Examination of the roles of glycoprotein Ib and glycoprotein IIb/IIIa in platelet deposition on an artificial surface using clinical antiplatelet agents and monoclonal antibody blockade.

The mechanism of platelet thrombus growth on an artificial surface is incompletely understood. While glycoprotein (GP)Ib and GPIIb/IIIa are required for normal attachment and thrombus formation on subendothelium, their roles in platelet deposition to artificial surfaces remain unclear. Using selected platelet inhibitors (aspirin [ASA], low molecular weight dextran, monoclonal antibodies 10E5 [v GPIIb/IIIa], and 6D1 [GPIb]) we examined the mechanism of platelet deposition to polyethylene (PE) surfaces under steady laminar and oscillatory flow conditions. Polyethylene-100 (PE-100) tubes (0.86 mm internal diameter) were perfused under steady laminar flow with citrated human whole blood reconstituted with 111indium-labeled platelets at 312 seconds-1 shear rate in the presence and absence of platelet inhibitors. The effect of oscillatory flow on platelet deposition was examined in a microwell system using 3/16-inch diameter discs of National Heart, Lung, and Blood Institute primary reference PE as the test surface. ASA and dextran did not significantly (P greater than .05) inhibit platelet deposition in laminar flow (not tested in oscillatory). Antibody 10E5 was a potent inhibitor (laminar less than 1%, P less than .0001, oscillatory less than 1.6%, P less than .01) of platelet deposition in both systems, and in this case, true adhesion (first attached layer) was blocked. Antibody 6D1 unexpectedly inhibited 70% of platelet deposition (P less than .01) in steady laminar flow and 56.5% in oscillatory flow (P less than .01). Scanning electron microscopy demonstrated platelets atop platelets in the controls, rare platelets in the 10E5 group, and a patchy monolayer of platelets in the 6D1 group. Transmission electron microscopy of cross-sections confirmed these observations. We conclude that the adhesion of the first platelet layer to an artificial surface requires GPIIb/IIIa. The data also suggest that GPIb is required for the development of the second layer in vertical platelet thrombus growth.

Mechanisms of vein graft atherosclerosis: LDL metabolism and endothelial actin reorganization.

We have explored the effect of arterial hemodynamics on endothelial cell morphology and low-density lipoprotein metabolism in human saphenous vein segments harvested from tissue donors. An arterial pulsatile perfusion system was used to impose physiologic pressures and flows for 20 hours on saphenous vein and companion (control) femoral artery segments. A venous perfusion apparatus was also employed for the perfusion of a second (control) saphenous vein segment for the same period of time. Calculations of fluid shearing and wall tensile stresses were performed and related to induced changes in endothelial cell geometry and cytoskeletal actin organization and the incorporation, degradation, and localization of intact low-density lipoprotein within the vessel wall. Our results indicate that, compared with native arteries and veins, a 20-hour exposure of test saphenous veins to arterial hemodynamics induced (1) a significant increase in endothelial cell luminal surface area and perimeter independent of alignment with flow, (2) disassembly of the dense peripheral band of actin with a concomitant assembly of stress fibers, and (3) a two- to fourfold elevation in the undegraded low-density lipoprotein content, localized primarily within the subendothelial intima. Although the exact mechanisms underlying these results are uncertain, the focal accumulation of intramural low-density lipoprotein may be related to the loss of normal barrier function during endothelial cell enlargement, which is accompanied by transient cytoskeletal reorganization during the adaptation to arterial flow.

Experimental determination of mechanical shear stress about an anastomotic junction.

The present study is undertaken to determine whether the elastic tube model originally developed by Kuchar and Ostrach (Biomedical Fluid Mechanics Symposium, pp. 45-69, 1966) accurately provides a first approximation of the biomechanics of the anastomotic junction. The experimental protocol involves the use of canine carotid arteries as the host vessel and several graft materials including autogenous and prosthetic substitutes. The host artery-graft combinations are perfused in vitro in a pulsatile perfusion apparatus which simulates the natural hemodynamic environment. This apparatus provides accurate dynamic measurements of radial wall motion (measured at various longitudinal increments), associated pressures and rates of fluid flow. These data are then applied to the theoretical model for calculation of anastomotic induced bending stresses. The results indicate that the predictions derived from the elastic model consistently overestimate the measured radial change adjacent to the anastomotic junction. As a result shear stresses based on elastic theory deviate from values derived from a numerical curve fit to the experimental data.