Kurjiaka D T, Segal S S
John B. Pierce Laboratory, Yale University School of Medicine, New Haven, CT 06519, USA.
Circ Res. 1995 May;76(5):885-91. doi: 10.1161/01.res.76.5.885.
We tested the hypothesis that sympathetic nerve activity can influence the conduction of vasodilation along the arteriolar wall. Arterioles in the superfused cremaster muscle of anesthetized male hamsters (n = 21, 109 +/- 4 g) were studied. Microelectrodes were positioned adjacent to the distal end of primary arterioles to stimulate sympathetic nerves throughout arteriolar networks (perivascular nerve stimulation [PNS]). Microiontophoresis micropipettes (tip outer diameter, 1 to 2 microns) filled with acetylcholine (ACh, 1 mol/L) were positioned adjacent to the wall of second-order (2A) or third-order (3A) arterioles approximately 1 mm distal to their origin to induce local and conducted vasodilation; diameter responses were recorded at the micropipette tip and at vessel origins, respectively. For 2A and 3A arterioles (resting diameters, 15 to 54 and 9 to 30 microns, respectively), vasoconstriction with PNS was frequency dependent (0.5 to 32 Hz); this was attenuated by 65% (P < .05) with alpha-adrenoceptor blockade (phentolamine, 1 mumol/L). Conducted vasodilation was attenuated by > 40% during 16-Hz PNS (P < .05); this effect was reversed by phentolamine. In a reciprocal fashion, conducted vasodilation diminished PNS-induced vasoconstriction by approximately 50% (P < .05). Elevating oxygen (from 0% to 10%) in the superfusion solution induced vasoconstriction similar to that with 16-Hz PNS yet had no effect on conduction. Neural blockade with tetrodotoxin (1 mumol/L) eliminated PNS-induced vasoconstriction and enhanced (P < .05) conducted vasodilation. These findings indicate that perivascular nerves in striated muscle can influence cell-to-cell communication along the arteriolar wall both at rest and during enhanced sympathetic activity.(ABSTRACT TRUNCATED AT 250 WORDS)
我们验证了交感神经活动可影响血管舒张沿小动脉壁传导的假说。对麻醉的雄性仓鼠(n = 21,体重109±4克)灌注的提睾肌中的小动脉进行了研究。将微电极置于初级小动脉远端附近,以刺激整个小动脉网络的交感神经(血管周围神经刺激[PNS])。将充满乙酰胆碱(ACh,1mol/L)的微离子电泳微量移液器(尖端外径1至2微米)置于二级(2A)或三级(3A)小动脉壁附近,距其起始处约1毫米,以诱导局部和传导性血管舒张;分别在微量移液器尖端和血管起始处记录直径反应。对于2A和3A小动脉(静息直径分别为15至54微米和9至30微米),PNS引起的血管收缩具有频率依赖性(0.5至32Hz);α-肾上腺素能受体阻断(酚妥拉明,1μmol/L)使其减弱65%(P<0.05)。在16Hz的PNS期间,传导性血管舒张减弱>40%(P<0.05);酚妥拉明可逆转此效应。以相反的方式,传导性血管舒张使PNS诱导的血管收缩减少约50%(P<0.05)。在灌注液中提高氧气浓度(从0%至10%)可诱导与16Hz PNS相似的血管收缩,但对传导无影响。用河豚毒素(1μmol/L)进行神经阻断可消除PNS诱导的血管收缩,并增强(P<0.05)传导性血管舒张。这些发现表明,横纹肌中的血管周围神经在静息和交感神经活动增强时均可影响沿小动脉壁的细胞间通讯。(摘要截断于250字)
