Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

---

Query: UMLS:C0409974 (lupus)
22,386 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We examined thrombophilic mechanisms and outcome in 54 patients with deep-vein thrombosis (DVT), who were otherwise apparently healthy and aged < or = 50 years. Patients were followed up 6 years (median) after a confirmed first DVT between 1987-1992 with no known predisposing illnesses. Patients were traced through the hospital registry and compared with 25 matched controls. Tested thrombophilic mechanisms were either genetic (activated protein C [APC] resistance; anti-thrombin III deficiency [ATIII]; protein C or protein S deficiency [PC, PS]) or acquired (lupus anti-coagulant [LAC]/anti-cardiolipin antibodies [ACA]; subsequent diagnosis of cancer). Twenty-nine DVT patients attended for full studies. The remaining 25 were interviewed by phone and none had a reported neoplastic disease, confirmed by their hospital records and the National Cancer Registry. These patients' demographics, risk factors and subsequent course were similar in all respects to the studied group. In the control group, APC resistance was the only coagulopathy found (1/25, 4%), and it was also the most common abnormality among DVT patients (8/29, 28%) (p = 0.009). Three DVT patients had LAC/ACA (10%) and one each, ATIII, PC and PS deficiencies (3.3% each). No malignancy was encountered during a follow-up of 7.9 +/- 5.7 years. Circumstantial risk factors were found in 52% of the patients, 21% had a family history of DVT, and 41% had recurrent DVT. These characteristics were not significantly different when DVT patients with and without coagulopathy were compared.
...
PMID:Causes and outcome of deep-vein thrombosis in otherwise-healthy patients under 50 years. 930 63

Antiphospholipid-protein antibodies (APA) include lupus-type anticoagulant (LA) and antibodies recognizing complexes of anionic phospholipids (e.g. cardiolipin) and proteins (e.g. prothrombin and beta2-glycoprotein I). The presence of APA is associated with an increased risk of both arterial and venous thrombosis. However, the pathogenic mechanism leading to thrombosis in patients with APA remains unclear. We studied 32 patients with systemic lupus erythematosus (SLE) who were divided into two groups depending on the presence (n = 19) or absence (n = 13) of APA. Healthy volunteers (n = 12) matched by age and sex served as controls. In all subjects LA and IgG class anticardiolipin antibodies (ACA) were determined. Thrombin generation was monitored ex vivo measuring fibrinopeptide A (FPA) and prothrombin fragment F1 + 2 (F1 + 2) in blood emerging from a skin microvasculature injury, collected at 30 second intervals. In subjects with antiphospholipid antibodies mean FPA and F1 + 2 concentrations were significantly higher at most blood sampling times than in controls. In some SLE patients with APA the process of thrombin generation was clearly disturbed and very high concentrations of fibrinopeptide A were detected already in the first samples collected. Two minutes after skin incision SLE patients without APA produced slightly more FPA, but not F1 + 2, as compared to healthy subjects. Mathematical model applied to analyze the thrombin generation kinetics revealed that APA patients generated significantly greater amounts of thrombin than healthy controls (p = 0.02 for either marker). In contrast, in the same patients generation of thrombin in recalcified plasma in vitro was delayed pointing to the role of endothelium in the phenomenon studied. In summary, these data show for the first time that in SLE patients with antiphospholipid-protein antibodies thrombin generation after small blood vessel injury is markedly increased. Enhanced thrombin generation might explain thrombotic tendency observed in these patients.
...
PMID:Thrombin generation measured ex vivo following microvascular injury is increased in SLE patients with antiphospholipid-protein antibodies. 936 80

Snake venom toxins have an established role in the coagulation laboratory for the assay of haemostatic parameters and a potential role for therapeutic treatment of thrombotic disorders. In the laboratory, snake venom thrombin-like enzymes (SVTLEs) are used for the assay of fibrinogen and detection of fibrinogen breakdown products and dysfibrinogenaemias. Importantly, because SVTLEs are not inhibited by heparin, they can be used for assaying antithrombin III and other parameters in samples which contain heparin. Prothrombin activators occur in many snake venoms and these have become established in the assay of prothrombin, in the study of dysprothrombinaemias and in the preparation of meizothrombin and non enzymic forms of prothrombin. Russell's viper (Daboia russelli) venom contains a number of useful compounds including toxins which can be used to assay blood clotting factors V, VII, X, platelet factor 3 and lupus anticoagulants (LA). More recently, activators from the taipan, Australian brown snake and saw-scaled viper have been used to assay LA. Proteins C and S can be measured by means of protac, a fast acting inhibitor from Southern copperhead snake venom and von Willebrand factor can be studied with botrocetin from Bothrops jararaca venom. The disintegrins, a large family of Arg-Gly-Asp (RGD)-containing proteins found in snake venoms, show great potential for the study of platelet glycoprotein receptors, notably, GPIIb/IIIa and Ib, and in the treatment of arterial thrombotic disease. Established SVTLEs used in clinical practice include ancrod and defibrase although success with these agents has been limited. A further group of enzymes under consideration as thrombolytic agents are the fibrinogenases.
...
PMID:Practical applications of snake venom toxins in haemostasis. 942 23

In order to clarify the coagulation profile accompanying ischemic stroke, which may have implications on therapeutic strategies, we performed a prospective study to evaluate the hemostatic parameters in the first 24 h after the onset of cortical atherothrombotic infarct and lacunar infarction. Twenty-seven patients with cortical atherothrombotic infarction and 27 patients with lacunar infarction, diagnosed on clinical and CT-scan criteria, had blood samples taken within the first 24 h after onset of the stroke, and before anticoagulant treatment had been started. Levels of fibrinogen, von Willebrand factor, D-dimers, prothrombin factors 1 + 2, anti-thrombin III, and C-protein and S-proteins, were measured. Laboratory tests detected the following abnormalities: a protein C deficiency was observed in 1 case of cortical infarction and in 1 case of lacunar infarction; a decrease in S-protein was observed in 1 case of cortical infarction, and the presence of lupus anticoagulant in 4 cases (2 in cortical and 2 in lacunar infarction). Various degrees of coagulation activation were observed. Statistically significant activation of the coagulation was observed in the patients with cortical infarction, compared to normal patients adjusted for age: the levels of DDI were significantly raised (2298 +/- 2221 ng ml-1 vs. 750 +/- 400 ng ml-1) (p < 0.03) as were F1 + 2 levels (3.9 +/- 2.8 nmol l-1 vs. 1.5 +/- 0.9 nmol l-1). (p < 0.01). In the lacunar infarction group, there was a significant rise in F1 + 2 compared with normal patients adjusted for age (2.2 +/- 1.7 nmol l-1 vs. 1.5 +/- 0.9 nmol l-1) (p < 0.01), while the DDI level was in the normal range, when age was taken into account. In the cortical infarction group, we observed a significantly raised fibrinogen level (4.8 +/- 1.7 g l-1 vs. 3.7 +/- 1.0 g l-1) (p < 0.05) and von Willebrand factor level (271 +/- 104% vs. 178 +/- 103%) (p < 0.01) compared to the lacunar infarction group. In addition, we observed a significantly low level of S-protein in the cortical infarction group (105 +/- 29%) compared to the lacunar infarction group (127 +/- 28%) (p < 0.01). Confirmation of the role of enhanced thrombin activity in the pathogenesis of acute stroke may be an important determinant in its therapeutic management.
...
PMID:Coagulation abnormalities in lacunar and cortical ischemic stroke are quite different. 947 Oct 97

Antiphospholipid antibodies (aPL) have been found to be associated with arterial and venous thrombosis. Percutaneous transluminal coronary angioplasty (PTCA) is an established therapy for ischaemic heart disease (IHD), which is still affected by restenosis at a rate of 20-30%. This study was aimed at investigating the possible role of aPL in restenosis after PTCA. In sixty consecutive IHD patients, aPL (lupus anticoagulant -LA- and anticardiolipin antibodies -aCL) and markers of haemostatic activation were investigated before PTCA, and patients were followed up for restenosis. No infections, autoimmune disease or treatment by drugs that may alter aPL levels occurred in any of the patients. aPL were found in 15/60 patients: aCL in 7/60, LA in 5/60 and aCL and LA in 3/60. No statistically significant difference was found between aPL negative and aPL positive patients in pre PTCA plasma levels of prothrombin activation fragment (F1+2) 1.4 nmol/l (0.3-5.71) vs 1.4 nmol/l (0.9-4.0), thrombin-antithrombin complex (TAT) 4.0 microg/l (1.1-34.2) vs 5.2 microg/l (2.1-60.0), D-dimer (DD) 25 ng/ml (2-515) vs 44 ng/ml (2-160) or plasminogen activator inhibitor activity (PAI) 4.8 IU/ml (2.5-36.4) vs 4.4 IU/ml (2.5-13.4). Restenosis was observed in 13/60 patients (7/45-15% - aPL negative and 6/15-40% - aPL positive patients) who underwent angiographic tests after PTCA because of recurring angina or positive exercise test. Restenosis occurred after 2.2 months (0.5-3) in aPL positive patients and after 3.5 months (1-12.8) in aPL negative. These results suggest that 1) restenosis with recurrent ischaemia occurs more frequently in aPL positive than in aPL negative patients, 2) in aPL positive patients restenosis occurs earlier, and 3) the presence of aPL is not associated with hypercoagulability.
...
PMID:Antiphospholipid antibodies: a new risk factor for restenosis after percutaneous transluminal coronary angioplasty? 960 31

Snake venom toxins are now regularly used in the coagulation laboratory for assaying haemostatic parameters and as coagulation reagents. Snake venom thrombin-like enzymes (SVTLE) are used for fibrinogen and fibrinogen breakdown product assay as well as detecting dysfibrinogenaemias. Significantly, because SVTLE are not inhibited by heparin, they can be used for defibrinating samples that contain the anticoagulant before assay of haemostatic variables. Prothrombin activators are found in many snake venoms and are used in prothrombin assays, for studying dysprothrombinaemias and preparing meizothrombin and non-enzymic prothrombin. Russell's viper (Daboia russelli) venom (RVV) contains a number of compounds useful in the assay of factors V, VII, X, platelet factor 3 and lupus anticoagulants. Activators from the taipan, Australian brown snake and saw-scaled viper have been used to assay lupus anticoagulants. Protein C and activated protein C resistance can be measured by means of RVV and Protac, a fast acting inhibitor from Southern copperhead snake venom and von Willebrand factor can be studied with Botrocetin from Bothrops jararaca venom. Finally, phospholipase A2 enzymes and the disintegrins, a family of Arg-Gly-Asp (RGD)-containing proteins found in snake venoms, show great potential for the study of haemostasis including, notably, platelet glycoprotein receptors GPIIb/IIIa and Ib.
...
PMID:Use of snake venom fractions in the coagulation laboratory. 971 87

Various coagulation abnormalities were reported in HIV-infected patients. Cases of severe thrombocytopenia were first observed in contaminated homosexual males, as well as prolonged APTT due to the presence of lupus-like anticoagulant with a frequency in the range 8 to 70% of the studied patients. Even if lupus anticoagulant could be evidenced in asymptomatic patients, it frequently occurred during acute opportunistic infections such as Pneumocystis carinii. More recently, increased prevalence of protein S and heparin cofactor II deficiency, two physiological coagulation inhibitors were demonstrated in HIV-infected patients. The same applied for hypoalbuminemia-related fibrin polymerization defects which induced prolonged thrombin and reptilase clotting times. Abnormalities of the fibrinolytic system were also reported, such as increased levels of both tissue-type plasminogen activator and type 1 plasminogen activator inhibitor or decreased levels of histidine-rich glycoprotein. Even if the acute phase response could play a key-role, the pathogenesis of these abnormalities is not fully understood, so far. In addition, their clinical consequences have not been extensively investigated, but hemorrhage appeared to be uncommon. Moreover, D-dimer levels were found increased in HIV-infected patients, suggesting that HIV-infection might be associated with a so-called prethrombotic state, which could lead to clinical thrombosis in some HIV-infected patients (2%).
...
PMID:[Hemostasis and human immunodeficiency virus (HIV) infection]. 975 40

Genetic defects of antithrombin (AT) or one of the components of the protein C pathway are associated with hereditary thrombophilia. Laboratory assays are currently available to diagnose and type hereditary thrombophilia due to deficiency or dysfunction of one of the anticoagulant factors antithrombin (AT), protein C (PC) and protein S (PS), and APC resistance without the need of DNA analysis. There are no functional tests for the prothrombin mutant G20210A and thrombomodulin mutations, which can be diagnosed by a PCR-based test or by gene analysis, respectively. Hereditary AT deficiency is classified in a quantitative type I and three functional type II deficiencies affecting the reactive site (RS), heparin binding site (HBS), or pleiomorphic site of the AT protein. All four types of hereditary AT deficiencies can be diagnosed by a heparin cofactor assay and one immune assay in combination with crossed immunoelectrophoresis of the AT protein. The combination of an enzyme-linked immunoadsorbent assay (ELISA) and a functional Protac-APTT-based assay for PC will detect quantitative type I and dysfunctional type II PC deficiencies. There is a significant overlap in PC antigen and functional levels between heterozygotes of PC deficiency and normals leaving a gray zone of uncertainty in differentiating congenital PC deficiency and normal individuals. Accurate diagnosis of hereditary PS deficiency should be a combination of tests aimed to measure free PS activity and antigen and total PS antigen levels. APTT-, Xa-, and RVVT-based APC-resistance tests, when test plasmas are diluted in factor V deficient plasma, have increased in sensitivity and specificity to 100% for the discrimination of normal individuals from heterozygotes and homozygotes for factor V Leiden. The RVVT-based APC-resistance test provides better separation of factor V Leiden and normals in the various clinical settings, lupus anticoagulant in particular. The modified APC-resistance tests also claim a separation between heterozygotes and homozygotes for factor V Leiden in the normal population, asymptomatic subjects, and thrombosis patients. Below a certain cut-off level, a minor overlap of normalized APC ratios between heterozygotes and homozygotes for factor V Leiden of thrombosis patients has been shown in one study, which still points to the need to perform the more time consuming and expensive DNA test to identify heterozygotes from the more clinically significant homozygotes. The prothrombin-based APC-resistance test, which measures thrombin activated factor Va in highly diluted test plasma, appears to be the most sensitive and specific of all APC-resistance tests and separates normal individuals from heterozygotes and heterozygotes from homozygotes for factor V Leiden without the need of confirmation by a DNA test.
...
PMID:Laboratory diagnosis of hereditary thrombophilia. 976 48

Thrombomodulin (TM), a high affinity thrombin receptor present on endothelial cell membrane, plays an important role as a natural anticoagulant. It acts as a cofactor of thrombin-catalyzed activation of protein C, and inhibits the procoagulant functions of thrombin. TM is also located in other cells (keratinocytes, osteoblasts, macrophages,...) where it might be involved in cell differentiation or in inflammation. In the presence of cytokines, activated neutrophils and macrophages, endothelial TM is cleaved enzymatically, releasing soluble fragments which circulate in the blood and are eliminated in urine. Plasma TM level (pTM) can be measured using a two-site enzyme-linked immunosorbent assay (ELISA). pTM level is regarded as a molecular marker reflecting injury of endothelial cells. It is often increased in case of diffuse endothelial damage as in disseminated intravascular coagulation, diabetic microangiopathy, Plasmodium falciparum and rickettsial infections. pTM is also a predictive marker of hypertensive complications in pregnancy. In several systemic inflammatory diseases, pTM levels are correlated to the activity of the disease.
Lupus 1998
PMID:Thrombomodulin: an overview and potential implications in vascular disorders. 981 88

The protein C pathway plays a critical role in the negative regulation of the blood clotting process. We recently identified an endothelial cell receptor for protein C/activated protein C (APC). The receptor is localized almost exclusively on endothelial cells of large vessels and is present at only trace levels or indeed absent from capillaries in most tissues. Patients with sepsis or lupus erythematosus exhibit elevated levels of plasma EPCR which migrates on gels as a single band and is fully capable of binding protein C/APC. There is no correlation with thrombomodulin levels, probably due to different vascular localizations and/or cellular release mechanisms. To understand the mechanisms by which EPCR plasma levels are elevated, we examined EPCR mRNA expression in a rat endotoxin shock model. The EPCR mRNA gene exhibited an early immediate gene response to endotoxin with the mRNA levels increasing nearly 4 fold in the first 3-6 hrs, before returning toward baseline. Plasma levels of EPCR also rose about 4 fold with little change in tissue EPCR levels. Both processes were markedly attenuated by hirudin suggesting that thrombin was responsible for increases in mRNA and plasma EPCR levels. At the level of mRNA, the induction is mediated by a thrombin response element in the 5' flanking region of the gene. Direct thrombin infusion and cell culture experiments support this contention. On endothelium, thrombin is capable of releasing cell surface EPCR and this process is blocked by the metalloproteinase inhibitor orthophenanthroline. Taken together these studies indicate that elevation in soluble plasma EPCR reflects endothelial cell activation in the larger vessels and is likely to be an indication of local thrombin generation near these vessel surfaces.
...
PMID:Regulation and functions of the protein C anticoagulant pathway. 1019 Sep 52


<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>

---