View clinical trials related to Thrombosis.
Filter by:The purpose of this study is to demonstrate the ability of new D-Dimer assay combined with a clinical pretest probability (PTP) to safely exclude pulmonary embolism (PE) or Deep Venous Thrombosis (DVT) in a 3 month follow-up.
The objective of the study is to demonstrate the superiority of the mesoglycan (Prisma®), compared to placebo, in reducing the incidence of thromboembolic complications (relapse / extension of superficial venous thrombosis (SVT), deep venous thrombosis (DVT), pulmonary embolism (PE)) in patients who have completed the cycle of therapy of the acute phase after superficial vein thrombosis.
Paroxysmal nocturnal hemoglobinuria (PNH) is a rare acquired clonal hematological disorder, which can cause arterial or venous thrombosis. The frequency of PNH in young patients (< 50 years old) with embolic stroke (ESUS), transient ischemic attack (ETUS) or superior sagittal sinus cerebral venous thrombosis (SSS-CVTUS) of undetermined source, is currently unknown. This study proposes to recruit ESUS, ETUS, SSS-CVTUS patients to determine the frequency of PNH diagnosis confirmed by flow cytometry in these patient populations.
Patients with cirrhosis of viral etiology (HCV/HBV); Patients with cirrhosis of any other etiology (alcohol, idiopatic, autoimmune). Planned Number of cirrhotic subjects 200 patients Inclusion Criteria Subjects (18 yr old) with liver cirrhosis of any etiology, Exclusion Criteria All patients should not have hepatocellular carcinoma or other malignant tumors, they should not be treated with anticoagulant / antiplatelet agents, not affected by PVT already diagnosed and not suffering from congenital coagulation disorders (haemophilia A / B, von disease Willebrand, another congenital deficiency of coagulation factors) or severe thrombocytopenia (<30,000 Plt / μL). Subject has participated in another clinical study within 30 days prior to study enrollment or is scheduled to participate in another clinical study on cirrhosis Primary Objective To describe the prospective modification of ADAMTS-13 level and other coagulation variables (e.g. FVIII, VWF:Ag/VWF:act) in cirrhotic patients during 18 months from the enrolment and to verify their predictive role as biomarker of development of portal vein thrombosis (PVT) Secondary Objectives To describe prospectively the modification of ADAMTS-13 level as a function of the etiology of cirrhosis Statistical analysis The total duration of the study will be of 12 months. The sample size of 200 subjects will be selected as a feasible number of patients to be recruited in a period of six months. The patients will be consecutively enrolled and followed for 18 months. As a result, in a follow up period of 18 months about 20-25 cases of PVT are expected. Continuous variables will be expressed as means ± standard deviations. In addition to descriptive statistics (location parameters), univariate analysis will be performed on each parameter and development of PVT during the follow up period. In previous observational studies both 1) a reduced PV flow [prospectively] and 2) a reduction of ADAMTS-13 are significantly associated with PVT. These associations will be investigated prospectively and analyzed simultaneously by a multivariate analysis and ROC curve to establish the sensitivity and specificity of these parameters as predictors of PVT development. Analyses will be performed using available data
Portal vein tumour thrombus (PVTT) is a common complication of hepatocellular carcinoma (HCC). PVTT has a profound adverse effect on prognosis, with a very short median survival time (2-4 months). The presence of PVTT also limits treatment options, such as liver transplantation and curative resection. Although the Barcelona Clinic Liver Cancer group recommended sorafenib as a standard therapy for advanced-stage HCC, the optimal treatment for HCC with PVTT remains largely controversial. Some studies have reported a survival benefit in patients with PVTT who underwent transarterial chemoembolization (TACE), even in patients with main portal vein (MPV) tumor thrombus. Iodine-125 brachytherapy had also showed promising efficacy as a new method for unresectable HCC with PVTT. Results of our previous study indicated that TACE combined with Iodine-125 seeds implantation might be a good choice for selected patients with PVTT. Thus, we conduct this study to farther evaluate the effect of TACE combined with Iodine-125 seeds implantation for HCC with PVTT. 270 patients with HCC and PVTT will be included and randomized to two group: group 1, patients received TACE combined with Iodine-125 seeds implantation; group 2, patients received TACE alone. TACE and Iodine-125 seeds implantation will be performed with a standardized procedure. Iodine-125 seeds implantation into PVTT (guided by CT) will be conducted 7 days after TACE. All patients revisit our institutions for follow-up examinations including contrast enhanced CT/MRI and laboratory tests every 4-6 weeks after the first treatment. Patients who have a tumor response rating of complete response will be required to revisit 3 months interval. At each visit, TACE or Iodine-125 seeds implantation is repeated if the following criteria are reached: 1) images indicating viable intrahepatic tumor tissue or PVTT; 2) Child-Pugh class A or B, and no contraindication to TACE and Iodine-125 seeds implantation. The primary end point of this study is overall survival. The secondary end points are time to tumor progression, disease control rate, duration of portal patency and adverse events. All adverse events are graded in accordance with Common Toxicity Criteria Adverse Events Version (CTCAE) 4.03.
This was a prospective, cohort study.
FEVRIER study is an observatory of hospitalizations in cardiology units in sub-Saharan Africa.
The goal of this study is to develop strategies that will improve outcomes for patients with deep vein thrombosis (DVT), using in vivo FDG-PET inflammation imaging to better predict the development of the post-thrombotic syndrome (PTS). New approaches are needed to improve the outcomes of patients with DVT, a disease that affects up to 600,000 patients per year in the US alone. DVT acutely places patients at risk of death from pulmonary embolism and causes 50,000 deaths annually in the US. Moreover, up to 30-50% of patients will develop PTS, an illness characterized by inflammation-driven fibrotic vein wall injury, and persistent thrombus obstruction. PTS occurs despite anticoagulant therapy, and produces chronic disability from leg pain, heaviness, edema, skin pigmentation, and ulcers; some patients may even require amputation. PTS impairs quality of life to the same extent as chronic obstructive pulmonary disease or diabetes. Therefore new diagnostic insights into PTS are urgently needed. There are several major challenges to improve outcomes in PTS: A) Limited in vivo knowledge regarding inflammation and the development of PTS; B) L Lack of predictive approaches to identify patients at high risk for PTS that will preferentially benefit from novel therapies. Recently, our laboratories have harnessed FDG-PET molecular imaging to illuminate DVT inflammation in vivo, and to provide a new strategy to diagnose recurrent DVT, a vexing clinical problem (Hara et al. Circulation 2014). We now propose to further develop FDG-PET to improve outcomes in DVT and PTS. The objective of this application is to develop FDG-PET as an inflammation imaging approach to assess DVT inflammation and predict risk of developing PTS in human subjects; Hypothesis 1A: Inflammatory activity in DVT (quantified acutely, using FDG-PET imaging within 0-7 days after DVT) will predict PTS incidence (primary) and severity (secondary) within a 24 month follow-up period. Hypothesis 1B: Inflammatory activity in DVTs (quantified sub-acutely, using FDG-PET imaging within 21-28 days after DVT), will predict PTS incidence and severity. Eighty patients with DVT will be imaged using FDG-PET/CT acutely (0-7 days of DVT diagnosis), and sub-acutely (21-28 days after diagnosis). Subjects will be evaluated repeatedly for up to 2 years to detect clinical evidence of PTS (Villalta score), ultrasound findings for structural venous injury, and soluble biomarkers of systemic inflammation. Subsequently, we will evaluate the relationship between FDG DVT activity and the development of PTS.
The growing use and the expanding indications for cardiovascular implantable electronic devices (CIEDs) have been associated to an increase of device removal. The indications of CIEDs removal are infectious (55%) or noninfectious (45%) such as upgrading of devices, nonfunctional devices and thrombosis. Removal can be performed according to transvenous or surgical procedures. Transvenous lead removal (TLR) must be done by experimented cardiologists and respecting current consensus. TLR can be done with conventional techniques involving inserting locking stylets and telescoping sheaths around the pacing leads to separate them from the surrounding scar tissue. These conventional procedures have a success rate of ≈65%. TLR thanks to laser sheath has been validated and improved the success rate until >95%. However, the TLR from chronically implanted CIEDs still carries a significant risk of procedural failure, morbidity, and mortality, related to tearing of the great vessels and cardiac structures, even when performed by experienced operators. Even if the transvenous extraction using laser sheath seems to be more effective, this strategy would be more expensive. Considering the availability of several strategies for TLR and the cost heterogeneity of procedures, a cost assessment in real life of these therapeutic strategies is essential for an optimal choice of therapeutic strategies.
The ASPIREX®S Endovascular System is a rotating and aspirating catheter system. It is intended to be used for the percutaneous transluminal removal of fresh thrombotic or thromboembolic material from native blood vessels (or vessels fitted with stents, stent grafts or native or artificial bypasses) outside the cardiopulmonary, coronary and cerebral circulations. CAPTUREX® , a catheter with a filter basket, is intended to be used for the filtering of emboli from blood vessels during potentially embolizing procedures on the patient. ASPIREX®S and CAPTUREX® are CE-marked (Class III) medical devices. In this study the effectiveness and safety in the removal of thrombi in veins is assessed under real life setting.