Huang A, Sun D, Kaley G, Koller A
Department of Physiology, New York Medical College, Valhalla, NY 10595, USA.
Circ Res. 1998 Nov 2;83(9):960-5. doi: 10.1161/01.res.83.9.960.
It is thought that elevated levels of reactive oxygen metabolites contribute to the dysfunction of vascular endothelium in hypertension. We hypothesized that high intravascular pressure itself elicits production of superoxide, which then interferes with nitric oxide (NO)-mediated responses of arterioles. Thus, isolated arterioles (approximately 80 microm in diameter) from gracilis muscle of normotensive Wistar rats were cannulated and exposed to 140 mm Hg perfusion pressure for 30 minutes (in the absence of perfusate flow). After high intravascular pressure treatment, dilations to increases in perfusate flow (0 to 30 microL/min) were significantly reduced (from 39+/-2.2 to 19+/-2.1 microm at 30 microL/min), eliciting an increase in wall shear stress from approximately 20 to approximately 60 dyne/cm2. Nomega-nitro-L-arginine (10(-4) mol/L) did not affect, whereas indomethacin eliminated, flow-induced dilations after pressure treatment. In control, substance P (SP, 10(-9) to 5x10(-8) mol/L), sodium nitroprusside (SNP, 10(-8) to 10(-6) mol/L), and adenosine (ADO, 10(-6) to 5x10(-5) mol/L) elicited dilations (SP: 31.5+/-1.9 microm, SNP: 45.6+/-4 microm, and ADO: 37.2+/-4.1 microm, at maximum concentrations, respectively). After pressure treatment, maximum dilations to SP and SNP were significantly reduced (by 49% and 39%, respectively), whereas responses to ADO were not affected. Presence of superoxide dismutase (120 U/mL) and catalase (80 U/mL), but not catalase alone, in the perfusate solution prevented the reduction in dilation of arterioles to flow and agonists after pressure treatment by restoring NO mediation. We conclude that high intravascular pressure per se elicits the release of superoxide, which then interferes with NO, a mechanism that contributes to the elevation of wall shear stress and peripheral resistance in hypertension.
人们认为,活性氧代谢产物水平升高会导致高血压患者血管内皮功能障碍。我们推测,高血管内压本身会引发超氧化物的产生,进而干扰小动脉中一氧化氮(NO)介导的反应。因此,将来自正常血压Wistar大鼠股薄肌的分离小动脉(直径约80微米)插管,并在无灌注液流动的情况下暴露于140 mmHg的灌注压力30分钟。在高血管内压处理后,随着灌注液流量增加(0至30微升/分钟)的扩张明显减少(在30微升/分钟时从39±2.2微米降至19±2.1微米),导致壁切应力从约20达因/平方厘米增加至约60达因/平方厘米。Nω-硝基-L-精氨酸(10⁻⁴摩尔/升)不影响压力处理后流量诱导的扩张,而吲哚美辛可消除这种扩张。在对照中,P物质(SP,10⁻⁹至5×10⁻⁸摩尔/升)、硝普钠(SNP,10⁻⁸至10⁻⁶摩尔/升)和腺苷(ADO,10⁻⁶至5×10⁻⁵摩尔/升)均可引起扩张(最大浓度时,SP为31.5±1.9微米,SNP为45.6±4微米,ADO为37.2±4.1微米)。压力处理后,对SP和SNP的最大扩张明显减少(分别减少49%和39%),而对ADO的反应不受影响。灌注液中存在超氧化物歧化酶(120单位/毫升)和过氧化氢酶(80单位/毫升),但单独的过氧化氢酶则不能通过恢复NO介导来防止压力处理后小动脉对流量和激动剂的扩张减少。我们得出结论,高血管内压本身会引发超氧化物的释放,进而干扰NO,这一机制导致高血压患者壁切应力和外周阻力升高。
