In the present study, we investigated whether high arterial shear stresses at various exposure times or a sudden increase in shear stress introduced by a stenosis affect platelet activation and platelet microparticle formation in native human blood. We used a parallel-plate perfusion chamber device through which nonanticoagulated human blood was drawn (10 mL/min) by a pump directly from an antecubital vein through the flow channel of a perfusion chamber at wall shear rates of 420, 2600, and 10500 s-1. In another set of experiments, an eccentric stenosis was introduced into the flow channel. Wall shear rates of 2600 or 10500 s-1 at the stenosis apex were maintained at the same flow rate. The wall shear rate upstream and downstream of these stenoses was 420 s-1. A shear rate of 420 s-1 is within the range of those encountered in healthy small coronary arteries, whereas those of 2600 and 10500 s-1 are representative for vessels with various degrees of stenotic lesions. The blood was exposed to these shear rates for periods varying from 0.075 to 3.045 seconds. Platelet activation was assessed as activated glycoprotein (GP) IIb/IIIa by FITC-labeled monoclonal antibody (MAb) PAC-1 and aminophospholipid translocation by FITC-labeled annexin V. Microparticle formation was quantified by FITC-labeled MAb Y2/51 directed against GP IIIa. Significant platelet activation and formation of microparticles were observed at 10500 s-1 only (P < .008). This shear-induced platelet activation and microparticle formation were enhanced by introduction of a thrombus-promoting surface consisting of type III human collagen fibrils. Introduction of the most severe stenosis at 10500 s-1 further increased platelet activation (P < .017). The collagen-induced thrombus formation increased the platelet thrombus volume at 10500 s-1 from 16.5 to 33.8 microns3/microns2 (P < .003) on the stenosis apex when the most severe stenosis was used. A correlation (P < .0001) between platelet thrombus volume and platelet microparticle formation was observed in the presence of the eccentric stenoses. Apparently, high shear stress (315 dynes/cm2 at 10500 s-1), as encountered in severe atherosclerotic arteries, activated platelets and triggered platelet microparticle formation. In contrast, no significant platelet activation or formation of platelet microparticles was observed at physiological shear (420 s-1) or at the shear condition simulating shear in arteries with a less severe stenosis (2600 s-1). The data imply that platelets are activated and form microparticles in native blood at very high shear stresses. These events are potentiated by prolonged exposure to the high shear or by a sudden change of increasing shear due to the stenosis. The latter situation apparently enhances platelet thrombus formation at the stenosis.
Induction of monocyte tissue factor procoagulant activity during coronary artery bypass surgery is reduced with heparin‐coated extracorporeal circuit
The possible activation of monocytes to express tissue factor procoagulant activity (TF-PCA) during CPB (cardiopulmonary bypass) was investigated. 22 patients undergoing myocardial revascularization were randomly assigned to two groups. In group C, heparin-coated circuits (Duraflo II) and reduced systemic heparinization (ACT > 250s) were used. In group NC, non-coated circuits and standard heparin administration (ACT > 480s) were used. Adherent monocytes retrieved from the oxygenators immediately after bypass arrest showed a 2-3-fold increase in TF-PCA when compared to circulating cells pre-CPB (P < 0.01). When cell PCA was expressed as percent change from pre-CPB (baseline) values, circulating monocytes in group NC at CPB-arrest showed a 2-fold increase in PCA compared to group C (P < 0.05). Moreover, the percent increase in PCA of oxygenator-retrieved monocytes was 7-fold in group NC and 2-fold in group C (P < 0.008 and P < 0.004, respectively). Thus, heparin-coating of the extracorporeal circuit reduced induction of adherent cell TF-PCA by 70% (P < 0.05). Thus, monocyte TF-PCA may cause activation of the extrinsic coagulation pathway during CPB surgery. It is apparent that heparin-coating enhanced biocompatibility of extracorporeal circuits. Reduced systemic heparinization in group C proved to be safe. However, further reduction of heparin administration may not be advisable, since monocytes were still activated in the coated oxygenator.
Tissue factor (TF) on monocyte and macrophage surfaces is a nonproteolytic cofactor for factor VIIa (FVIIa)-induced coagulation. Monocyte-derived macrophages in atherosclerotic plaques express TF, which, after plaque disruption or rupture, may complex with FVII/VIIa from the bloodstream, resulting in activation of extrinsic coagulation. We studied the effect of TF expression on human monocytes on arterial thrombus formation in a model system of thrombogenesis. Thawed, cryopreserved human monocytes adherent to plastic coverslips were stimulated with lipopolysaccharide (0.5 microgram/mL) to express TF and subsequently exposed to flowing nonanticoagulated human blood in a parallel-plate perfusion chamber. The wall shear rate at the cell surface was 650 seconds-1, corresponding to that of average-sized coronary arteries. The stimulated monocytes elicited pronounced fibrin deposition and platelet-thrombus formation. The platelet-thrombus volume was as large as that triggered by human type III collagen fibrils under similar experimental conditions. In contrast, the monocytes elicited much more fibrin deposition than the collagen surface. However, inclusion of an anti-TF monoclonal antibody that blocks the complexation of FVII/FVIIa with TF virtually abolished the fibrin deposition (P < .03) and reduced platelet-thrombus formation by more than 70% (P < .04). Thus, arterial thrombus formation induced by stimulated monocytes was almost completely blocked by the anti-TF antibody, suggesting that inhibition of TF/FVIIa complex formation on monocytes and macrophages at sites of plaque rupture or after percutaneous transluminal coronary angioplasty procedures may reduce intravascular thrombotic complications.
Agents that downregulate the induction of monocyte/macrophage tissue factor (TF) activity may attenuate the thrombotic risk associated with mechanical restoration of vessel patency or artificial arterial grafting. In such events, procoagulant macrophages in the atherosclerotic plaque and procoagulant monocytes adherent to artificial materials may be exposed to the blood stream. Ishii et al (Blood 80:2556, 1992) reported that induction of endothelial TF is downregulated by all-trans retinoic acid (ATRA), and Conese et al (Thromb Haemost 66:662, 1991) reported that retinoids downregulate monocyte procoagulant activity (PCA). These findings led us to investigate the effect of ATRA on monocyte TF expression, and to study the effect of ATRA on monocyte-induced thrombus formation in a model system of human arterial thrombogenesis. Induction of PCA in human peripheral blood monocytes by 0.5 microgram/mL lipopolysaccharide (LPS) was dose dependently reduced by ATRA, reaching a reduction of 56% at 10(-5) mol/L ATRA (P < .0001). A 38% reduction (P < .0007) in LPS- induced TF antigen expression was observed at an ATRA concentration of 10(-6) mol/L. Adherence of monocytes to plastic cover slips (Thermanox, Miles Laboratories, Naperville, IL) also triggered induction of cellular PCA, which was inhibited by more than 80% by an anti-TF monoclonal antibody (MoAb) (P < .002). Inclusion of ATRA (10(-6) mol/L) reduced this PCA by 40% (P < .03), and the TF antigen expression by 30% (P < .0001). Exposure of Thermanox adherent monocytes to flowing nonanticoagulated human blood in a parallel-plate perfusion chamber device at an arterial wall shear rate of 650 s-1 elicited significant fibrin deposition and platelet thrombus formation. Partial interruption of this thrombus formation was achieved by 10(-6) mol/L ATRA, which reduced the fibrin deposition by 80% (P < .02) and platelet thrombus formation by 50% (P < .05). In comparison, incubation of adherent monocytes with the anti-TF MoAb before the blood exposure, reduced the fibrin deposition by 83% (P < .02) and platelet thrombus volume by 75% (P < .0008). Thus, ATRA is an effective down-regulator of monocyte TF- PCA, and may reduce thrombotic complications at sites of plaque rupture, at plaque disruption after percutaneous transluminal angioplasty procedures, or on surfaces introduced by artificial arterial grafting.
Iodixanol appears to be most biocompatible with endothelium, and has a moderate inhibitory effect on fibrin deposition in flowing blood. This differs from iohexol, and in particular from ioxaglate, which induce endothelial changes in morphology with no effect on fibrin deposition. Since none of the CM affected the platelet aggregate formation, and since ioxaglate has been reported to have stronger anticoagulant and antithrombotic properties than iodixanol or iohexol in in vitro assays, it is apparent that these properties were not reflected in thrombus formation under the experimental conditions of high arterial shear.
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