These results demonstrate that NO is a potent inhibitor of platelet adhesion under flow conditions and thereby contributes to the regulatory role of vascular endothelial cells on platelet-vessel wall interaction.
In a prospective double-blind trial, we treated 194 patients with acute venous thromboembolism with heparin or low molecular weight heparin (LMWH; Fragmin). To evaluate the most important prognostic factors for bleeding, the presenting clinical features of the patients, the patients' anticoagulant responses, and the doses of the drugs were analyzed using univariate and multivariate regression analyses. No significant differences in clinical risk factors associated with bleeding were observed between heparin and LMWH. The univariate analyses ranked the parameters in the following order of importance: World Health Organization (WHO) performance status, history of bleeding tendency, cardiopulmonary resuscitation, recent trauma or surgery, leukocyte counts, platelet counts, duration of symptoms, and body surface area. Patients with WHO grade 4 had an eightfold increase in risk of bleeding as compared with WHO grade 1. Assessment of the individual contribution of each variable using multivariate regression analysis showed that the WHO performance status was the most important independent factor predicting major bleeding. A history of a bleeding tendency, recent trauma or surgery, and body surface area were also independent risk factors. The risk of bleeding was influenced by two factors related to the treatment, the patient's anticoagulant response as measured with the anti-Xa assay and the dose of the drug expressed as U/24 h/m2. An increased risk of bleeding was only observed at mean anti-Xa levels greater than 0.8 U/mL for both drugs. Significantly more major bleedings occurred in patients treated with high doses of the drugs, an observation that was independent of the concomitant anti-Xa levels. It should be considered whether choosing an appropriate initial dose adapted to the patient's body surface area and clinical risk factors can improve the efficacy to safety ratio of heparin treatment.
Platelet adhesion to fibrillar collagens (types I, II, III, and V) and nonfibrillar collagens (types IV, VI, VII, and VIII) was investigated in the presence of physiologic concentrations of divalent cations under conditions of stasis and flow. Under static conditions, platelet adhesion was observed to collagen types I through VII but not to type VIII. Under flow conditions, platelet adhesion to collagen types I, II, III, and IV was almost independent of shear rates above 300/s. Collagen type V was nonadhesive. Platelet adhesion to collagen type VI was shear rate-dependent and optimal at a rate of 300/s. Collagen types VII and VIII showed minor reactivity and supported platelet adhesion only between shear rates 100 to 1,000/s. Monoclonal antibody (MoAb) 176D7, directed against platelet membrane glycoprotein Ia (GPIa; very late antigen [VLA]-alpha 2 subunit), completely inhibited platelet adhesion to all collagens tested, under conditions of both stasis and flow. Platelet adhesion to collagen type III at shear rate 1,600/s was only inhibited for 85%. The concentration of antibody required for complete inhibition of platelet adhesion was dependent on the shear rate and the reactivity of the collagen. An MoAb directed against GPIIa (VLA-beta subunit) partially inhibited platelet adhesion to collagen. These results show that GPIa-IIa is a major and universal platelet receptor for eight unique types of collagen.
To define the role of activated platelets we have attempted to prepare monoclonal antibodies specific for activated platelets. The IgG2b antibody of one of the clones, designated 2.28, was studied in more detail. Native platelets from normal individuals bound 650 125I-2.28 molecules/platelet, whereas thrombin-activated platelets bound 12,600 molecules/platelet with high affinity (4.6 nmol/L). Immunoelectrophoretic analysis revealed that 2.28 reacted with a 53,000- mol wt protein. Immunocytochemistry showed that the antigen is located in a special subclass of platelet granules in unstimulated platelets and is exposed on the surface of thrombin-activated platelets. Double- labeling studies with immunogold labels disclosed simultaneous localization of 2.28 binding sites and cathepsin D in the same granules both in megakaryocytes and endothelial cells, thereby indicating that the antigen may be localized in lysosomes. By using flow cytofluorometry, in vivo platelet activation was studied in patients undergoing cardiac surgery with cardiopulmonary bypass. Increased numbers of platelets that expressed the 2.28 antigen on their surface were observed after extracorporeal perfusion. The percentage of 2.28- positive platelets in the circulation was 3.9% +/- 2.7% (SD) in controls (n = 20), 5.5% +/- 3.0% in patients (n = 10) before cardiopulmonary bypass surgery, 24.6% +/- 13.5% after the bypass, and 8.5% in two patients with acute deep venous thrombosis. These data indicate that 2.28 may serve as a useful probe of in vitro and in vivo platelet activation.
To study the interaction between factor VIII and von Willebrand factor (vWF), binding experiments were performed using immobilized plasma vWF. Plasma was obtained from healthy donors and from patients with severe hemophilia A. For normal and hemophilic vWF, the dissociation constants (kd) for binding of factor VIII to vWF were 0.21 +/- 0.04 and 0.22 +/- 0.05 nmol/L, respectively. At saturation, the stoichiometry was one factor VIII molecule per 50 vWF monomers. In gel-filtration experiments, vWF was saturated by 23 times more factor VIII. However, when this FVIII-vWF complex was immobilized on microtiter plates, the ratio of factor VIII/vWF decreased to the same ratio as in the solid-phase binding assay. To exclude any effect of antibody binding, colloidal gold particles with a diameter of 15 nm were coupled to purified vWF. This vWF-gold complex remained immunoreactive toward polyclonal and monoclonal antibodies, and was able to bind factor VIII, specifically, saturably, and reversibly. After incubation of vWF-gold with factor VIII, unbound and bound factor VIII were separated by centrifugation. Binding isotherms of these fluid-phase binding experiments indicated a kd of 0.32 +/- 0.09 nmol/L and a stoichiometry of approximately 0.5 factor VIII molecule per vWF monomer. We conclude that vWF-binding to a surface, with or without an antibody, may induce a conformational change causing a dissociation of bound factor VIII from vWF.
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