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Disease
Symptom
Drug
Enzyme
Compound
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Target Concepts:
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Query: UMLS:C0012739 (
disseminated intravascular coagulation
)
8,673
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We measured concentrations of the natural anticoagulant protein C; its cofactor, protein S; and the carrier protein
C4b-binding protein
(
C4BP
), in 24 patients with severe infection and 13 with septic shock. Decreased antithrombin III levels were found in 16 of 24 infection patients and all shock patients; high thrombin-antithrombin (TAT) complexes were present in 16 of 24 infection and 12 of 13 shock patients. Protein C concentrations were significantly reduced compared to healthy blood donors, to 60 +/- 14% (infection) and 47 +/- 20% (septic shock) (mean +/- 1 SD). Total protein S levels were not reduced (119 +/- 36.7 and 88 +/- 20.0%, normal value 96 +/- 15%). Free protein S was also normal (27 +/- 9.4 and 30 +/- 8.7%, normal value 29 +/- 9%). The percentage free of total protein S was normal in shock patients (35 +/- 8.5%), but significantly reduced in patients without shock (23 +/- 5.3%).
C4BP
was significantly higher than normal in the latter group (135 +/- 43%), but not in the shock group (118 +/- 40%), possibly due to increased consumption. Thus, no deficiency of total or free protein S was found in these patients, who had evidence of activated coagulation but no clinical
DIC
.
...
PMID:Protein C, protein S and C4b-binding protein in severe infection and septic shock. 182 15
Patients with acute leukemia undergoing remission induction chemotherapy occasionally develop venous thrombosis despite severe thrombocytopenia and in the absence of
disseminated intravascular coagulation
. This observation prompted us to study the levels of the naturally occurring anticoagulant proteins C and S prospectively in patients undergoing remission induction chemotherapy for acute leukemia. Plasma samples from 50 adult patients with acute leukemia (34 AML, 16 ALL) were analyzed for protein C antigen, functional protein C, immunologic total and free protein S as well as levels of
C4b
binding protein (C4bBP). Plasma levels of immunologic protein C were significantly lower in patients with active acute myelocytic leukemia (mean = 77.9) than in controls (mean = 123.6) or patients in remission (mean = 132). Functional protein C levels were also significantly lower in AML patients with active disease (mean = 58.5) than controls (mean = 95.5) or patients in remission (mean = 98.5). Patients with acute lymphocytic leukemia (ALL) had normal levels of immunologic and functional protein C. Although total protein S levels were normal in all patients studied, levels of free protein S were significantly decreased in patients with active AML (mean = 29.3) compared with patients in remission (mean = 42.0) or controls (mean = 42.4). In contrast, patients with ALL, both with active disease and in remission had normal free protein S levels. This decrease in free protein S seen in active AML was not associated with liver disease, white cell count or an increase in C4bBP. These findings provide a possible explanation for the occasional occurrence of venous thrombosis in patients with acute myelocytic leukemia.
...
PMID:Protein C and S levels in acute leukemia. 183 Apr 52
Plasma levels of protein S (PS) antigen, both total and free fractions, were measured together with
C4b-binding protein
(
C4bp
) and protein C (PC) antigen in 39 patients with
disseminated intravascular coagulation
(
DIC
), 34 with liver disease, 17 with collagen disease, 17 with diabetes mellitus, and 51 under stabilized warfarin treatment. In patients with
DIC
, mean concentrations of total PS and free PS were normal, while PC was reduced and
C4bp
were elevated. Total PS, free PS,
C4bp
and PC were all decreased in liver disease, elevated in diabetes mellitus, and normal in collagen disease. In warfarin-treated patients, total PS, free PS and PC were moderately decreased, but the decrease in
C4bp
was minimal. The concentration of PS correlated positively with PC in liver disease, diabetes mellitus, and during oral anticoagulation, but did not in
DIC
. These results indicate that PS and PC behave similarly when liver synthetic function is principally affected, but in contrast to PC, PS is hardly consumed during intravascular coagulation.
...
PMID:Plasma protein S in disseminated intravascular coagulation, liver disease, collagen disease, diabetes mellitus, and under oral anticoagulant therapy. 252 31
Proteins C and S are two vitamin K-dependent plasma proteins that work in concert as a natural anticoagulant system. Activated protein C is the proteolytic component of the complex and protein S serves as an activated protein C binding protein that is essential for assembly of the anticoagulant complex on cell surfaces. The anticoagulant activity is expressed through the selective inactivation of Factors Va and VIIIa. Many patients deficient in proteins C and S have been described and have an associated thrombotic tendency, but not all heterozygous protein C and S deficient individuals experience thrombotic complications. Multiple mechanisms and/or drugs can lead to acquired deficiencies of these proteins: oral anticoagulation, liver disease,
DIC
and in the case of protein S, lupus erythematosus, nephrotic syndrome, pregnancy and certain hormones. The anticoagulant activity of protein C decreases rapidly after administration of warfarin (i.e., with a time course similar to Factor VII). This rapid decrease may lead to a transient imbalance and contribute to coumarin induced skin necrosis. Protein S antigen levels do not decrease as rapidly, but protein S functional levels are often low in patients with an acute thrombus. The discrepancy between antigen and function results from elevations in
C4b-binding protein
, which complexes reversibly with protein S. Unlike free protein S, the complex does not function in the anticoagulant pathway. The available information all suggest that deficiency of protein C and protein S should be considered a risk factor contributing to recurrent thrombotic disease and that the function of these proteins is altered by many common clinical conditions which have associated an increased risk of thrombosis.
...
PMID:Anticoagulation proteins C and S. 295 34
Protein S, an important cofactor of activated protein C, and
C4b-binding protein
were purified from human plasma. Specific antibodies against the purified proteins were raised in rabbits and used for the development of immunologic assays for these proteins in plasma: an immunoradiometric assay for protein S (which measures both free protein S and protein S complexed with
C4b-binding protein
) and an electroimmunoassay for
C4b-binding protein
. Ranges for the concentrations of these proteins were established in healthy volunteers and patients using oral anticoagulant therapy. A slight decrease in protein S antigen was observed in patients with liver disease (0.78 +/- 0.25 U/ml); no significant decrease in protein S was observed in patients with
DIC
(0.95 +/- 0.25 U/ml). Criteria were developed for the laboratory diagnosis of an isolated protein S deficiency.
...
PMID:Determination of plasma protein S--the protein cofactor of activated protein C. 316 Dec 6
Protein S is a vitamin K-dependent plasma protein which serves as the cofactor for activated protein C. Protein S circulates in both an active, free form and in an inactive complex with
C4b-binding protein
. To elucidate the role of protein S in disease states and during oral anticoagulation, we developed a functional assay for protein S that permits evaluation of the distribution of protein S between free and bound forms and permits determination of the specific activity of the free protein S. In liver disease, free protein S antigen is moderately reduced and the free protein S has significantly reduced specific activity. In
disseminated intravascular coagulation
, reduced protein S activity occurs due to a redistribution of protein S to the inactive bound form. During warfarin anticoagulation, reduction of free protein S antigen and the appearance of forms with abnormal electrophoretic mobility significantly decrease protein S activity. After the initiation of warfarin, the apparent half-life of protein S is 42.5 h. In patients with thromboembolic disease, transient protein S deficiency occurs due to redistribution to the complexed form. Caution should be exercised in diagnosing protein S deficiency in such patients by use of functional assays.
...
PMID:Acquired deficiencies of protein S. Protein S activity during oral anticoagulation, in liver disease, and in disseminated intravascular coagulation. 328 13
This review presents the rationale for and main results of coagulation inhibitor substitution during experimental and human sepsis. Activation of the contact system induces activation of the classical complement pathway with generation of anaphylatoxins, of the kinins pathway and of fibrinolysis. Physiologic inhibition depends on the C1-inhibitor (C1-Inh.). Septic patients exhibit a relative deficiency of biologically active C1-Inh. Substitution with concentrations of C1-Inh has been safely performed and preliminary results are consistent with a possible beneficial effect on hypotension and vasopressor requirement in septic shock. The extrinsic pathway is the main initial coagulation process involved in sepsis-induced
DIC
. Endothelial and monocyte generation of tissue factor (TF) is activated by bacterial products and endotoxin. Activation of TF is counteracted by a specific tissue factor pathway inhibitor (TFPI). The potential for TFPI substitution to inhibit the activation of the coagulation cascade in sepsis requires further study. Thrombin generation is inhibited by antithrombin III (AT III) and the protein C-protein S system. During sepsis, AT III is consumed and degraded by elastase. Animal studies have shown that
DIC
and death were prevented by high doses of AT III concentrates. Although a significant reduction in the duration of biological symptoms of
DIC
has been reported in most human studies, the usefulness of AT III substitution in human sepsis is still debated. None of the studies was able to document a statistically significant reduction in mortality. Protein C is activated by thrombomodulin and, with its cofactor protein S, inhibits factors Va and VIIIa. The free level of protein S depends on the level of the
C4b
binding protein (C4bBP), an acute-phase complement regulatory protein. During sepsis, protein C activity is significantly reduced, either by acute consumption or by thrombomodulin down-regulation, and increased levels of plasma C4bBP inhibit protein S. Infusion of activated protein C and protein S substitution both protect animals from the lethal effects of bacteria. Combining these different coagulation inhibitors should be carefully studied before its use in septic patients is recommended.
...
PMID:Coagulation inhibitor substitution during sepsis. 863 34
We evaluated the effect of C1 inhibitor (C1-inh), an inhibitor of the classical pathway of complement and the contact system, on the physiologic and inflammatory response in baboons suffering from lethal Escherichia coli sepsis. Five animals pretreated with 500 U/kg C1-inh (treatment group; n = 5), followed by a 9-h continuous infusion of 200 U/kg C1-inh subsequent to bacterial challenge, were compared with five controls receiving E. coli alone. Of the treatment group, one animal survived and another lived beyond 48 h, whereas all control animals died within 27 h. In four of five treated animals, less severe pathology was observed in various target organs. C1-inh administration did not prevent the hemodynamic or hematologic changes observed upon E. coli infusion. The activation of fibrinolysis and the development of
disseminated intravascular coagulation
were essentially unaffected by C1-inh. However, C1-inh supplementation significantly reduced decreases in plasma levels of factor XII and prekallikrein and abrogated the systemic appearance of
C4b
/c, indicating substantial inhibition of activation of the contact system and the classical complement pathway, respectively. Furthermore, treated animals displayed a reduced elaboration of various cytokines including TNF, IL-10, IL-6, and IL-8. Thus, the administration of C1-inh may have a beneficial but modest effect on the clinical course and outcome of severe sepsis in nonhuman primates. We suggest that activated complement and/or contact system proteases may, at least in part, contribute to the attendant manifestations of septic shock through an augmentation of the cytokine response.
...
PMID:Effect of C1 inhibitor on inflammatory and physiologic response patterns in primates suffering from lethal septic shock. 955 6
Previous studies suggest that there is a systemic activation of clotting and fibrinolysis in preterm infants with advanced respiratory distress syndrome (RDS). However, there are no data on the hemostatic status in the early stages of the disease; therefore, we studied some of the hemostatic parameters in these patients and made several studies at different times in preterm infants who did or did not develop RDS, using similar protocols. We found normal plasma fibrinogen, protein C, protein S,
C4b-binding protein
, thrombomodulin, antithrombin III, thrombin-antithrombin III complex, prothrombin fragment 1.2, plasminogen, tissue plasminogen activator, alpha-1 antitrypsin, alpha-2-macroglobulin and protein Z. However, lower D-dimer and higher plasminogen activator inhibitor and von Willebrand factor antigen levels were found within six hours of life in infants who later developed RDS compared to the control group. These findings suggest that
disseminated intravascular coagulation
is not prominent in the early stages of RDS. Moreover, reduced D-dimer and increased plasminogen activator inhibitor and von Willebrand factor antigen levels are probably related to the abnormalities in the fibrinolytic mechanism due to lung damage in RDS, but further studies are needed to show their pathogenic significance in RDS.
...
PMID:Hemostatic system in early respiratory distress syndrome: reduced fibrinolytic state? 1077 Jan 17
Collectin-11 (CL-11) is a pattern recognition molecule of the lectin pathway of complement with diverse functions spanning from host defense to embryonic development. CL-11 is found in the circulation in heterocomplexes with the homologous collectin-10 (CL-10). Abnormal CL-11 plasma levels are associated with the presence of
disseminated intravascular coagulation
, urinary schistosomiasis, and congenital disorders. Although there has been a marked development in the characterization of CL-11 there is still a scarcity of clinical tools for its analysis. Thus, we generated monoclonal antibodies and developed a quantitative ELISA to measure CL-11 in the circulation. The antibodies were screened against recombinant CL-11 and validated by ELISA and immunoprecipitation of serum and plasma. The best candidates were pairwise compared to develop a quantitative ELISA. The assay was validated regarding its sensitivity, reproducibility, and dilution linearity, demonstrating a satisfactory variability over a working range of 0.29-18.75 ng/ml. The mean plasma concentration of CL-11 in healthy controls was determined to be 289.4 ng/ml (range 143.2-459.4 ng/ml), highly correlated to the levels of CL/10/11 complexes (
r
= 0.729). Plasma CL-11 and CL-10/11 co-migrated in size exclusion chromatography as two major complexes of ~400 and >600 kDa. Furthermore, we observed a significant decrease at admission in CL-11 plasma levels in patients admitted to intensive care with systemic inflammatory response syndrome. By using the in-house antibodies and recombinant CL-11, we found that CL-11 can bind to zymosan independently of calcium by a separate site from the carbohydrate-binding region. Finally, we showed that CL-11/MASP-2 complexes trigger
C4b
deposition on zymosan. In conclusion, we have developed a specific and sensitive ELISA to investigate the ever-expanding roles of CL-11 in health and disease and shown a novel interaction between CL-11 and zymosan.
...
PMID:Development of a Quantitative Assay for the Characterization of Human Collectin-11 (CL-11, CL-K1). 3032 15
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