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Query: UMLS:C0024141 (
systemic lupus erythematosus
)
44,322
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Thrombophilia is characterized by clinical tendency to thrombosis or molecular abnomalities of hemostasis that predisposes to thromboembolic disease. Hereditary thrombophilia may be due to antithrombin deficiency, or protein C or protein S deficiency. More recently, other molecular abnormalities have been described: activated protein C resistance due to factor V Leiden, G 20210 A polymorphism on the prothrombin gene, increased factor VIII plasma levels or
hyperhomocysteinemia
. Acquired thrombophilia is frequently associated with the antiphospholipid syndrome characterized by thrombosis and presence of
lupus
anticoagulant or phospholipid-binding antibodies. In some cases, no molecular abnormality is found despite recurrent thrombosis observed in patient and his/her family. This situation can be considered as clinical thrombophilia.
...
PMID:[Definition of thrombophilia]. 1502 78
The vascular placental pathology (VPP) is associated with many etiologies. Some are the consequence of a maternal genetic or acquired predisposition. Others are associated with a chronic maternal disease (hypertension,
lupus
, obesity, diabetes, ...). Finally, some others are associated with placental implantation leading to fetal ischemia (multiple pregnancy, chorioangioma, primiparity, feto-placental hydrops) or to environmental (altitude) or nutritional factors (famine and specific alimentary depressions). We classify these factors into three categories according to the risk level (moderate, significant and elevated). While any of these factors can increase the risk of VPP, no one is sufficiently sensitive or specific in predict inevitable onset of VPP. In most cases VPP results from a combination of two (or more) risk factors. The risk factors of VPP classified as moderate include age (> or = 35 years), increased blood pressure during the second trimester of pregnancy, a new paternity, dietetic factors or environmental factors, smoking and controlled diabetes (class B, C), or inactive systemic diseases. Risk is significantly elevated among obese (BMI > or = 25), primiparous women, women with a past familial history (first degree) of preeclampsia or eclampsia, cocaine use or association of tobacco and caffeine use, increased placental mass (associated with twin pregnancy, fetal hydrops or molar pregnancy), uncontrolled diabetes,
lupus
, active scleroderma. Risk is considered to be high among patients with chronic hypertension, women with a past history of preeclampsia, diabetes (class D, F, R), patients with active systemic disease or with antiphospholipid antibodies or women with
lupus
or renal lesions and/or proteinuria as well as chronic kidney disease resulting in proteinuria, hypertension and renal insufficiency. Finally, the risk of VPP is considered to be increased in the presence of acquired thrombophilia. It remains moderate in the presence of isolated genetic thrombophilia, except in forms presenting with multiple genetic mutations or associated with an
hyperhomocysteinemia
. A "high-risk group" is defined among women with past history of deep venous thromboembolic events outside pregnancy, or with a past history of placental vascular pathology (intra-uterine death, placental abruptio, severe and precocious placental, intra-uterine growth retardation, early and repetitive fetal loss) and who, in addition, present with acquired thrombophilia (antiphospholipid antibodies, thrombocytemia), unique homozygous genetic thrombophilia, amultiple genetic thrombophilia or unique heterozygous genetic thrombophilia associated with
hyperhomocysteinemia
. Prophylactic treatment of acquired thrombophilia and of the multiple genetic forms or associated with hypercysteinemia is a logical rationale, particularly among women with a past history of placental vascular pathology, or with a past history of venous thromboembolic events. On the contrary, prophylaxis using low-molecular-weight heparin in the event of asymptomatic genetic thrombophilic mutations and for women without a past history of deep venous thromboembolism or vascular placental pathology remains controversial.
...
PMID:[Vascular placental pathology in high-risk groups: definition and synopsis]. 1502 87
The etiology of venous thromboembolic disease has been the subject of several recent discoveries, particularly on genetic predisposing factors. The laboratory investigation that may help to evaluate the risk for individual patients includes the measurements of coagulation inhibitors (antithrombin, protein C, and protein S) in plasma assays, the search for the factor V Leiden mutation by the plasma activated protein C resistance test (always to be confirmed by DNA analysis when abnormal), and the search for the prothrombin gene mutation by DNA analysis. Among acquired abnormalities, the most frequently involved are phospholipid-dependent autoantibodies associated or not with a subset of antibodies having an anticoagulant effect in vitro (
lupus
anticoagulant). Other coagulation abnormalities such as increased FVIII, FIX, or FXI levels or
hyperhomocysteinemia
have been suggested to be risk factors for thrombosis, although additional studies are required to definitively assess their role.
...
PMID:Venous thromboembolic disease: risk factors and laboratory investigation. 1519 17
The purpose of the present study was to determine whether using an extended panel of laboratory tests increases the detection of a hypercoagulable state in patients with ocular thromboses. Twenty consecutive patients with ocular thromboses (vein, artery, or choriocapillaris occlusions) underwent testing for activated protein C resistance/factor V Leiden, prothrombin G20210A,
lupus
anticoagulant, anticardiolipin antibodies,
hyperhomocysteinemia
, and deficiencies of protein C, protein S, and antithrombin. For each patient, we selected two age-matched and gender-matched individuals without ocular thromboses as controls. Sixteen of the 20 patients (80%) had one or more laboratory tests that supported a hypercoagulable condition. Prothrombin G20210A (P < 0.02) and
hyperhomocysteinemia
(P < 0.0006) were significantly more frequent in ocular thrombosis patients compared with controls. The most common condition was antiphospholipid antibody syndrome, present in 40% of patients (confirmed by repeat testing at least 6 weeks later), but this did not reach statistical significance compared with the controls. No patients with ocular thromboses had hereditary abnormalities of protein S, protein C, or antithrombin. In conclusion, an extended panel of laboratory tests improved the detection of a hypercoagulable state in ocular thromboses. Testing for homocysteine, antiphospholipid antibodies, and the prothrombin G20210A mutation should be considered in patients with ocular thromboses.
...
PMID:Prothrombin gene mutation G20210A, homocysteine, antiphospholipid antibodies and other hypercoagulable states in ocular thrombosis. 1520 87
Patients with ischemic stroke are sometimes found to have an underlying inherited (deficiency of protein C, protein S, antithrombin III, activated protein C resistance, prothrombin gene mutation,
hyperhomocysteinemia
) or acquired thrombophilia (
lupus
anticoagulant and anticardiolipin antibodies,
hyperhomocysteinemia
). Patient selection for thrombophilia screening is, therefore, a frequent question in managing patients with ischemic stroke. In this review we discuss patient selection and timing for laboratory tests for thrombophilia screening in stroke patients based on a literature review and we calculated overall costs per year in Germany for testing patients older than 18 years with an ischemic stroke of undetermined cause. As there is a lack of studies comparing anticoagulation with antiplatelet therapy in patients with diagnosed thrombophilia, laboratory screening for thrombophilia even in a selected group of patients with cryptogenic ischemic stroke remains of questionable value at present. An exception appears to be testing for
lupus
anticoagulant and anticardiolipin antibodies in younger patients with suspected antiphospholipid syndrome (two positive test results necessary), because anticoagulation seems to be superior to aspirin in patients with antiphospholipid syndrome.
...
PMID:[Thrombophilias in patients with ischemic stroke. Indication and calculated costs for evidence-based diagnostics and treatment]. 1533 41
Although antiphospholipid antibodies (aPL) are associated with thrombosis, it is not known who with aPL is at higher risk for thrombosis. It was the aim of this cross-sectional study to investigate how thrombophilic factors contribute to venous or arterial thrombosis in aPL-positive individuals. In outpatient test centres at two tertiary care hospitals, two hundred and eight (208) persons requiring aPL testing were matched by age, gender and centre to 208 persons requiring a complete blood count. Persons were classified as aPL-positive (having anticardiolipin,
lupus
anticoagulant and/or anti-beta(2)-glycoprotein I antibodies) or aPL-negative. Several thrombophilic factors were studied using logistic regression modelling. Results showed that the aPL-positive group had three-fold more events (37%) than the aPL-negative group (12%). In unadjusted analyses, clinically important associations were observed between factor V Leiden and venous thrombosis,
hyperhomocysteinemia
and arterial thrombosis, and activated protein C resistance (APCR) and venous thrombosis (OR, 95% CI = 4.00, 1.35-11.91; 4.79, 2.03-11.33; and 2.03, 1.03-3.97, respectively). After adjusting for recruitment group, persons with both APCR and aPL had a three-fold greater risk (OR, 95% CI = 3.31, 1.30-8.41) for venous thrombosis than those with neither APCR nor aPL. Similarly, after adjusting for hypertension, family history of cardiovascular disease, gender and recruitment group, persons with both
hyperhomocysteinemia
and aPL had a five-fold increased risk (OR, 95% CI = 4.90, 1.37-17.37) for arterial thrombosis compared to those with neither risk factor. In conclusion, APCR phenotype and
hyperhomocysteinemia
are associated with a higher risk of venous and arterial thrombosis, respectively, in the presence of aPL.
...
PMID:Antiphospholipid antibodies and thrombosis: association with acquired activated protein C resistance in venous thrombosis and with hyperhomocysteinemia in arterial thrombosis. 1558 39
Cardiovascular disease is a major cause of morbidity and mortality in patients with
systemic lupus erythematosus
(
SLE
). Antiphospholipid syndrome (APS) is one of the most important causes of thrombosis in
SLE
. In addition, an association between
hyperhomocysteinemia
and increased cardiovascular risk has also been reported. Our aim is to analyse the association of thrombosis with plasma total homocysteine (ptHcy), antiphospholipid antibodies (aPL) and other vascular risk factors in
SLE
patients. Fasting plasma levels of ptHcy, vitamin B12, folate, total cholesterol and creatinine were measured in 117
SLE
patients. Clinical and immunological data were obtained from our prospective computerized database. aPL-positivity was defined according to Sapporo criteria. There was no association between aPL and ptHcy. ptHcy was higher in patients with arterial (median 13.02 versus 10.16 micromol/L, P = 0.010) but not venous thrombosis. In the subgroup analysis, this association was only seen in aPL-negative patients. In logistic regression, aPL (OR 6.60, 95% CI 1.86-23.34) and ptHcy (OR 1.10, 95% CI 1.01-1.19) were independently associated with arterial thrombosis. However, when hypertension, smoking and plasma total cholesterol were added to the model, only aPL (OR 7.38, 95% CI 2.02-26.91) and hypertension (OR 7.70, 95% CI 2.33-25.39), but not ptHcy, remained independently related to arterial events. aPL was the only variable independently related to venous thrombosis (OR 7.68, 95% CI 1.60-36.86). ptHcy concentrations are higher in
SLE
patients with arterial thrombosis. No interaction between homocysteine and aPL was found. Raised ptHcy may be a marker of increased vascular risk in aPL-negative
SLE
patients. The role of homocysteine as a marker of vascular risk may depend on the presence of traditional risk factors, although a modest intrinsic effect cannot be entirely excluded.
Lupus
2004
PMID:Homocysteine, antiphospholipid antibodies and risk of thrombosis in patients with systemic lupus erythematosus. 1564 48
Venous thromboembolism is a chronic disease with an annual incidence of recurrence of 5 to 10%. Patients with venous thrombosis should be treated with anticoagulants for at least 3 months. The optimal duration of anticoagulation entails balancing the risk of recurrence against the risk of treatment-associated bleeding. Candidates for extended anticoagulation are patients with a high risk of recurrence. The risk of recurrence is increased in patients with antithrombin deficiency, the
lupus
anticoagulant, homozygous F V Leiden, combined defects, high F VIII, high F IX, high TAFI,
hyperhomocysteinemia
or more than one episode of thrombosis. The risk of recurrence is low in patients with venous thrombosis secondary to surgery or trauma. Routine thrombophilia screening is aimed at identifying patients who could benefit from extended anticoagulation. This population consists of patients with venous thrombosis at a young age, an unprovoked episode of venous thrombosis, patients with a strong positive family history or patients with recurrent venous thrombosis. Screening should comprise antithrombin determination and the search for the
lupus
anticoagulant. Patients harbouring one of these defects are at high risk of recurrence and most likely will profit from prolonged anticoagulation. The clinical relevance of new treatment strategies such as extended low-intensity warfarin or administration of the direct thrombin inhibitor (xi-)melagatran is at present unclear.
...
PMID:The optimal duration of secondary thromboprophylaxis in patients with venous thromboembolism. The importance of thrombophilia screening. 1577 39
Spontaneous tendon rupture in a patient with
systemic lupus erythematosus
(
SLE
) is a rare but potentially disabling complication. Minor trauma, local inflammation and long term corticosteroid therapy are regarded as possible causes. However, ischemic necrosis of the tendon resulting from hypercoagulability and methyl prednisolone (MTP) pulse therapy has not been reported. We present a 20-year old female, newly diagnosed with
lupus
, who has high titer antiphospholipid antibodies,
hyperhomocysteinemia
and protein S deficiency. Her severe clinical symptoms of
lupus
were improved after MTP pulse therapy. Several days later, cold sensation over the right lower leg developed. On day 15 after pulse therapy, acute onset of right heel pain occurred when she was ascending stairs. Rupture of the right Achilles tendon was demonstrated by sonography and MRI. A Doppler sonography revealed narrowing and abrupt cessation of blood flow in the right popliteal artery. Heparin treatment was started. The angiography performed two days after heparinization revealed narrow caliber and decreased flow of the right tibial artery below the right ankle. Surgical repair of the tendon was successful and the pathology of the resected tendon revealed focal necrosis, degeneration and capillary proliferation. MTP pulse therapy in a
lupus
patient with hypercoaguable state with
hyperhomocysteinemia
, protein S deficiency and high titer antiphospholipid antibodies may cause spontaneous tendon rupture.
Lupus
2005
PMID:Spontaneous Achilles tendon rupture in a patient with systemic lupus erythematosus due to ischemic necrosis after methyl prednisolone pulse therapy. 1586 19
Previous studies have shown an increased risk of retinal vein occlusion (RVO) in patients with hypertension, hypercholesterolemia and diabetes mellitus. Literature on the association between thrombophilic factors and RVO consists of small studies and case reports. The objective was to determine the relationship between thrombophilic risk factors and RVO. Thrombophilic risk factors analyzed were
hyperhomocysteinemia
, MTHFR gene mutation, factor V Leiden mutation, protein C and S deficiency, antithrombin deficiency, prothrombin gene mutation, anticardiolipin antibodies and
lupus
anticoagulant. For all currently known thrombophilic risk factors odds ratios for RVO were calculated as estimates of relative risk. The odds ratios were 8.9 (95% CI 5.7 - 13.7) for
hyperhomocysteinemia
, 3.9 (95% CI 2.3 - 6.7) for anticardiolipin antibodies, 1.2 (95% CI 0.9 - 1.6) for MTHFR, 1.5 (95% CI 1.0 - 2.2) for factor V Leiden mutation and 1.6 (95% CI 0.8 - 3.2) for prothrombin gene mutation. In conclusion, regarding thrombophilic risk factors and RVO there is only evidence for an association with
hyperhomocysteinemia
and anticardiolipin antibodies, factors that are known as risk factors for venous thrombosis as well as for arterial vascular disease. The minor effect of factor V Leiden mutation and the protrombin gene mutation (risk factors for venous thrombosis only) suggests that atherosclerosis might be an important factor in the development of CRVO.
...
PMID:Retinal vein occlusion: a form of venous thrombosis or a complication of atherosclerosis? A meta-analysis of thrombophilic factors. 1596 81
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