Journal of thrombosis and haemostasis : JTH
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J. Thromb. Haemost. · Jan 2016
Multidetector computed tomographic pulmonary angiography in patients with a high clinical probability of pulmonary embolism.
ESSENTIALS: When high probability of pulmonary embolism (PE), sensitivity of computed tomography (CT) is unclear. We investigated the sensitivity of multidetector CT among 134 patients with a high probability of PE. A normal CT alone may not safely exclude PE in patients with a high clinical pretest probability. In patients with no clear alternative diagnosis after CTPA, further testing should be strongly considered. ⋯ A normal multidetector CTPA result alone may not safely exclude PE in patients with a high clinical pretest probability.
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J. Thromb. Haemost. · Jan 2016
Comorbid risks of deep vein thrombosis and pulmonary thromboembolism in patients with chronic pancreatitis: a nationwide cohort study.
ESSENTIALS: Risks of deep vein thrombosis (DVT) and pulmonary embolism (PE) in chronic pancreatitis (CP) are unclear. We conducted a nationwide cohort study to evaluate the risks of DVT and PE in CP patients. 17 778 patients with CP and 71 106 without CP were followed for 86 740 and 429 116 person-years, respectively. Patients with CP had a 2.95-fold increased rate of DVT and a 4.51-fold increased rate of PE. ⋯ The risks of DVT and PE are significantly higher in CP patients than in the general population.
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J. Thromb. Haemost. · Jan 2016
Replication of a genetic risk score for venous thromboembolism in whites but not in African Americans.
ESSENTIALS: There is little prospective information on genetic risk scores to predict venous thromboembolism (VT). Community based cohort followed a median of 22.6 years for VT occurrence. A 5-SNP risk score identified whites at risk of VT, but not African Americans. The utility of genetic risk scores for VT is yet to be established. ⋯ Higher values for a five-SNP genetic risk score helped identify white adults at risk of VTE. The genetic risk score did not identify future VTE occurrence in African Americans.
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J. Thromb. Haemost. · Jan 2016
Observational StudyDerivation of a clinical prediction score for chronic thromboembolic pulmonary hypertension after acute pulmonary embolism.
Essentials Predicting chronic thromboembolic pulmonary hypertension (CTEPH) after pulmonary embolism is hard. We studied 772 patients with pulmonary embolism who were followed for CTEPH (incidence 2.8%). Logistic regression analysis revealed 7 easily collectable clinical variables that combined predict CTEPH. Our score identifies patients at low (0.38%) or higher (10%) risk of CTEPH. ⋯ Introduction Validated risk factors for the diagnosis of chronic thromboembolic pulmonary hypertension (CTEPH) after acute pulmonary embolism (PE) are currently lacking. Methods This is a post hoc patient-level analysis of three large prospective cohorts with a total of 772 consecutive patients with acute PE, without major cardiopulmonary or malignant comorbidities. All underwent echocardiography after a median of 1.5 years. In cases with signs of pulmonary hypertension, additional diagnostic tests to confirm CTEPH were performed. Baseline demographics and clinical characteristics of the acute PE event were included in a multivariable regression analysis. Independent predictors were combined in a clinical prediction score. Results CTEPH was confirmed in 22 patients (2.8%) by right heart catheterization. Unprovoked PE, known hypothyroidism, symptom onset > 2 weeks before PE diagnosis, right ventricular dysfunction on computed tomography or echocardiography, known diabetes mellitus and thrombolytic therapy or embolectomy were independently associated with a CTEPH diagnosis during follow-up. The area under the receiver operating charateristic curve (AUC) of the prediction score including those six variables was 0.89 (95% confidence interval [CI] 0.84-0.94). Sensitivity analysis and bootstrap internal validation confirmed this AUC. Seventy-three per cent of patients were in the low-risk category (CTEPH incidence of 0.38%, 95% CI 0-1.5%) and 27% were in the high-risk category (CTEPH incidence of 10%, 95% CI 6.5-15%). Conclusion The 'CTEPH prediction score' allows for the identification of PE patients with a high risk of CTEPH diagnosis after PE. If externally validated, the score may guide targeting of CTEPH screening to at-risk patients.
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J. Thromb. Haemost. · Jan 2016
High prevalence of hereditary thrombotic thrombocytopenic purpura in central Norway: from clinical observation to evidence.
Essentials The population prevalence of hereditary thrombotic thrombocytopenic purpura (TTP) is unknown. We studied the prevalence of hereditary TTP and population frequencies of two ADAMTS-13 mutations. A high frequency of hereditary TTP related to ADAMTS-13 mutation c.4143_4144dupA was found. Vicinity of ABO blood group and ADAMTS-13 loci may facilitate screening of ADAMTS-13 mutations. ⋯ Background Hereditary thrombotic thrombocytopenic purpura (TTP) caused by ADAMTS-13 mutations is a rare, but serious condition. The prevalence is unknown, but it seems to be high in Norway. Objectives To identify all patients with hereditary TTP in central Norway and to investigate the prevalence of hereditary TTP and the population frequencies of two common ADAMTS-13 mutations. Patients/Methods Patients were identified in a cross-sectional study within the Central Norway Health Region by means of three different search strategies. Frequencies of ADAMTS-13 mutations, c.4143_4144dupA and c.3178 C>T (p.R1060W), were investigated in a population-based cohort (500 alleles) and in healthy blood donors (2104 alleles) by taking advantage of the close neighborhood of the ADAMTS-13 and ABO blood group gene loci. The observed prevalence of hereditary TTP was compared with the rates of ADAMTS-13 mutation carriers in different geographical regions. Results We identified 11 families with hereditary TTP in central Norway during the 10-year study period. The prevalence of hereditary TTP in central Norway was 16.7 × 10(-6) persons. The most prevalent mutation was c.4143_4144dupA, accounting for two-thirds of disease causing alleles among patients and having an allelic frequency of 0.33% in the central, 0.10% in the western, and 0.04% in the southeastern Norwegian population. The allelic frequency of c.3178 C>T (p.R1060W) in the population was even higher (0.3-1%), but this mutation was infrequent among patients, with no homozygous cases. Conclusions We found a high prevalence of hereditary TTP in central Norway and an apparently different penetrance of ADAMTS-13 mutations.