Role of collagen-adherent platelets in mediating fibrin formation in flowing whole blood

Activated platelets provide assembly sites for coagulation enzyme complexes and in this way can mediate coagulation during hemostasis and thrombosis. In this study, we examined the procoagulant activity of platelets adhering directly to fibrillar collagen, a main thrombogenic constituent of subendothelium. For this purpose, we used a human ex- vivo thrombosis model in which collagen-coated coverslips were exposed to flowing nonanticoagulated blood (shear rate, 65/s) for 5.5 minutes, which led to the deposition of adherent platelets, platelet thrombi, and fibrin. To examine the procoagulant activity of adherent platelets only, a selective antagonist of the platelet GPIIb-IIIa complex, Ro 44- 9883, was infused via a mixing device, resulting in a complete abrogation of platelet thrombus formation but leaving the collagen- adherent platelet layer intact. This platelet layer generated increased postchamber fibrinopeptide A (FPA) levels (203 +/- 33 ng/mL) as compared with control experiments without infusion of inhibitor (95 +/- 13 ng/mL). Concomitantly, fibrin deposition measured by morphometric analysis of cross-sections was also increased, as was the platelet adhesion to collagen. An immunochemical staining of fibrin fibers further showed that the adherent platelets formed the nuclei for fibrin fiber formation. This increase in fibrin deposition was mediated by the intrinsic factor X (F.X) activation complex on adherent single platelets, because almost complete inhibition of FPA generation (9 ng/mL) and fibrin deposition (0.4% +/- 0.2% coverage) was achieved upon coinfusion of the GP IIb-IIIa antagonist and active site-inhibited F.IXa. The large platelet thrombi that were deposited in control experiments contained no significant amounts of immunodetectable fibrin except at the thrombus base, where adherent platelets anchored the thrombi to the collagen surface. These results suggest that the collagen-adherent platelets are important promoters of coagulation during the initial phase of thrombogenesis by providing assembly sites for the F.X activation complex.     

Recombinant factor VIIa enhances deposition of platelets with congenital or acquired alpha IIb beta 3 deficiency to endothelial cell matrix and collagen under conditions of flow via tissue factor-independent thrombin generation

A novel approach to treat bleeding episodes in patients with Glanzmann thrombasthenia (GT) and perhaps also in patients receiving alpha IIb beta 3 inhibitors is the administration of recombinant factor VIIa (rFVIIa). The mechanism of action of rFVIIa in these patients is, however, still unclear. We studied the effect of rFVIIa-mediated thrombin formation on adhesion of alpha IIb beta 3-deficient platelets under flow conditions. Adhesion of alpha IIb beta 3-deficient platelets to the extracellular matrix (ECM) of stimulated human umbilical vein endothelial cells or to collagen type III was studied using a model system with washed platelets and red cells. When alpha IIb beta 3-deficient platelets were perfused over the surface at arterial shear rate for 5 minutes, a low surface coverage was observed (GT platelets, mean +/- SEM, 37.5% +/- 5.0%; normal platelets preincubated with an RGD-containing peptide, 7.4% +/- 2.1%). When rFVIIa, together with factors X and II, was added to the perfusate, platelet deposition significantly increased (GT platelets, mean +/- SEM, 67.0% +/- 4.3%; normal platelets preincubated with an RGD-containing peptide, 48.2% +/- 2.9%). The same effect was observed when normal platelets were pretreated with the commercially available anti-alpha IIb beta 3 drugs abciximab, eptifibatide, or tirofiban. It was shown that tissue factor-independent thrombin generation (presumably induced by binding of rFVIIa to adhered platelets) was responsible for the increase in platelet deposition. In conclusion, defective adhesion of alpha IIb beta 3-deficient platelets to ECM can be restored by tissue factor-independent rFVIIa-mediated thrombin formation. The enhanced generation of platelet procoagulant surface facilitates fibrin formation, so that lack of platelet aggregate formation might be compensated for.     

Enhanced thrombin generation and platelet binding on herpes simplex virus-infected endothelium.

Atherosclerotic lesions have been reported to contain herpes simplex virus 1 (HSV-1) genomic material. This, and other previous evidence, suggests that latent viral infection may be an atherogenic trigger. Moreover, active HSV-1 lesions manifest marked fibrin deposition in microvessels. In this report we show that very early infection of human endothelial cells with HSV-1 appears to alter surface conformation as detected by merocyanine 540 staining. Concomitantly, the efficiency of prothrombinase complex assembly increases, resulting in a 2- to 3-fold accelerated rate of thrombin generation on the cell surface. Increased thrombin generation is probably doubly procoagulant, since we also demonstrate that thrombin-induced platelet accumulation on HSV-infected endothelium (50.7 +/- 9.3%) is increased compared to uninfected endothelium (9.5 +/- 2.1%; P less than 0.002). Associated with HSV infection, prostacyclin secretion in response to thrombin is diminished by a factor of 20, probably explaining the enhanced platelet attachment. We conclude that HSV infection shifts endothelial cell properties from anticoagulant to procoagulant, both by promoting prothrombinase complex formation and function and by increasing platelet binding, well before cell disruption takes place. Virus-induced changes in the endothelial plasma membrane and diminished prostacyclin secretion are suggested as the pathways for this pathophysiologic mechanism, which may be germane to atherosclerotic thrombosis as well as HSV-mediated tissue necrosis.     

Normal haemostasis and its regulation

Regulation of normal haemostasis and blood flow involves complex interactions between plasma proteins and blood cells, including platelets, leukocytes and the endothelial lining of blood vessels. Thrombin acts as a pivot in the maintenance of the haemostatic balance; the vascular endothelial cell in particular limits the generation of thrombin by localisation of anticoagulant processes on its luminal membrane. The endothelial cell synthesises key molecules in this process and also binds exogenously derived molecules, as well as releasing proteins of the fibrinolysis cascade. The thromboresistance of the luminal surface is further regulated by lipoxygenase and cyclo-oxygenase metabolites of unsaturated fatty acids synthesised by the endothelial cell. In response to trauma, inflammatory reactions, normal wound healing and in association with a variety of disease states, the anticoagulant and fibrinolytic mechanisms are downregulated and the procoagulant and thrombotic mechanisms predominate with resultant generation of thrombin, fibrin clot formation and subsequent platelet adhesion and aggregation. Pro-inflammatory and prothrombotic cytokines downregulate the fibrinolytic and activated protein C pathways as well as inducing synthesis of specific procoagulant and prothrombotic mediators by platelets and leukocytes as well as endothelium.     

Effect of spontaneous pathology and thrombin on leukocyte adhesion to rat aortic endothelium.

Leukocyte adhesion and other injury parameters have been studied in the aortic endothelium of Sprague-Dawley rats in two situations: (1) spontaneous pathology in conventional rats with antibodies to Mycoplasma pulmonis and/or Kilham or Sendai viruses, and (2) intravascular coagulation by thrombin administration in SPF rats. Adhesion (esterase (+) leukocytes/mm2) in SPF rats was 8 +/- 5 (n = 12). Adhesion in 38% of the conventional rats was 54 +/- 27 (n = 8), half of them being non-analyzed and the rest having antibodies to M. pulmonis and/or Kilham rat virus. In 19 rats with antibodies to M. pulmonis and/or Kilham or Sendai viruses, AgNO3 and hematoxylin staining of the aortic endothelium showed an increase in leukocyte adhesion, and the presence of argyrophilic cells, stigmata and granularity--severe endothelial lesions being observed in some cases. Adhesion in rats after 0.25, 1, 3 and 6 h of thrombin administration (30 units/100 g) was not different from controls. Adhesion after 24 h was 108 +/- 53 (n = 10) and 60 +/- 59 (n = 10), and 22 +/- 20 (n = 10) in rats treated with thrombin plus heparin or hirudin, respectively. Thrombin produced endothelial lesions at all times studied, and these included membrane blebs, platelet and erythrocyte adhesion and alterations in the pattern of endothelial esterase activity.     

Bioreactivity of stent material: Activation of platelets,coagulation, leukocytes and endothelial cell dysfunction in vitro

Outcome of patients with coronary artery disease has been significantly improved by percutaneous coronary interventions with stent implantation. However, despite progress made on devices and antithrombotic treatments, stent thrombosis remains an important issue because of serious adverse consequences. Several mechanisms are assumed to favor stent thrombosis as platelet aggregation, fibrin formation, defective healing and local inflammation. The objective of this study was to evaluate in vitro the thrombogenicity, proinflammatory properties and healing capacities of cobalt–chromium (CoCr), an alloy commonly used for cardiovascular implants. Platelet adhesion was quantified in static and flow conditions. Thrombin generation was performed using the calibrated automated thrombogram. Neutrophil adhesion and formation of extracellular traps were visualized by scanning electron microscopy and by immunofluorescence. The phenotype of endothelial cells grown on CoCr was analyzed using specific antibodies, whereas the procoagulant potential was analyzed by measuring thrombin generation and protein C activation. Our results show that human blood platelets adhere to and are activated on CoCr in static and flow conditions. Overall, CoCr significantly induced thrombin generation in the presence or absence of platelets by 1.5- and 4.8-fold, respectively, involving activation of the contact pathway and activation of platelets. CoCr triggered leukocyte adhesion and behaved as a scaffold for the formation of neutrophil extracellular traps in the presence of platelets. Endothelial cells adhered and formed a monolayer covering CoCr. However, they switched from an anticoagulant phenotype to a procoagulant one with a significant 2.2-fold increase in thrombin generation due to a combined 30% reduced capacity to trigger protein C activation and 30% increased expression of tissue factor. Moreover, endothelial cells grown on CoCr acquired an inflammatory phenotype as indicated by the increased expression of ICAM-1 and VCAM-1. These data show that bare CoCr is prothrombotic and proinflammatory due to its capacity to activate platelets and coagulation and to induce leukocyte adhesion and activation. More importantly, even if endothelialization is achievable, the switch in endothelial phenotype prevents effective healing. Furthermore, we propose our methodology for future preclinical in vitro evaluation of the thrombogenicity of stent materials.     

Minimal platelet deposition and activation in models of injured vessel wall ensure optimal neutrophil adhesion under flow conditions.

Platelets at injured vessel wall form an adhesive surface for leukocyte adhesion. The precise relation between platelet adhesion and activation and leukocyte adhesion, however, is not known. We therefore used various models of injured vessel wall to form different patterns of platelet adhesion. The interaction of polymorphonuclear neutrophils (PMNs) was subsequently studied under flow conditions. In the absence of platelets, not only endothelial cell, smooth muscle cell, and fibroblast matrices but also purified matrix proteins (fibrinogen, collagen, and fibronectin) barely support PMN adhesion. The presence of platelets, however, strongly enhances PMN adhesion. PMN adhesion shows a proportional increase with platelet coverage up to 15%. Although PMNs roll over the scarcely scattered platelets, they speed up again when encountering surfaces without platelets. This "hopping" interaction of PMNs vanishes with platelet coverage >15%. Unobstructed rolling of PMNs is than observed and soon leads to a maximal adhesion of 1000 to 1200 cells/mm2. The mean rolling velocity of PMNs continues to decrease with higher platelet coverage. Platelet aggregate formation is an accepted indicator of platelet activation. The presence of platelet aggregates instead of contact or spread platelets, however, does not increase PMN adhesion. Also, additional stimulation of surface-associated platelets by thrombin fails to influence PMN adhesion. Moreover, indomethacin as an inhibitor of platelet activation and aggregation does not change the subsequent PMN interaction. In conclusion, approximately 15% of platelet coverage is sufficient for optimal PMN adhesion. Increasing platelet coverage increases the availability of platelet-associated receptors that lower PMN rolling velocity. Additional activation of adherent platelets makes no difference in the expression of relevant adhesion receptors. Therefore, minimal vascular damage in vivo and only scarce platelet adhesion will already evoke significant colocalization of leukocytes.     

Effect of blood flow on thrombin generation is dependent on the nature of the thrombogenic surface

We have investigated the influence of blood flow on thrombin generation, fibrin formation, and fibrin deposition on procoagulant and nonprocoagulant surfaces. Nonanticoagulated human blood was drawn for 5 minutes directly from an antecubital vein over stimulated endothelial cells expressing tissue factor and over human type III collagen fibrils, positioned in parallel-plate perfusion chambers. The shear rates at these surfaces were 50, 650, and 2,600 s-1. Deposition of platelets and fibrin was measured by morphometry. Thrombin and fibrin formation was determined by measuring prothrombin fragments 1 + 2 (F 1 + 2), thrombin-antithrombin III complexes, (T-AT) and fibrinopeptide A (FPA) in blood effluent from the perfusion chamber at the end of the 5- minute perfusion period. On procoagulant endothelial cells, the thrombi were primarily composed of fibrin. The fibrin deposition (81%, 21%, and 2% at 50, 650, and 2,600 s-1, respectively) and plasma levels of F 1 + 2, T-AT and FPA were shear rate dependent and highest at 50 s-1. There was a positive correlation between F 1 + 2 and T-AT and the fibrin deposition (P < .01). In contrast, the collagen surface triggered primarily thrombi that were composed of platelets. The platelet thrombi and plasma levels of F 1 + 2 and T-AT were also dependent on the shear rate, but highest at 650 and 2,600 s-1. F 1 + 2 and T-AT reached the same level as observed with procoagulant endothelial cells at the higher shear rates. There was a positive correlation between F 1 + 2 and T-AT and the platelet thrombus formation (P < .05), confirming the predominant role of platelets in thrombin generation. Thus, thrombin formation is strongly influenced by the blood flow, and this effect depends on the composition of the thrombogenic surface.     

Platelet adhesion and aggregation and fibrin formation in flowing blood: a historical contribution by Giulio Bizzozero

At the occasion of the first centennial of Giulio Bizzozero's death, the modern readers' attention is addressed to some ingenious experiments Bizzozero performed in Turin, Italy, around 1880. He discovered and carefully described blood platelet function in flowing conditions and the relationship between platelet adhesion to an artificial surface, aggregation and subsequent fibrin formation and deposition on activated platelet membrane. Bizzozero challenged contemporary concepts involving leukocytes in blood coagulation, but concluded that participation of blood platelets and white cells in fibrin formation was conceivable.     

Thrombin facilitates primary platelet adhesion onto vascular surfaces in the absence of plasma adhesive proteins: studies under flow conditions

BACKGROUND AND OBJECTIVE: The effect of local and circulating thrombin on platelet adhesion onto vascular surfaces was explored in the absence of plasma adhesive proteins using flow conditions. DESIGN AND METHODS: To study the local effects of thrombin, denuded rabbit aorta segments were incubated with thrombin concentrations of 0.001, 0.01 and 0.1 U/mL. To evaluate the effects of circulating thrombin, the same concentrations were added to perfusates consisting of washed platelets and washed red blood cells suspended in a human albumin solution (5%). In some experiments, purified von Willebrand's factor (vWF) (Haemate-P) was added to the perfusates (0. 8 U/mL of vWF, final concentration). A humanized chimeric antibody to the GPIIb-IIIa complex (Reopro) was used to determine the role of this glycoprotein on platelet adhesion under the conditions described. The effect of blocking GPIb was also assessed. Perfusions were carried out at 800 s(-1) for 10 min. The interaction of platelet with the vessel surface was morphometrically evaluated and expressed as percentage of surface coverage (%SC). Changes in the surface expression of the major platelet antigens were also analyzed by flow cytometry. RESULTS: Incubation of subendothelial surfaces with thrombin enhanced platelet deposition with respect to control levels (increases in SC of 64%, 79% and 86% with 0.001, 0.01 and 0.1 U/mL of thrombin, respectively). Low concentrations of thrombin (0.001 and 0.01 U/mL) incorporated in the perfusates resulted in a similar pro-adhesive effect (increases in SC of 64% and 71%, respectively) while the highest concentration (0.1 U/mL) failed to produce a pro-adhesive effect due to the augmented formation of platelet aggregates with subsequent thrombocytopenia (15+/-1 vs. 160+/-5x10(9) plt/L in the perfusates). Similar results were obtained when VWF was present in the perfusate. Reduction of platelet deposition by blockade of GPIIb-IIIa (to 5.3+/-0.7%) was partially restored by thrombin. Blockade of GPIb prevented platelets from adhering even when thrombin was present (%SC of 2.0+/-0.8%). No significant changes in the distribution of platelet membrane glycoproteins during perfusion experiments were detected. INTERPRETATION AND CONCLUSIONS: Our results suggest that thrombin facilitates primary platelet adhesion onto vascular surfaces even in the absence of plasma adhesive proteins. This effect seems to be mainly dependent on the GPIb/vWF axis.     

Endothelial function and hemostasis

The vascular endothelium influences not only the three classically interacting components of hemostasis: the vessel, the blood platelets and the clotting and fibrinolytic systems of plasma, but also the natural sequelae: inflammation and tissue repair. Two principal modes of endothelial behaviour may be differentiated, best defined as an anti- and a prothrombotic state. Under physiological conditions endothelium mediates vascular dilatation (formation of NO, PGI2, adenosine, hyperpolarizing factor), prevents platelet adhesion and activation (production of adenosine, NO and PGI2, removal of ADP), blocks thrombin formation (tissue factor pathway inhibitor, activation of protein C via thrombomodulin, activation of antithrombin III) and mitigates fibrin deposition (t- and scuplasminogen activator production). Adhesion and transmigration of inflammatory leukocytes are attenuated, e.g. by NO and IL-10, and oxygen radicals are efficiently scavenged (urate, NO, glutathione, SOD). When the endothelium is physically disrupted or functionally perturbed by postischemic reperfusion, acute and chronic inflammation, atherosclerosis, diabetes and chronic arterial hypertension, then completely opposing actions pertain. This prothrombotic, proinflammatory state is characterised by vaso-constriction, platelet and leukocyte activation and adhesion (externalization, expression and upregulation of von Willebrand factor, platelet activating factor, P-selectin, ICAM-1, IL-8, MCP-1, TNF alpha, etc.), promotion of thrombin formation, coagulation and fibrin deposition at the vascular wall (expression of tissue factor, PAI-1, phosphatidyl serine, etc.) and, in platelet-leukocyte coaggregates, additional inflammatory interactions via attachment of platelet CD40-ligand to endothelial, monocyte and B-cell CD40. Since thrombin formation and inflammatory stimulation set the stage for later tissue repair, complete abolition of such endothelial responses cannot be the goal of clinical interventions aimed at limiting procoagulatory, prothrombotic actions of a dysfunctional vascular endothelium.     

Procoagulant State of Sleep Apnea Depends on Systemic Inflammation and Endothelial Damage

IntroductionGrowing evidence shows a hypercoagulable state in obstructive sleep apnea (OSA) that could be a risk factor for thromboembolic disease.ObjectivesWe aimed to elucidate mechanisms involved in the procoagulant profile observed in patients with OSA and to investigate the potential utility of global tests in its characterization.MethodsThirty-eight patients with severe OSA without previous history of thrombosis and nineteen healthy age- and sex-matched controls were included.Kinetic of clot formation was determined using rotational thromboelastometry.Haemostatic capacity of plasma and microparticles was determined by Calibrated Automated Thrombinography.Platelet surface receptors, activation markers and formation of platelet/leukocytes aggregates were analyzed by flow cytometry.ResultsThromboelastometry showed a procoagulant state in patients with OSA that did not seem to be related to a basal activation of platelets but by the increased existence of platelet/leukocyte aggregates.Patients with OSA presented many signs of endothelial damage such as increased plasma levels of E-selectin and cfDNA and enhanced thrombin generation due to the presence of microparticles rich in tissue-factor, which is related to OSA severity.ConclusionsOSA induces an enhancement in the dynamics of clot formation which appears to be caused by at least two pathological mechanisms. First, a greater formation of platelet-leukocyte aggregates; secondly, endothelial damage which provokes a greater procoagulant potential due to the increase in tissue factor-rich microparticles. Moreover, this study has identified thromboelastometry and thrombin generation assay as useful tools to evaluate the prothrombotic state in these patients.     

Fibrinogen deposition at the postischemic vessel wall promotes platelet adhesion during ischemia-reperfusion in vivo

Following ischemia-reperfusion (I/R), platelet adhesion is thought to represent the initial event leading to remodeling and reocclusion of the vasculature. The mechanisms underlying platelet adhesion to the endothelium have not been completely established. Endothelial cells rendered ischemic acquire a procoagulant phenotype, characterized by fibrinogen accumulation. Therefore, we evaluated whether fibrinogen deposition during I/R mediates platelet adhesion. Using fluorescence microscopy, fibrinogen deposition and the accumulation of platelets were assessed in vivo in a model of intestinal I/R (1.5 hours/60 minutes). Fibrinogen accumulated in arterioles and venules early after the onset of reperfusion. The deposition of fibrinogen colocalized with large numbers of adherent platelets (520 +/- 65 and 347 +/- 81 platelets/mm(2) in arterioles and venules). Pretreatment with an antifibrinogen antibody attenuated platelet adhesion. Intracellular adhesion molecule (ICAM)-1 served as a major receptor for fibrinogen, since fibrinogen deposition and platelet adhesion to the endothelial cell surface were markedly decreased in ICAM-1-deficient mice. The platelet alpha(IIb)/beta(3) integrin plays a key role in fibrinogen-dependent platelet accumulation, because (1) platelet adhesion involved RGD-recognition sequences, and (2) platelets isolated from a patient with Glanzmann's disease showed decreased interaction with the postischemic endothelium. Since platelets are demonstrated here to induce tyrosine phosphorylation in endothelial cells, platelet recruitment might contribute to the development of an inflammatory reaction during I/R.     

P-selectin in arterial thrombosis

P-selectin is a transmembrane protein present in the alpha granules of platelets and the Weibel-Palade bodies of endothelial cells. Following activation, it is rapidly translocated to the cell surface. P-selectin expression in platelets has been shown to be elevated in disorders associated with arterial thrombosis such as coronary artery disease, acute myocardial infarction, stroke, and peripheral artery disease. P-selectin mediates rolling of platelets and leukocytes on activated endothelial cells as well as interactions of platelets with leukocytes. Platelet P-selectin interacts with P-selectin glycoprotein ligand-1 (PSGL-1) on leukocytes to form platelet-leukocyte aggregates. Furthermore, this interaction of P-selectin with PSGL-1 induces the upregulation of tissue factor, several cytokines in leukocytes and the production of procoagulant microparticles, thereby contributing to a prothrombotic state. P-selectin is also involved in platelet-platelet interactions, i. e. platelet aggregation which is a major factor in arterial thrombosis. P-selectin interacts with platelet sulfatides, thereby stabilizing initial platelet aggregates formed by GPIIb/IIIa-fibrinogen bridges. Inhibtion of the P-selectin-sulfatide interaction leads to a reversal of platelet aggregation. Thus, P-selectin plays a significant role in platelet aggregation and platelet- leukocyte interactions, both important mechanisms in the development of arterial thrombosis.     

Endothelial cell function and thrombosis.

The endothelium is pivotal in the control of haemostasis and thrombosis because it is the primary source of many of the major haemostatic regulatory molecules. Healthy endothelial cells, unlike extravascular cells, are anticoagulant and antithrombotic. This is due to the regulated secretion of antiplatelet agents, including prostacyclin and nitric oxide. Following vessel injury, platelet adhesion to exposed matrix requires von Willebrand Factor, another endothelial cell product. Local generation of thrombin causes a series of receptor-mediated endothelial cell functional responses, while the surface of the endothelium is additionally the site for inactivation of thrombin by antithrombin, and its conversion to a coagulation inhibitor by interaction with thrombomodulin. Endothelial cells are also the source of circulating tissue-type plasminogen activator and its inhibitor, and Tissue Factor pathway inhibitor. In disease states, many of these endothelial cell properties are perturbed towards a more procoagulant and prothrombotic phenotype.     

Cytokines in sickle cell disease

Sickle red cells express adhesion molecules including integrin alpha4beta1, CD36, band 3 protein, sulfated glycolipid, Lutheran protein, phosphatidylserine and integrin-associated protein. The proadhesive sickle cells may bind to endothelial cell P-selectin, E-selectin, intercellular adhesion molecule-1 (ICAM-1), vascular cell adhesion molecule-1 (VCAM-1), CD36 and integrins leading to its activation. Monocytes also activate endothelium by releasing proinflammatory cytokines like tumor necrosis factor alpha (TNF-alpha) and interleukin 1beta (IL-1beta). Sickle monocytes also express increased surface CD11b and cytoplasmic cytokines TNFalpha and IL-1beta indicating activated state. Polymorphonuclear leukocytes (PMNs) are also activated with reduced L-selectin expression, enhanced CD64 expression and elevated levels of sL-selectin, sCD16 and elastase resulting in increased adhesiveness to the endothelium. Platelets are also activated and secrete thrombospondin (TSP) and cytokine IL-1. They also form platelet- monocytes aggregates causing endothelial cell P-selectin expression. Endothelial cell activation by these multiple mechanisms leads to a loss of vascular integrity, expression of leukocyte adhesion molecules, change in the surface phenotype from antithrombotic to prothrombotic, excessive cytokine production and upregulation of HLA molecules. Furthermore, contraction of these activated endothelial cells leads to exposure of extracellular matrix proteins, such as TSP, laminin, and fibronectin and their participation in adhesive interactions with bridging molecules from the plasma such as von Willebrand factor (vWf) released from endothelial cells, ultimately culminating in vasoocclusion and local tissue ischemia, the pathognomonic basis of vasoocclusive crisis.     

Cytokines in Sickle Cell Disease

Sickle red cells express adhesion molecules including integrin ₄β₁, CD36, band 3 protein, sulfated glycolipid, Lutheran protein, phosphatidylserine and integrin-associated protein. The proadhesive sickle cells may bind to endothelial cell P-selectin, E-selectin, intercellular adhesion molecule-1 (ICAM-1), vascular cell adhesion molecule-1 (VCAM-1), CD36 and integrins leading to its activation. Monocytes also activate endothelium by releasing proinflammatory cytokines like tumor necrosis factor alpha (TNF-) and interleukin 1β (IL-1β). Sickle monocytes also express increased surface CD11b and cytoplasmic cytokines TNF and IL-1β indicating activated state. Polymorphonuclear leukocytes (PMNs) are also activated with reduced L-selectin expression, enhanced CD64 expression and elevated levels of sL-selectin, sCD16 and elastase resulting in increased adhesiveness to the endothelium. Platelets are also activated and secrete thrombospondin (TSP) and cytokine IL-1. They also form platelet- monocytes aggregates causing endothelial cell P-selectin expression. Endothelial cell activation by these multiple mechanisms leads to a loss of vascular integrity, expression of leukocyte adhesion molecules, change in the surface phenotype from antithrombotic to prothrombotic, excessive cytokine production and upregulation of HLA molecules. Furthermore, contraction of these activated endothelial cells leads to exposure of extracellular matrix proteins, such as TSP, laminin, and fibronectin and their participation in adhesive interactions with bridging molecules from the plasma such as von Willebrand factor (vWf) released from endothelial cells, ultimately culminating in vasoocclusion and local tissue ischemia, the pathognomonic basis of vasoocclusive crisis.     

Procoagulant activity on platelets adhered to collagen or plasma clot

In a new 2-stage assay of platelet procoagulant activity (PCA), we first subjected gel-filtered platelets to adhesion on collagen (as a model of primary hemostasis) or plasma clots (as a model of preformed thrombus) for 30 minutes, and then the adherent platelets were supplemented with pooled, reptilase-treated, diluted plasma. Defibrinated plasma provided coagulation factors for assembly on platelet membranes without uncontrolled binding of thrombin to fibrin(ogen). Platelet adhesion to both surfaces showed modest individual variation, which increased at platelet densities that allowed aggregation. However, adhesion-induced PCA varied individually and surface-independently >3-fold, suggesting a uniform platelet procoagulant mechanism. Permanently adhered platelets showed markedly enhanced PCA when compared with the platelet pool in suspension, even after strong activation. The rate of thrombin generation induced by clot-adherent platelets was markedly faster than on collagen-adherent platelets during the initial phase of coagulation, whereas collagen-induced PCA proceeded slowly, strongly promoted by tissue thromboplastin. Therefore at 10 minutes, after adjustment for adhered platelets, collagen supported soluble thrombin formation as much as 5 times that of the thrombin-retaining clots. Activation of platelets by their firm adhesion was accompanied by formation of microparticles, representing about one third of the total soluble PCA. Collagen-adhered platelets provide soluble thrombin and microparticles, whereas the preformed clot serves to localize and accelerate hemostasis at the injury site, with the contribution of retained thrombin and microparticles.     

An endothelial cell-dependent pathway of coagulation.

Although the endothelial cell is considered antithrombogenic, endothelium has recently been shown to participate in procoagulant reactions. In this report cultured bovine aortic endothelial cells are shown to propagate a procoagulant pathway starting with factor XIa, leading to activation of factors IX, VIII, X, and prothrombin, culminating in fibrinopeptide A cleavage from fibrinogen and formation of a fibrin clot. Electron microscopic studies demonstrated that fibrin strands are closely associated with the endothelial cells. Endotoxin-treated endothelial cells, having acquired tissue factor activity, generated fibrinopeptide A in the presence of factors VIIa, IX, VIII, X, prothrombin, and fibrinogen. Factor X activation by factor VIIa and tissue factor expressed by endothelial cells is 10 times greater in the presence of factors IX and VIII than in their absence. This indicates that on the perturbed endothelial cell surface, factors IX and VIII do have an important role in the activation of factor X. Addition of platelets (10(8) per ml) augmented thrombin formation seen in the presence of endothelium alone by about 15-fold. Anti-human factor V IgG decreased this enhanced thrombin formation in the presence of platelets, indicating that factor V from platelets was playing an important role in thrombin formation. These data lead us to propose that endothelial cells can actively participate in procoagulant reactions. Although platelets can augment thrombin formation by these endothelial cell-dependent reactions, endothelial cells alone can lead to formation of a cell-associated fibrin clot. The endotoxin-treated endothelial cell provides a model of the thrombotic state supplying tissue factor to initiate coagulation and propagating the reactions leading to fibrin formation. This endothelial cell-dependent pathway suggests a central role for factors VIII and IX consistent with their importance in hemostasis.     

Procoagulant activity of endotoxin-treated human endothelial cells exposed to native human flowing blood

It has been reported that cultured endothelial cells become procoagulant when exposed to endotoxin. This prompted us to investigate whether human endothelial cells treated with endotoxin could promote the generation of fibrin when exposed to human flowing blood. For this purpose we used a parallel-plate perfusion chamber in which confluent cultured endothelial cells from human umbilical veins were exposed for five minutes to directly drawn human nonanticoagulated blood, at wall shear rates of 100, 650, and 2600 sec-1. Fibrin deposition was assessed by morphometry. No fibrin deposition occurred on normal endothelial cells. In contrast, cells incubated with endotoxin for 4 or 18 hours induced fibrin deposition, but only at a shear rate of 100 sec-1. Since some extracellular matrix was exposed between the cells, we investigated whether extracellular matrix played a role in fibrin formation. When the endothelial cells incubated or not with endotoxin were removed by EDTA, the exposed extracellular matrix perfused with blood at 100 sec-1 supported platelet and fibrin deposition in both cases. This suggests that the effect of endotoxin on endothelial cells was not due to extracellular matrix alteration but only to cellular activation or secretion of procoagulant substances. We conclude that human endothelial cells treated with endotoxin can trigger fibrin formation and deposition at their surface when exposed to flowing blood at low shear rate.