Although several experiments have demonstrated the existence of a basal NO-dependent vasodilatory tone at the arteriolar level, the contribution of NO to the mechanical properties of large arteries has not been investigated in humans. To evaluate the effect of NO-synthase inhibition on these mechanical properties, radial artery internal diameter (d, mm) and wall thickness (h, mm) were measured continuously in 11 healthy volunteers (age: 24 +/- 1 years), using an A-mode echo-tracking system coupled to a Doppler device for the measurement of radial blood flow (RBF, ml/min). A catheter was inserted in the brachial artery for measurement of arterial pressure (AP, mmHg), and infusion of the inhibitor of NO synthesis NG-monomethyl L-arginine (L-NMMA: 4 mumol/min for 5 min, infusion rate 0.8 ml/min). Arterial compliance C, 10(-3) mm2/mmHg), distensibility (D, 10(-3)/mmHg), mid-wall stress (sigma, 10(5) dynes/mm2) and incremental modulus (Ei, 10(7) dynes/mm2) were calculated before and after L-NMMA. After L-NMMA, RBF decreased from 31 +/- 6 to 23 +/- 4 (p < 0.05), radial vascular resistance increased from 2.70 +/- 0.35 to 3.77 +/- 0.55 (p < 0.05), without changes in AP or heart rate. Table shows mechanical parameters, assessed at fixed AP (80 mmHg) (*: p < 0.05 vs baseline): [table: see text] Thus, the L-NMMA-induced decrease in radial arterial wall stiffness (Ei) without changes in arterial diameter or stress demonstrates that NO-synthase inhibition induces an isometric relaxation of vascular muscle cells, which explains the increase of arterial compliance at constant mid-wall stress. These results demonstrate that NO contributes to the regulation of peripheral muscular arterial mechanics in humans. At the level of large arteries, the isometric relaxation observed after NO-synthase inhibition is probably the consequence of compensatory vasodilator mechanisms.