Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0243026 (sepsis)
 52,417 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Disseminated intravascular coagulation (DIC) is an acquired syndrome characterized by intravascular fibrin formation occurring in the course of a variety of severe diseases. In gram-negative sepsis, endotoxin is the bacterial component eliciting a cascade of tissue factor dependent hypercoagulable reactions mediated by cytokines, including tumor necrosis factor-alpha and interleukin-6. Fibrinolysis is activated in this process by the action of tumor necrosis factor-alpha, but its activity is impaired by the predominant inhibitory effect of plasminogen activator inhibitor-1. Natural inhibitory mechanisms include antithrombin, the protein C system, and tissue factor pathway inhibitor. Each of these defense systems counteracts the harmful effects of DIC, and its acquired deficiency is associated with increased mortality in observational studies. The generation of several proteases in DIC, including factor Xa and thrombin, has potential interactions with inflammatory pathways that may potentiate the systemic inflammatory syndrome that often accompanies DIC. Experimental studies support the notion that defects in the protein C pathway modulate the inflammatory response, and illustrate that coagulation and inflammation are coupled systems in DIC.
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PMID:Pathophysiology of disseminated intravascular coagulation in sepsis. 1100 90

Protease-activated receptor-2 (PAR-2) and/or effector cell protease receptor-1 (EPR-1) may mediate the direct cellular actions of coagulation factor Xa in some cultured cell lines. The present study examined if factor Xa could actually evoke relaxation through either of these receptor systems in isolated rat aorta. Factor Xa at 8.5-85 nM, like the PAR-2-activators trypsin and SLIGRL-NH(2), produced nitric oxide-dependent relaxation in the precontracted aortic rings. PAR-2 desensitization abolished relaxation responses to factor Xa as well as trypsin in the rings. The factor Xa interepidermal growth factor synthetic peptide L(83)FTRKL(88)(G)-NH(2), known to block factor Xa binding to EPR-1, failed to inhibit factor Xa-evoked relaxation in the preparations. Our findings provide evidence that factor Xa evokes relaxation by activating PAR-2, but independently of EPR-1, in the rat aorta. The factor Xa-PAR-2 pathway might thus contribute to the severe hypotension during sepsis, in which multiple coagulation factors including factor X would become activated and PAR-2 would be induced.
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PMID:Factor Xa-evoked relaxation in rat aorta: involvement of PAR-2. 1140 77

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

Human tissue factor pathway inhibitor (TFPI) is a modular protein comprised of three Kunitz type domains flanked by peptide segments that are less structured. The sequential order of the elements are: an N-terminal acidic region followed by the first Kunitz domain (K1), a linker region, a second Kunitz domain (K2), a second linker region, the third Kunitz domain (K3), and the C-terminal basic region. The K1 domain inhibits factor VIIa complexed to tissue factor (TF) while the K2 domain inhibits factor Xa. No direct protease inhibiting functions have been demonstrated for the K3 domain. Importantly, the Xa-TFPI complex is a much more potent inhibitor of the VIIa-TF than TFPI by itself. Furthermore, the C-terminal basic region of TFPI is required for rapid physiologic inhibition of coagulation and is needed for the inhibition of smooth muscle cell proliferation. Although a number of additional targets for attachment have been reported, the C-terminal basic region appears to play an important role in binding of TFPI to cell surfaces. A primary site of TFPI synthesis is endothelium and the endothelium-bound TFPI contributes to the antithrombotic potential of the vascular endothelium. Further, increased levels of plasma TFPI under septic conditions may represent endothelial dysfunction. We have proposed that the extravascular cells that synthesize TF also synthesize TFPI providing dual components necessary for the regulation of clotting in their microenvironment. Like the TF synthesis in these cells is augmented by serum, so is the case with the TFPI gene expression. TFPI gene knock out mice reveal embryonic lethality suggesting a possible role of this protein in early development. Since TF-induced coagulation is thought to play a significant role in many disease states, including disseminated intravascular clotting, sepsis, acute lung injury and cancer, recombinant TFPI may be a beneficial therapeutic agent in these disease states to attenuate pathologic clotting. The purpose of this review is to outline recent developments in the field related to the structural specificity and biology of TFPI.
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PMID:Structure and biology of tissue factor pathway inhibitor. 1168 53

Anticoagulants have gained increasing attention in the treatment of sepsis. This study used danaparoid to investigate the role of factor Xa in endotoxin-induced coagulation and inflammation and its effectiveness when coagulation activation has already occurred. Thirty healthy volunteers were enrolled in the randomized, placebo-controlled trial. Subjects received 2 ng/kg endotoxin and danaparoid 10 min or 3 h thereafter or placebo. Endotoxin increased prothrombin fragment 1+2 (F(1+2)) levels from 0.5 to 7.0 nmol/L at 5 h in the placebo group. Early danaparoid infusion inhibited endotoxin-induced thrombin formation: maximum F(1+2) levels reached only 1.8 nmol/L (P<.01, vs. baseline or placebo). Delayed danaparoid infusion effectively blocked further thrombin formation. However, danaparoid did not alter endotoxin-induced changes in the fibrinolytic system, cytokine levels, activation of leukocytes, or tissue factor expression on monocytes. Danaparoid therefore selectively attenuates endotoxin-induced coagulopathy, even with delayed administration when coagulation activation is well under way.
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PMID:Effect of factor X inhibition on coagulation activation and cytokine induction in human systemic inflammation. 1240 96

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

The Kunitz-type proteinase inhibitor, tissue factor pathway inhibitor (TFPI), is the only endogenous inhibitor of the tissue factor (TF)-mediated coagulation pathway that plays a dominant role in normal haemostasis. TFPI exerts its action by binding to factor Xa (FXa) forming a TFPI-FXa complex that then, in a second step, binds and effectively inhibits the TF-factor VIIa (FVIIa) complex. Both full-length TFPI and chemically modified forms (e.g., truncated, glycosylated or phosphorylated TFPI variants) exert various pharmacological effects. The anticoagulant and antiplatelet actions of TFPI, its potency in inhibiting thrombin and FXa generation, as well as its favourable antithrombotic effectiveness seen in different animal models of venous and arterial thrombosis make this inhibitor a promising agent that could be potentially useful in several clinical indications. The inhibitory action of TFPI is accelerated by heparin. Heparin, as well as low molecular weight heparin (LMWH) derivatives, release TFPI from the vascular endothelium, an effect which seems to contribute mainly to the antithrombotic effectiveness of these drugs. The clinical relevance of TFPI is still undefined. Based on the beneficial actions in animal studies, as well as on the results obtained in first clinical investigations, TFPI is expected to be effective in the treatment of various diseases, such as disseminated intravascular coagulation, sepsis, coronary syndromes, stroke and acute respiratory distress syndrome (ARD). Further clinical trials should clarify the role of TFPI and more importantly define its potential usefulness as a prophylactic and/or therapeutic agent.
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PMID:Recombinant TFPI and variants: potential implications in the treatment of cardiovascular disorders. 1599 20

Anticoagulation during renal replacement therapy is recommended to avoid thrombosis of the filter devices and to maintain the blood flow. However, in the case of multiorgan failure and sepsis, an imminent bleeding complication in patients with acute renal failure may cause the need for an extracorporeal circulation without anticoagulation. The most common drug used in renal replacement therapy is the unfractionated heparin (UFH). With low molecular weight heparin (LMWH) good experiences are reported, too. Based on the level of evidence from clinical studies plasma measurement of heparin is indispensable for patients with renal insufficiency. The activated whole blood clotting time (ACT), the activated partial thromboplastin time (aPTT), and the determination of the anti-factor Xa activity (anti Xa) with chromogenic substrates are available as routine as well as as point-of-care tests. To monitor plasma levels of LMWH the anti Xa assay serves exclusively as a suitable monitoring. The anti Xa assay using chromogenic substrates is the most specific and valid one for monitoring heparin therapy. In lack of large controlled studies for the anticoagulation therapy and its monitoring with the anti Xa test in acute renal failure, the current experiences are based on the results of chronic renal replacement therapy.
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PMID:[Monitoring of the heparin therapy during acute haemodialysis]. 1611 51

World wide, heparins are the most commonly used anticoagulants for renal replacement therapy (RRT). In the intensive care unit (ICU) keeping the RRT circuit patent is more difficult than during routine outpatient hemodialysis, as ICU patients typically have sepsis and/or inflammation resulting in activation of the procoagulant pathways, with reduced antithrombin. One important cause of repeated RRT circuit clotting is heparin-induced thrombocytopenia (HIT), which should not be overlooked in patients with a reduced platelet count. If HIT is clinically suspected then all heparins should be withdrawn, and the patient systemically anticoagulated with either a direct thrombin inhibitor, such as argatroban and/or hirudin, or the heparinoid danaparoid. The availability and licensing of these alternative anticoagulants varies from country to country. Argatroban has to be continuously infused, which is an advantage for continuous RRT, but not for intermittent RRT, and can be monitored by activated partial thromboplastin time. Hirudin has a prolonged half life, which is extended by hirudin antibodies, and requires specialist monitoring to prevent over anticoagulation. Although the half life of danaparoid is increased in renal failure, it can be given as boluses for intermittent and continuous RRT, or by continuous infusion during continuous RRT, but requires factor Xa monitoring.
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PMID:Anticoagulation options for patients with heparin-induced thrombocytopenia requiring renal support in the intensive care unit. 1746 35


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