Puybasset L, Béa M L, Ghaleh B, Giudicelli J F, Berdeaux A
Département de Pharmacologie, Faculté de Médecine, Paris-Sud, France.
Circ Res. 1996 Aug;79(2):343-57. doi: 10.1161/01.res.79.2.343.
Sustained inhibition of NO synthesis (N omega-nitro-L-arginine [L-NNA], 20 mg.kg-1.d-1, 7 days) was investigated at rest and during exercise in conscious dogs. At rest, L-NNA did not alter mean arterial blood pressure but markedly increased total peripheral resistance (+73 +/- 14%, P < .01). Exaggerated hypertension was observed during exercise (+132 +/- 5 mm Hg after L-NNA versus +113 +/- 5 mm Hg before L-NNA, P < .01). L-NNA decreased the resting coronary artery diameter by 6 +/- 1% and suppressed its exercise-induced dilation but had no effect on coronary blood flow and resistance. L-NNA decreased flow repayment volumes during reactive hyperemia, but corresponding flow debt volumes remained unchanged. The cyclooxygenase inhibitor diclofenac (10 mg/kg) had no effect on reactive hyperemia parameters before L-NNA but reduced flow repayment volumes, durations, and corresponding debt-to-repayment ratios in L-NNA-treated dogs (all P < .05). In vitro, indomethacin blunted the residual relaxation to bradykinin of large coronary arteries taken from L-NNA-treated, but not from control, dogs. Bradykinin-induced increase in 6-ketoprostaglandin F1 alpha production was greater in coronary arteries taken from L-NNA-treated dogs (+ 179 +/- 41 pg/mm2) than from control dogs (+ 66 +/- 18 pg/mm2) (P < .05). These results indicate that (1) NO is of major importance in the control of systemic but not coronary resistance vessels at rest and during exercise, and (2) after L-NNA, the cyclooxygenase pathway is involved in myocardial reactive hyperemia and in the residual relaxation to bradykinin of isolated coronary arteries. Thus, in conscious dogs, the cyclooxygenase pathway might act as a protective mechanism of the coronary circulation when endothelial nitric oxide synthesis is altered.
在清醒犬静息和运动状态下,研究了持续抑制一氧化氮(NO)合成(Nω-硝基-L-精氨酸[L-NNA],20mg·kg-1·d-1,7天)的情况。静息时,L-NNA不改变平均动脉血压,但显著增加总外周阻力(+73±14%,P<.01)。运动期间观察到高血压加剧(L-NNA后为+132±5mmHg,而L-NNA前为+113±5mmHg,P<.01)。L-NNA使静息冠状动脉直径减小6±1%,并抑制其运动诱导的扩张,但对冠状动脉血流和阻力无影响。L-NNA减少了反应性充血期间的血流偿还量,但相应的血流亏欠量保持不变。环氧合酶抑制剂双氯芬酸(10mg/kg)在L-NNA之前对反应性充血参数无影响,但在L-NNA处理的犬中减少了血流偿还量、持续时间以及相应的亏欠偿还比(均P<.05)。在体外,吲哚美辛减弱了取自L-NNA处理犬而非对照犬的大冠状动脉对缓激肽的残余舒张作用。缓激肽诱导的6-酮前列腺素F1α产生增加在取自L-NNA处理犬的冠状动脉中(+179±41pg/mm2)比对照犬(+66±18pg/mm2)更大(P<.05)。这些结果表明:(1)在静息和运动时,NO在控制全身阻力血管而非冠状动脉阻力血管方面起主要作用;(2)L-NNA后,环氧合酶途径参与心肌反应性充血以及离体冠状动脉对缓激肽的残余舒张。因此,在清醒犬中,当内皮一氧化氮合成改变时,环氧合酶途径可能作为冠状动脉循环的一种保护机制。
