The effect of combined arterial hemodynamics on saphenous venous endothelial nitric oxide production.

INTRODUCTION: Evidence exists that an ideal bypass conduit should have a functional endothelial cell surface combined with mechanical properties similar to those of native arteries. We hypothesized that the effect of combined arterial levels of pulsatile shear stress, flow, and cyclic strain would enhance saphenous venous endothelial cell nitric oxide (NO) production, and that variations in these "ideal" conditions could impair this function. We studied NO production as a measure of endothelial function in response to different hemodynamic conditions. METHODS: Human adult saphenous venous endothelial cells were cultured in 10-cm silicone tubes, similar in diameter (5 mm) and compliance (6%) to a medium-caliber peripheral artery (eg, popliteal). Tube cultures were exposed to arterial conditions: a combined pressure (120/80 mm/Hg; mean, 100 mm/Hg), flow (mean, 115 mL/min) and cyclic strain (2%), with a resultant pulsatile shear stress of 4.8 to 9.4 dyne/cm2 (mean, 7.1). Identical tube cultures were used to study variations in these conditions. Modifications of the system included a noncompliant system, a model with nonpulsatile flow, and a final group exposed to pulsatile pressure with no flow. NO levels were measured with a fluorometric nitrite assay of conditioned media collected at 0, 0.25, 0.5, 1, 2, and 4 hours. Experimental groups were compared with cells exposed to nonpulsatile, nonpressurized low flow (shear stress 0.1 dyne/cm2) and static cultures. RESULTS: All experimental groups had greater rates of NO production than cells under static conditions (P <.05). Cells exposed to ideal conditions produced the greatest levels of NO. Independent decreases in compliance, flow, and pulsatility resulted in significantly lower rates of NO production than those in the group with these conditions intact (vs noncompliant P <.05, vs nonflow P <.05, and vs nonpulsatile P <.05). CONCLUSIONS: Our results show that in the absence of physiologically normal pulsatility, cyclic strain, and volume flow, endothelial NO production does not reach the levels seen under ideal conditions. Pulsatile flow and compliance (producing flow with cyclic stretch) play a key role in NO production by vascular endothelium in a three-dimensional hemodynamically active model. This correlates biologically with clinical experience linking graft inflow and runoff and the mechanical properties of the conduit to long-term patency.

The response of adult human saphenous vein endothelial cells to combined pressurized pulsatile flow and cyclic strain, in vitro.

Adult human saphenous vein endothelial cells (HVEC) were cultured in a compliant tubular device and evaluated by Northern hybridization for the effects of combined pressurized pulsatile flow and cyclic strain on the expression of mRNAs for endothelin-1 (ET-1), endothelial cell nitric oxide synthase (ecNOS), tissue plasminogen activator (tPA), and plasminogen activator inhibitor type 1 (PAI-1). The hemodynamic environment was designed to mimic shear stress conditions at the distal anastomosis of a saphenous vein graft, a common site of intimal proliferation. Steady-state mRNA levels in experimental tubes were expressed relative to that in controls. No changes were observed in ET-1 mRNA after 1 and 24 hr, but a 50% decrease in experimental cultures was observed after 48 hr in the vascular simulating device. Similar results were obtained for ecNOS mRNA, although a subgroup (4 of 11) showed a significant decrease (>50%) by 24 hr. For tPA mRNA, no change was observed after 1 hr, but a significant decrease (>60%) was measured after 24 hr and no message was detectable after 48 hr. Steady-state levels for PAI-1 mRNA remained unchanged through 48 hr of treatment. These results show that pressure, pulsatile flow, and cyclic strain, when applied in concert, differentially alter vasoactive and fibrinolytic functions in HVEC. Moreover, the dramatic decrease in steady-state levels of tPA mRNA is consistent with a shift toward an increased thrombotic state.