Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0036690 (sepsis)
 59,461 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Endothelial cells have two important anticoagulant systems, heparan sulfate-antithrombin system and thrombomodulin-protein C system. Under physiological conditions, these two systems inhibit activation of coagulation on endothelial cells. However, under inflammatory conditions, tumor necrosis factor(TNF)-alpha or other cytokines produced by monocytes reduce the anticoagulant properties of endothelial cell by downregulating expression of heparan sulfate and thrombomodulin on endothelial cells. Antithrombin stimulates prostacyclin generation from endothelial cells by interacting with heparan sulfate of endothelial cells and generated prostacyclin inhibits TNF-alpha production by monocytes. Activated protein C inhibits TNF-alpha production by monocyte dependent of its protease activity. Thus, antithrombin and activated protein C might inhibit the endothelial perturbation induced by cytokines. Antithrombin regulates TNF-alpha induced tissue factor expression on endothelial cells by an unknown mechanism. Thus, antithrombin and activated protein C might be useful agents for treating coagulation abnormalities associated with sepsis or other inflammation because these agents inhibit not only coagulation but also downregulation of anticoagulant activities of endothelial cells.
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PMID:[Endothelial cells and coagulation abnormalities]. 1081 Aug 75

It is becoming increasingly clear that coagulation augments inflammation and that anticoagulants, particularly natural anticoagulants, can limit the coagulation induced increases in the inflammatory response. The latter control mechanisms appear to involve not only the inhibition of the coagulation proteases, but interactions with the cells that either generate anti-inflammatory substances, such as prostacyclin, or limit cell activation. Recent studies have demonstrated a variety of mechanisms by which coagulation, particularly the generation of thrombin, factor Xa and the tissue factor-factor VIIa complex, can augment acute inflammatory responses. Many of these responses are due to the activation of one or more of the protease activated receptors. Activation of these receptors on endothelium can lead to the expression of adhesion molecules and platelet activating factor, thereby facilitating leukocyte activation. Therefore, anticoagulants that inhibit any of these factors would be expected to dampen the inflammatory response. The three major natural anticoagulant mechanisms seem to exert a further inhibition of these processes by impacting cellular responses. Antithrombin has been shown in vitro to increase prostacyclin responses and activated protein C has been shown to inhibit a variety of cellular responses including endotoxin induced calcium fluxes in monocytes and the nuclear translocation of NFKB, a key step in the generation of the inflammatory response. In some, but not all, in vivo models, these natural anticoagulants have been able to inhibit endotoxin/E. coli-mediated leukocyte activation and to diminish cytokine elaboration (TNF, IL-6 and IL-8). Phase III clinical studies for treatment of patients with severe sepsis have been completed for APC, which was successful (1), and for antithrombin, which was not (2). A phase III trial with tissue factor pathway inhibitor is in progress. In this review, the mechanisms by which the different natural anticoagulants are thought to function will be reviewed.
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PMID:Role of coagulation inhibitors in inflammation. 1148 41

Antithrombin (AT) prevents Escherichia coli-induced hypotension in animal models of sepsis, and it further reduces the mortality of patients with septic shock. In the present study, we examined whether AT may prevent the endotoxin (ET)-induced hypotension by promoting the endothelial release of prostacyclin (PGI(2)) in rats. Intravenous administration of AT (250 U/kg) prevented both hypotension and the increases in plasma levels of NO(2)(-)/NO(3)(-) in rats given ET. Lung expression of messenger RNA (mRNA) for tumor necrosis factor-alpha (TNF-alpha) was transiently increased after ET administration, followed by the increases in lung tissue levels of TNF-alpha. Both the lung activity of the inducible form of nitric oxide synthase (iNOS) and the lung expression of iNOS mRNA in animals administered ET were gradually increased after the TNF-alpha mRNA expression had peaked. Administration of AT significantly inhibited these increases. Neither DEGR-F.Xa, a selective inhibitor of thrombin generation, nor Trp(49)-modified AT, which is not capable of promoting the endothelial release of PGI(2), showed any effects on these changes induced by ET. Administration of antirat TNF-alpha antibody produced effects similar to those induced by AT. Indomethacin pretreatment abrogated the effects induced by AT. Iloprost, a stable derivative of PGI(2), produced effects similar to those of AT. These findings suggested that AT prevents the ET-induced hypotension by inhibiting the induction of iNOS through inhibiting TNF-alpha production. These effects of AT could be mediated by the promotion of endothelial release of PGI(2) and might at least partly explain the therapeutic effects for septic shock.
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PMID:Antithrombin prevents endotoxin-induced hypotension by inhibiting the induction of nitric oxide synthase in rats. 1186 Dec 78

Antithrombin has been used for over two decades as adjuvant therapy in severe sepsis, especially when associated with coagulopathy. A positive effect has been demonstrated in several experimental sepsis models and a number of small clinical trials have suggested a beneficial effect. A large confirmatory randomized clinical trial with 2,314 evaluable patients with severe sepsis was recently completed [1]. No treatment effect of antithrombin was demonstrated (28 day overall mortality was 38.9% and 38.7% in the treatment and placebo groups, respectively). Among various secondary effect and subgroup analyses, it is noteworthy that no trend indicating a beneficial effect of antithrombin substitution was found even in the subgroup of patients with plasma levels of antithrombin < 60% on randomization (n = 1,117). In summary, there is presently no support for the general use of antithrombin as adjuvant therapy in severe sepsis/septic shock.
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PMID:[Antithrombin therapy of no value in sepsis according to a large clinical trial]. 1198 56

Antithrombin (AT) circulates in plasma in two isoforms, AT-alpha (90-95%) and AT-beta (5-10%). AT isoform proportions were measured in plasma samples of 17 healthy subjects and 26 posttraumatic or postoperative septic patients, as well as in 4 commercially available AT concentrates. Total AT was immune-purified from plasma and concentrates. Micellar electrokinetic chromatography was used to analytically separate and quantify the isoforms. Compared with plasma samples of healthy donors, septic plasmas revealed significantly reduced AT activity (p < 0.001) and beta-isoform content (p < 0.05). AT-beta correlated inversely with urea and creatinine serum concentrations (p < 0.01), indicating a relationship between better renal function and higher beta-isoform content. beta-Isoform neither correlated with age, gender, and 28-day mortality, nor with plasma concentrations of various inflammatory and organ function parameters. The commercial AT concentrate, which is equivalent to the current WHO standard, had an AT-beta content close to that found in plasma of healthy subjects. The availability of this novel quantitative AT isoform assay allows, for the first time, a closer look at the role of AT isoforms in hemostasis and sepsis pathophysiology.
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PMID:Quantification of antithrombin isoform proportions in plasma samples of healthy subjects, sepsis patients, and in antithrombin concentrates. 1237 30

Antithrombin (AT) is a plasma-derived, single-chain glycoprotein with a molecular weight of 58 kDa. It is a serine protease inhibitor (serpin), sharing about 30% homology in amino acid sequence with other serpins. AT is a complex molecule with multiple biologically important properties. It is a potent anticoagulant that has been demonstrated to provide benefit in animal models and small cohorts of patients with coagulation disorders. AT also has remarkable anti-inflammatory properties, several of which result from its actions in the coagulation cascade. Activated coagulation proteases like activated factor X and thrombin contribute to inflammation; for instance, by the release of pro-inflammatory mediators. Inhibition of these proteases by AT prevents their specific interaction with cells and subsequent reactions. Anti-inflammatory properties of AT independent of coagulation involve direct interactions with cells leading to the release of, for instance, prostacyclin. Binding of AT to a recently identified cellular receptor, syndecan-4, leads to the interference with the intracellular signal induced by mediators like lipopolysaccharides and, thereby, to a down-modulation of the inflammatory response. AT has been shown to be effective in prospective and well-controlled small-scale studies of patients with inflammatory conditions, including sepsis. Although AT did not decrease overall patient mortality in a double-blind, placebo-controlled, phase III trial of patients with sepsis, it is important to note that AT improved the survival of individuals in this study not receiving heparin as a prophylactic regimen, which can be explained by the impaired interaction of AT with its cellular receptor in the presence of heparin, resulting in the reduction of the anti-inflammatory properties. Accordingly, the supplementation of AT without concomitant heparin may be beneficial in disorders with inflammatory characteristics, which has to be demonstrated in further clinical studies. Finally, recent results suggest that latent AT can induce apoptosis of endothelial cells by disrupting cell-matrix interactions. Further investigations will have to demonstrate whether latent and/or cleaved AT are physiological means to control angiogenesis. A potential prophylactic or therapeutic use as an anti-angiogenic and antitumor agent merits further exploration, including whether the growth of vessels in tumor tissues or close to tumors can be controlled by latent AT without affecting the formation of blood vessels during wound healing processes.
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PMID:Antithrombin: a new look at the actions of a serine protease inhibitor. 1244 4

Antithrombin (AT) supplementation in patients with severe sepsis has been shown to improve organ failures in which activated leukocytes are critically involved. However, the precise mechanism(s) for the therapeutic effects of AT is not well understood. We examined in rats whether AT reduces ischemia/reperfusion (I/R)-induced renal injury by inhibiting leukocyte activation. AT markedly reduced the I/R-induced renal dysfunction and histologic changes, whereas neither dansyl glutamylglycylarginyl chloromethyl ketone-treated factor Xa (DEGR-F.Xa), a selective inhibitor of thrombin generation, nor Trp49-modified AT, which lacks affinity for heparin, had any effect. Renal tissue levels of 6-keto-PGF(1 alpha), a stable metabolite of prostacyclin (PGI(2)), increased after renal I/R. AT enhanced the I/R-induced increases in renal tissue levels of 6-keto-PGF(1 alpha), whereas neither DEGR-F.Xa nor Trp49-modified AT had any effect. AT significantly inhibited I/R-induced decrease in renal tissue blood flow and the increase in the vascular permeability. Ischemia/reperfusion-induced increases in renal tissue levels of tumor necrosis factor-alpha, cytokine-induced neutrophil chemoattractant, and myeloperoxidase were significantly inhibited in animals given AT. Pretreatment of animals with indomethacin reversed the effects induced by AT. Iloprost, an analog of PGI(2), produced effects similar to those induced by AT. These observations strongly suggest that AT reduces the I/R-induced renal injury by inhibiting leukocyte activation. The therapeutic effects of AT might be mainly mediated by PGI(2) released from endothelial cells through interaction of AT with cell surface glycosaminoglycans.
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PMID:Antithrombin reduces ischemia/reperfusion-induced renal injury in rats by inhibiting leukocyte activation through promotion of prostacyclin production. 2354 58

As a result of advanced technology, dramatic developments in the area of new anticoagulant and antithrombotic drugs appear to have made a profound impact on the use of LMWHs. Furthermore, because porcine mucosal heparin is used for the preparation of these agents, it is likely that alternative drugs with comparable pharmacologic and clinical efficacy are sought. Antithrombin drugs such as argatroban and hirudin are already approved for alternative management of heparin-compromised patients. Their efficacy in other indications is less superior. The development of specific anti-Xa drugs is slow. Although these agents may inhibit factor Xa and thrombin generation, none of them are capable of mimicking the polytherapeutic effects of LMWHs and thus can only be given in drug combinations. Synthetic and recombinant protein-derived anti-tissue factor agents have also been developed. These drugs only inhibit the tissue factor-mediated process and are limited in their therapeutic spectrum. Plasma-derived and recombinant serine protease inhibitors (serpins) are also available for the management of thrombotic and inflammatory disorders, but these agents cannot be given subcutaneously. Furthermore, because they are proteins, antibodies to these agents are generated. Nucleic acid derivatives (natural and synthetic aptomers) are developed for intravenous administration, but they are relatively weak antithrombotic agents. Dermatans, heparans, and chondroitin sulfates represent nonheparin GAGs, and, in mono-compositional and polycompositional form, these drugs are mainly used for the intravenous management of DVT prophylaxis. They can be given to patients who are heparin compromised. Synthetic heparinomimetics include heparin consensus-binding oligosaccharides and synthetic oligosaccharides with non-serpin affinity. In addition, binding oligosaccharides are conjugated with antithrombin agents to mimic the anti-Xa/anti-IIa activities of heparin. Biotechnology using bacterial and yeast cultures, aqua cultures for marine products, and plant carbohydrates have been the focus of developing heparin analogues. Development of these agents is in the early phase; however, it is likely that this approach may provide a reasonable alternative to LMWHs. Despite these developments, it is unlikely that any of these drugs will have a profound impact on the use of LMWHs in the near future. Unfractionated heparin and LMWHs collectively represent an important group of polypharmacologic drugs without which the management of thrombosis and vascular disorders would not be possible. The continual development of LMWHs in expanded indications did not comprise the use of unfractionated heparin in surgical and interventional cardiovascular indications. Ever since their introduction in the 1980s, the use of LMWHs has continually increased. This is primarily because of expanded indications and growing awareness among the clinicians. It is likely that once an antidote is developed and additional information is available on the mechanism of action of LMWHs, these drugs may gradualty be used for surgery patients. Despite these developments, it is likely that unfractionated heparin will continue to be used for specific indications. Drug combinations with heparins may necessitate dose adjustments, but it is unclear whether unilateral reduction of heparins will be optimal. The coming years will provide useful clinical and applied data on the improved use of unfractionated heparin. LMWHs, and pentasaccharide in the management of thrombotic and cardiovascular disorders. In addition, use of these drugs will be extended to many conditions, including cancer, inflammation, sepsis, and autoimmune diseases. Polytherapeutic approaches emphasizing LMWHs as primary and secondary drugs will also have an impact on the management of thrombotic and nonthrombotic disorders. Ultra-LMWHs and synthetic heparinomimetics, such as fondaparinux, that exhibit a narrow pharmacologic spectrum will only be useful in specific indications and in combination with other drugs.
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PMID:Heparin, low-molecular-weight heparins, and heparin pentasaccharide: basic and clinical differentiation. 1262 73

Circulating endotoxin is elevated in sepsis and plays a role in endothelial dysfunction whereas antithrombin is decreased by virtue of its consumption during complex formation with clotting factors and by proteolytic degradation by granulocyte elastase. Dysfunction of endothelium results in enhanced leukocyte rolling and diapedesis into tissues leading to edema formation and injury. Antithrombin exerts beneficial effects on endothelial function in sepsis. A direct anti-inflammatory action of anti-thrombin in inflammatory cells is exerted via heparan sulfate proteoglycans. In this study, we investigated whether antithrombin affects endotoxin-induced adhesion of neutrophils to human endothelial cells in vitro and whether glycosaminoglycans are involved in its signaling. Adhesion of human neutrophils to monolayers of umbilical vein endothelial cells was tested under static conditions. Endothelial cells were pretreated with endotoxin, interleukin-1, heparinase-I, chondroitinase-ABC or anti-syndecan-4-antibody. Endotoxin and interleukin-1 increased neutrophil adherence to human umbilical vein endothelial cells which was inhibited by antithrombin. Concomitant incubation with pentasaccharide abolished this effect of antithrombin. Treatment of endothelial cells with heparinase or chondroitinase led to higher adhesion and prevented effects of antithrombin. With antibodies to syndecan-4, enhanced adhesion of neutrophils was observed. As studied by Western blotting, endotoxin-induced signaling was diminished by antithrombin and the effect was reversible by chondroitinase or heparinase. From our results, we can conclude that endotoxin-induced adhesion of leukocytes to endothelium can be reversed by ligation of syndecan-4 with antithrombin's heparin-binding site and interferences with stress response signaling events in endothelium.
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PMID:Syndecan-4-dependent signaling in the inhibition of endotoxin-induced endothelial adherence of neutrophils by antithrombin. 1465 50

Hypercoagulability is widely associated with sepsis, inflammation, diabetes, cancers, aging, and many pathological conditions, resulting in life-threatening disseminated intravascular coagulation (DIC), venous thrombosis, thromboembolism, cardiovascular complications, or even deadly multiple organ failure. Relieving coagulation dysfunction is not only a task for research scientists but also a challenge for physicians. The development of effective anticoagulants is under way with the basic understanding of the pathophysiology of hypercoagulable state. In this overview, various anticoagulants will be discussed according to the proposed inhibitory target-sites along the extrinsic pathway that is believed to play an integral role in homeostasis. Anticoagulants generally fall into two broad categories as natural or pharmacological ones. Antithrombin (AT), activated protein C (APC), and tissue factor pathway inhibitor (TFPI) mainly constitute the natural anticoagulant system apart from the recently reported physiological components such as lipoproteins, sphingosine, thrombomodulin (TM) or cellular Marcks protein. Pharmacological anticoagulants include warfarin, FVIIa inhibitors, FXa inhibitors, and thrombin inhibition by its direct inhibitors or heparins. In addition, a group of novel compounds inhibiting TF-dependent FVII activation result in anticoagulation; such upstream downregulation in the extrinsic pathway awaits further research to establish their in vivo benefits. The molecular genetic approaches such as developing soluble TF, FVII and thrombin mutants provide unique downregulation. Anticoagulation also extends its significance to anti-inflammation, making broad impacts on the improvement of human health.
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PMID:Biochemical strategies to anticoagulation: a comparative overview. 1532 Aug 20


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