to arginine at near physiological concentrations (100-400 microM).

METHODS

Arginine was applied to a single arteriole through a micropipette to determine the fastest possible responses. For vascular blood flow and [NO] responses, arginine was added to the bathing media.

RESULTS

Dilation of single arterioles to arginine began in 10-15 seconds and application over the entire vasculature increased [NO] in approximately 60-90 seconds, and flow increased within 120-300 seconds. Resting periarteriolar [NO] for arterioles was 493.6 +/- 30.5 nM and increased to 696.1 +/- 68.2 and 820.1 +/- 110.5 nM at 200 and 400 microM L-arginine. The blood flow increased 50% at 400-1200 microM L-arginine. The reduced arterial resistance during topical arginine was significantly greater than microvascular resistance at 100 and 200 microM arginine. All responses were blocked by L-NAME.

CONCLUSIONS

This study demonstrated arterial resistance responses are as or more responsive to arginine induced NO formation as arterioles at near physiological concentrations of arginine. The vascular NO and resistance responses occurred rapidly at L-arginine concentrations at and below 400 microM, which predict arginine transport processes were involved.

摘要

目的

用于一氧化氮生成的精氨酸可来自细胞内储存或转运进入细胞。本研究评估了在接近生理浓度(100 - 400微摩尔)时,一氧化氮和血管阻力对精氨酸反应的快速性及主要部位。

方法

通过微量移液器将精氨酸应用于单个小动脉,以确定最快可能的反应。对于血管血流和[一氧化氮]反应,将精氨酸添加到浴液中。

结果

单个小动脉对精氨酸的舒张在10 - 15秒内开始,在整个血管系统中应用后,[一氧化氮]在约60 - 90秒内增加,血流在120 - 300秒内增加。小动脉的静息动脉周围[一氧化氮]为493.6±30.5纳摩尔,在200和400微摩尔L - 精氨酸时分别增加到696.1±68.2和820.1±110.5纳摩尔。在400 - 1200微摩尔L - 精氨酸时,血流增加50%。局部应用精氨酸期间动脉阻力的降低在100和200微摩尔精氨酸时显著大于微血管阻力。所有反应均被L - 硝基精氨酸甲酯阻断。

结论

本研究表明,在接近生理浓度的精氨酸条件下,动脉阻力反应对精氨酸诱导的一氧化氮生成的反应与小动脉一样灵敏或更灵敏。在L - 精氨酸浓度为400微摩尔及以下时,血管一氧化氮和阻力反应迅速发生,这表明涉及精氨酸转运过程。

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