New perspectives on the coagulation cascade

Factors Associated with Systemic Bleeding in Bothrops Envenomation in a Tertiary Hospital in the Brazilian Amazon

Bothrops snakebites usually present systemic bleeding, and the clinical–epidemiological and laboratorial factors associated with the development of this manifestation are not well established. In this study, we assessed the prevalence of Bothrops snakebites with systemic bleeding reported at the Fundação de Medicina Tropical Dr. Heitor Vieira Dourado, in Manaus, Amazonas State, Brazil, and the clinical–epidemiological and laboratorial factors associated with systemic bleeding. This is an observational, cross-sectional study carried out between August, 2013 and July, 2016. Patients who developed systemic bleeding on admission or during hospitalization were considered cases, and those with non-systemic bleeding were included in the control group. Systemic bleeding was observed in 63 (15.3%) of the 442 Bothrops snakebites evaluated. Bothrops snakebites mostly occurred in males (78.2%), in rural areas (89.0%) and in the age group of 11 to 30 years old (40.4%). It took most of the patients (59.8%) less than 3 h to receive medical assistance. Unclottable blood (AOR = 3.11 (95% CI = 1.53 to 6.31; p = 0.002)) and thrombocytopenia (AOR = 4.52 (95% CI = 2.03 to 10.09; p < 0.001)) on admission were independently associated with systemic bleeding during hospitalization. These hemostatic disorders on admission increase the chances of systemic bleeding during hospitalization. Prospective studies are needed to clarify the pathophysiology of systemic bleeding in Bothrops snakebites in the Amazon region.

Anticoagulant effects of an antidiabetic drug on monocytes in vitro

INTRODUCTION

Monocyte- and microparticle (MP)-associated tissue factor (TF) is upregulated in diabetes. Lipopolysaccharide (LPS) induces expression of TF and alternatively spliced TF (asTF) and increases MP release from monocytes. Using LPS-stimulated TF-bearing human monocytes, we examined whether glibenclamide, a sulfonylurea used to treat diabetes type 2, might possess anticoagulant properties.

METHODS

We studied the effects of glibenclamide on cell- and supernatant-associated procoagulant activity (Factor Xa-generating assay and clot formation assay), on expression of TF and asTF (flow cytometry, RT-qPCR, western blot) and on cell viability and MP release (flow cytometry).

RESULTS

Glibenclamide dose-dependently decreased procoagulant activity of cells and supernatants. The reduction in cellular procoagulant activity coincided with reduced expression of TF and asTF in cells, whereas cell viability remained almost unchanged. The glibenclamide-induced reduction in procoagulant activity of supernatants appeared to be associated with a decreased number of released MPs.

CONCLUSIONS

Reduction of monocyte- and supernatant-associated procoagulant activity by glibenclamide is associated with decreased expression of TF and asTF and possibly with a reduced MP number. Our data indicate that glibenclamide reduces the prothrombotic state in LPS-stimulated monocytes in vitro. Glibenclamide might therefore also have an anticoagulant effect in vivo, but this needs to be further evaluated.

Regional manifestations and control of the immune system

Although immune responses are generally considered to be systemic, local events such as interaction of complement products with blood vessels and with inflammatory cells play a pivotal role in determining the nature and manifestations of immune responses. This paper will discuss how blood vessel physiology and immunity influence one another to reach homeostasis upon exposure to an infectious agent. We review new insights into the mechanisms by which the microenvironment of tissues protects against microbial invasion yet facilitates migration of leukocytes and 'decides' whether immunity or tolerance ensues and whether, in the face of immunity, protective responses or tissue injury ensues. These 'decisions' are made based on interaction of components of normal tissues such as proteoglycans and injured tissues such as cell-associated cytokines with receptors on immune cells and blood vessels.

Pharmacology of low molecular weight heparins

Although intravenous heparin has been the treatment of choice for acute VTE disease, LMWHs are gaining wider recognition and support as not only a new option but also as the standard of care. Each LMWH is viewed as a unique drug by regulatory agencies because of their differing physical and pharmacokinetic attributes. LMWHs have high absorption, high bioavailability, and long half-lives enabling once- or twice-daily dosing with predictable dose-response relationships. These factors enable the LMWHs to be used without laboratory monitoring and at home for acute DVT management. Studies continue to show that LMWH preparations are as at least as effective as heparin in a variety of settings, including VTE disease prophylaxis, management of acute VTE disease, unstable angina, and NSTEMI. They are at least as safe as heparin relative to hemorrhagic complications. Heparin-induced thrombocytopenia is less of a problem with LMWHs. Use of LMWHs has resulted in cost benefits in the treatment of acute DVT, unstable angina, and NSTEMI as well as in prophylaxis against venous thromboembolism. Emergency physicians, because of their unique position at the forefront of acute care, will soon regularly use LMWHs.

Effect of oligodeoxynucleotide thrombin aptamer on thrombin inhibition by heparin cofactor II and antithrombin

'Thrombin aptamers' are based on the 15-nucleotide consensus sequence of d(GGTTGGTGTGGTTGG) that binds specifically to thrombin's anion-binding exosite-I. The effect of aptamer-thrombin interactions during inhibition by the serine protease inhibitor (serpin) heparin cofactor II (HCII) and antithrombin (AT) has not been described. Thrombin inhibition by HCII without glycosaminoglycan was decreased approximately two-fold by the aptamer. In contrast, the aptamer dramatically reduced thrombin inhibition by >200-fold and 30-fold for HCII-heparin and HCII-dermatan sulfate, respectively. The aptamer had essentially no effect on thrombin inhibition by AT with or without heparin. These results add to our understanding of thrombin aptamer activity for potential clinical application, and they further demonstrate the importance of thrombin exosite-I during inhibition by HCII-glycosaminoglycans.

Insight into the mechanism of asparaginase-induced depletion of antithrombin III in treatment of childhood acute lymphoblastic leukemia

Asparaginase (ASNase) is a widely used and successful agent against childhood acute lymphoblastic leukemia (ALL). Asparaginase cleaves asparagine (Asn) to give aspartic acid and ammonia, thereby depleting free Asn in the blood. However, treatment with ASNase has been implicated in significant reduction of plasma levels of the coagulation serine protease inhibitor (serpin) antithrombin III (AT3), predisposing patients to thromboembolic complications. Our investigation was designed to delineate the biochemical mechanism of AT3 depletion that can occur in the plasma of ALL patients undergoing ASNase therapy. SDS-PAGE showed no cleavage of purified AT3 following treatment with ASNase. Furthermore, purified AT3 treated with ASNase demonstrated no decrease in inhibitory activity. Human plasma and whole blood treated with approximate therapeutic concentrations of ASNase showed no loss of AT3 activity as detected by a plasma-based factor Xa inhibition assay. Treatment of a confluent monolayer of HepG2 (hepatocarcinoma) cells with ASNase showed no gross loss in AT3 message levels detected by rtPCR. However, a decrease of cell viability was observed in cultures treated with ASNase. Interestingly, medium from HepG2 cells treated with ASNase showed a marked decrease in secretion of AT3 and another serpin, heparin cofactor II. Collectively, these data show that ASNase has no direct effect on AT3 in blood or plasma, but that ASNase may affect plasma levels of AT3 by interfering with translation and/or secretion of the protein in liver cells.

Evaluation of bleeding disorders. A detailed history and laboratory tests provide clues

A single, optimal screening laboratory test for hemostasis would evaluate vascular, platelet, coagulation, and fibrinolytic functions. Unfortunately, such a test does not exist. The key factor in determining the presence of a bleeding diathesis is obtaining a detailed patient history. Results of coagulation tests should always be interpreted in the context of such a history. Screening tests include platelet count, PTT, and PT. Subsequent investigations depend on the results of these tests.

Fundamentals of coagulation and glycoprotein IIb/IIIa receptor inhibition

An understanding of the coagulation process and the role of platelets is essential to recognizing the shortcomings of older anticoagulant therapies and appreciating the clinical potential of newer forms of antiplatelet and anticoagulant therapy for acute coronary syndromes. The anticoagulant actions of heparin are severely limited by dependence on antithrombin III, neutralization by platelet factor 4, and the resistance of clot-bound thrombin and platelet membrane-bound factor Xa to the heparin-antithrombin III complex. Unlike heparin, the direct thrombin inhibitors (such as hirudin) are active against both circulating and clot-bound thrombin. However, in recent clinical trials they have not resulted in major improvements in patient outcome. Another new class of drugs, the glycoprotein IIb/IIIa receptor antagonists, blocks the final common pathway of platelet aggregation and is capable of preventing platelet accumulation at sites of injury. The net effect is a dramatic reduction in the amount of platelet membrane available to support the process of coagulation. Clinical trials with the glycoprotein IIb/IIIa inhibitors have suggested that this class of agents may be particularly effective in reducing the thrombotic complications associated with coronary interventional procedures and may be useful in the treatment of acute coronary syndromes.

The pathophysiology of bleeding disorders presenting as abnormal uterine bleeding

Abnormal uterine bleeding is often the presenting complaint in women with underlying coagulopathies. A clear understanding of the pathophysiology of common bleeding disorders will help the practicing obstetrician/gynecologist in the diagnosis and treatment of these conditions. The normal hemostatic process can be divided into three phases. The first phase, primary hemostasis, consists of platelet adhesion and aggregation. After vascular injury, proteins in the subendothelium are exposed that promote platelet adhesion. Platelet adhesion is uniquely dependent on von Willebrand factor, a plasma protein that serves as a molecular bridge between components of the vessel wall and the platelet glycoprotein Ib/IX receptor. Activation of the adherent platelets promotes additional platelet recruitment, culminating in the formation of the platelet plug. Quantitative or qualitative defects in either the platelet or von Willebrand factor (von Willebrand disease) lead to defective primary hemostasis. Patients present with a prolonged bleeding time and mucocutaneous bleeding manifestations. In the next phase, secondary hemostasis, the plasma coagulation factors are sequentially activated, which leads to fibrin formation and cross-linking. These reactions take place primarily on the surface of activated platelets and are essential in maintaining the stability of the initial platelet plug. Defective secondary hemostasis arises from congenital or acquired deficiencies in coagulation factors. Although these defects are most often associated with bleeding into joints and soft tissues, other manifestations, including abnormal uterine bleeding, may be present. The prothrombin time and the activated partial thromboplastin time serve as initial screening tests for these coagulation disorders, although more specific tests, including factor levels, thrombin time, clot solubility, and mixing studies, are needed to fully define the defect. In the final phase of normal hemostasis, fibrinolysis, the fibrin clot undergoes an orderly process of degradation. Deficiencies in the normal inhibitors of fibrinolysis, such as alpha 2-antiplasmin or plasminogen activator inhibitor-1, may be underdiagnosed causes of delayed bleeding because they are not identified by the usual coagulation screening tests. Disorders of primary hemostasis, including thrombocytopenia and von Willebrand disease, are particularly important to consider when evaluating women with abnormal uterine bleeding. Patients with acquired or congenital deficiencies of either coagulation factors or the regulators of the fibrinolytic system may also present with menorrhagia. Accurate diagnosis of a bleeding disorder is essential to the design of an appropriate therapeutic regimen and is likely to have important clinical implications beyond that of the presenting gynecologic complaint.

Functional characterization of the human factor VII 5'-flanking region

Factor VII is a vitamin K-dependent coagulation protein essential for proper hemostasis. The human Factor VII gene spans 13 kilobase pairs and is located on chromosome 13 just 2.8 kilobase pairs 5' to the Factor X gene. In this report, we show that Factor VII transcripts are restricted to the liver and that steady state levels of mRNA are much lower than those of Factor X. The major transcription start site is mapped at -51 by RNase protection assay and primer extension experiments. The first 185 base pairs 5' of the translation start site are sufficient to confer maximal promoter activity in HepG2 cells. Protein binding sites are identified at nucleotides -51 to -32, -63 to -58, -108 to -84, and -233 to -215 by DNase I footprint analysis and gel mobility shift assays. A liver-enriched transcription factor, hepatocyte nuclear factor-4 (HNF-4), and a ubiquitous transcription factor, Spl, are shown to bind within the first 108 base pairs of the promoter region at nucleotide sequences ACTTTG and CCCCTCCCCC, respectively. The importance of these binding sites in promoter activity is demonstrated through independent functional mutagenesis experiments, which show dramatically reduced promoter activity. Transactivation studies with an HNF-4 expression plasmid in HeLa cells also demonstrate the importance of HNF-4 in promoting transcription in non-hepatocyte derived cells. Additionally, the sequence of a naturally occurring allele containing a previously described decanucleotide insert polymorphism at -323 is shown to reduce promoter activity by 33% compared with the more common allelic sequence.

Complement-mediated regulation of tissue factor activity in endothelium

Inflammation and immunity may be associated with endothelial cell (EC) injury and thrombus formation. We explored the mechanisms through which a humoral immune response directed against the endothelium might promote coagulation. Using the interaction of anti-EC antibodies and complement (C) with cultured EC as a model, we studied the expression and function of tissue factor, a cofactor for factor VIIa-mediated conversion of factor X to Xa. Exposure of EC to anti-EC antibodies and C in sublytic amounts stimulated the synthesis of tissue factor over a period of 16-42 h. Cell surface expression of tissue factor activity required activation of C and assembly of the membrane attack complex, because expression was inhibited by soluble CR1 and was not detected in the absence of C8. Elaboration of tissue factor messenger RNA was observed over a period of 8-30 h and required protein synthesis. Expression of tissue factor was not a direct consequence of the action of C on the EC but was a secondary response that required as an intermediate step the release of interleukin 1 alpha, an early product of the EC response to C activation. These findings suggest that, after the assembly of membrane attack complex on EC, the production of tissue factor and initiation of coagulation in a blood vessel depend on the production of interleukin 1 alpha and on its availability to stimulate affected EC.

Transient perturbation of endothelial integrity induced by natural antibodies and complement

The barrier function of blood vessels is though to be regulated at least in part by endothelium. This concept is supported by the dramatic loss of barrier function occurring in the hyperacute rejection of vascularized grafts mediated by anti-endothelial cell (EC) antibodies and complement. In this process, the endothelium is not destroyed but instead loses the ability to retain blood cells and plasma proteins within capillaries. The noncytotoxic mechanism that allows this change in EC function has been unknown. Here we report that within 10 to 20 min of exposure to human xenoreactive natural antibodies and complement, porcine EC undergo alterations in cell shape and in the cytoskeleton that disrupt monolayer integrity and lead to formation of intercellular gaps. Gap formation is not associated with cell death but requires the complement complex C5b67. The gaps induced by anti-EC antibodies and complement are transient; gap closure requires formation of C5b-9 complexes on the cells and the rate of recovery depends on the release of cellular products into the medium. Preincubation of EC with dibutyryl cAMP (0.5 mM) prevents gap formation and disruption of the cytoskeleton caused by antibodies and complement. These results provide evidence that the integrity of endothelium is regulated by components of the complement system and suggest a mechanism that may explain the prominent loss of endothelial integrity seen in humoral immune responses.

Diabetic muscle infarction: a new perspective on pathogenesis and management

Two patients with insulin dependent diabetes mellitus developed recurrent episodes of focal muscle pain and swelling. Clinical evaluation, magnetic resonance imaging (MRI) and muscle biopsy confirmed the diagnosis of recurrent hemorrhagic muscle infarctions. Our studies suggest that muscle infarction occurred because of hypercoagulability and associated vascular endothelial damage. Based on these findings we recommend long-term anticoagulation to prevent recurrent infarction.

An overview of hemostasis

Hemostasis is a remarkable and a remarkably complex mechanism. It can maintain blood in a fluid state intravascularly but very quickly changes blood to a jellylike mass upon disruption of the vasculature. This review will give a synopsis of the 3 phases of hemostasis: platelet, vascular, and coagulation. Fibrinolysis and control mechanisms of hemostasis will also be covered. In addition, brief descriptions of the clinical and laboratory evaluation of patients and the diagnosis of bleeding disorders will be presented.