View clinical trials related to Embolism.
Filter by:Severe COVID-19 is associated with a hypercoagulable state, with a high risk of thrombotic phenomena such as pulmonary thromboembolism (PE). Its diagnostic suspicion is complicated, due to the overlap of symptoms of PE with those of COVID-19 itself. Therefore, it is essential to improve PE prediction to optimise the performance of confirmatory imaging tests such as thoracic CT angiography. Early diagnosis has relevant therapeutic implications, as it justifies starting anticoagulant treatment early, with a possible positive impact on the clinical evolution of these patients. The CHOD risk scale has recently been described: the acronym for C-reactive protein concentration, heart rate, oxygen saturation, and D-Dimer levels. Its initial description was carried out in a study in a single hospital centre. proving to be an easy-to-apply tool, useful for predicting the appearance of PE in patients hospitalized for COVID-19. The objective of this study is to carry out an external validation of this scale in patients hospitalized for COVID-19 pneumonia, through an observational, cross-sectional, multicenter, real-life study in patients hospitalized for severe COVID-19 pneumonia, confirmed by objective methods, and showing high D-dimer values. Imaging tests with CT angiography will be performed in patients with elevated D-Dimer, following international clinical practice regulations. Given that they will be consecutive patients, CT angiography will be performed in all patients regardless of the patient's clinical probability of PE as long as they meet the inclusion criteria and none of the exclusion criteria. To calculate the PE predictive power of the CHOD scale in the validation cohort, a methodology similar to that used in the construction cohort will be used, that is, the use of a ROC curve. Taking into account that a similar predictive value (with a maximum error of 5%) between the CHOD scale in the construction cohort and that of this study (validation cohort) will be considered as an adequate external validation, and taking into account a statistical power of 80%, an alpha error of 5% and a maximum loss of patients of 15%, the required sample size is 245 patients. Since 7 centres initially participate, each of which will have to contribute 35 valid consecutive patients for the analysis.
Pulmonary embolism (PE) is a common cardiovascular condition with an estimated incidence of 0.60 to 1.12 per 1000 inhabitants in the United States of America, and the diagnosis is challenging as patients with PE present with a wide array of symptoms. Computed tomography pulmonary angriography (CTPA) and lung ventilation-perfusion scintigraphy (VQ) are considered the gold-standards in PE-diagnostics but may not always be feasible. CTPA is contraindicated by contrast allergy or renal failure and both modalities require involvement of multiple staff-members and transport of the patient. Lung scintigraphy cannot be performed in an emergency situation, with unstable patients and patients unable to comply to the examination. Ultrasound represent a possible tool in confirming or dismissing clinical PE suspicion. Ultrasound is non-invasive and can be performed bedside by the clinician, an approach known as point-of-care ultrasound (PoCUS), reducing both time, radiation-exposure and costs. The aim of this study is to investigate whether integrating cardiac, lung and deep venous ultrasound in the clinical evaluation of suspected PE reduces the need for referral to CTPA or lung scintigraphy, during emergency department work up, while maintaining safety standards.
Investigators are building an empirical evidence base for real world data through large-scale replication of randomized controlled trials. The investigators' goal is to understand for what types of clinical questions real world data analyses can be conducted with confidence and how to implement such studies.
Pulmonary embolism (PE) is the third leading cause of cardiovascular mortality. The Pulmonary Embolism Response Team (PERT) concept offers a rapid and multidisciplinary approach focused on improving outcomes for patients with PE. All institutionalized PERTs in Poland have been invited to join the study. The goal of this registry is to describe current practice and outcomes in patients with acute PE treated by Polish PERTs.
The pulmonary embolism (PE) causes a blockade of the pulmonary arteries typical due to a thrombus which is formed in the lower region of the body or pretty rare to other materials (tumor, air, fat). The working group plans to evaluate the pathology of the thromboembolism in the case of a partial, subtotal or even total pulmonary embolism. The acute PE is still often in the adult population and in many accompanied by death. Etiological the problem occurs through an acute right ventricular failure and leads into severe pulmonal perfusion disorder with shock and hypoxemia. The right diagnose is pretty hard in the clinical day because all symptoms are common and unspecific. To provide the best treatment in short time it is needed to sum up all the symptoms and evaluate the risk of an acute pulmonary embolism and it's morbidity. The easiest and fastest way treating a PE is to apply a systemic intravenous thrombolysis but bleeding complications are the most common and most frequently side effects. The decision-making process in patients without shock is pretty hard because of having no clear diagnose. Lab parameters and imaging (CT angiography) is important for the best decision in critical ill PE patients but time is sometimes missing. A possible new biomarker in identifying a PE is adrenomedullin. Elevated adenomedullin levels in septic patients with left ventricular heart failure, severe dyspnoea and intubated patients are well known, but in the case of PE it wasn't analysed yet. Human adrenomedullin is a protein with 52 amino acid which is produced in the lung and first extracted in the adrenal gland. The sequence homology is pretty similar to the Calcitonin-Gene-Related-Peptide (CGRP)-protein superfamily (vasodilatation). Its precursor is named pro-adrenomedullin peptide and it shows a significant weaker vasodilatation activity compaired to adrenomedullin. Adrenomedullin causes severe hypotonia in scientific studies where it was applied as an intravenous bolus or infusion. This vasodilatation effect concern to the systemic and as well in the pulmonary circulation. Its vasodilatation mechanism is not clarified yet. The trial is defined as an prospective study, where the investigators would like to measure/analyse the adrenomeulline level in PE patients in the intermediate high and high risk population. The diagnose and treatment of the patients is fixed to the European Society of Cardiology (ESC) recommendations of the cardiology society of 2019 Guidelines on Acute Pulmonary Embolism (Diagnosis and Management of Pulmonary Embolism).
The overall goal of the VVIRTUOSO study is to determine the incidence of VTE including symptomatic DVT and PE after hospital discharge in patients with COVID-19 by implementing a pragmatic patient-centred prospective virtual VTE monitoring program in Canada and the United States.
Venous phase spectral or dual energy (DE) chest computed tomography (CT) in patients with suspected pulmonary embolism (PE) compared to standard computed tomography pulmonary angiography (CTPA): sensitivity, evaluation of iodine mapping and incidental findings.
Pulmonary embolism impacts over 1 in 1000 adults annually and is the third leading cause of cardiovascular death after heart attack and stroke. The consequence of each PE is widely variable. Physiologically, the morbidity and mortality of PE is ultimately caused by failure of the right ventricle. The acute rise in pulmonary vascular resistance caused by a PE can overwhelm the right ventricle, resulting in a drop in cardiac output and death from failure of the heart to provide vital perfusion. Despite the importance of stroke volume and cardiac output in the current understanding of PE mortality, they are notably absent from risk stratification scores because they historically could only be measured invasively. Novel non-invasive methods of estimating stroke volume and associated cardiac output have the potential to revolutionize PE risk stratification and care. Non-invasive blood pressure (NIBP) monitors can even measure stroke volume beat to beat, allowing for continuous evaluation of cardiac function. NIBP systems are typically composed of a finger cuff with an inflatable bladder, pressure sensors, and light sensors. An arterial pulse contour is formed using the volume clamp method of blood pressure measurement combined with calibration and brachial pressure reconstruction algorithms. The stroke volume with each heart beat can be estimated as the area under the systolic portion of the blood pressure curve divided by the afterload. NIBP monitors may improve clinical care of PE because they allow for assessment of dynamic cardiac changes in real time. Detection of worsening stroke volume in acute PE could inform providers of impending cardiac collapse, and improvement of stroke volume may function as a positive prognostic factor or marker of therapeutic success. Use of NIBP monitors during acute PE to identify clinically significant changes in cardiac function may advance both PE prognostication and management. Our clinical study proposes to monitor hemodynamic parameters including stroke volume in patients with acute pulmonary embolism using non-invasive blood pressure monitors. The relationship between hemodynamic parameters and PE outcomes will be assessed, as well as the changes in hemodynamic parameters with PE intervention. To our knowledge, interval monitoring of stroke volume during acute PE with NIBP monitors has never been reported before.
This retrospective cohort study aims to characterise outcomes for patients treated on an intensive care unit (ICU) with COVID-19 in England and Wales, one year after discharge from hospital. Outcomes will be compared with patients admitted as an emergency to an ICU for other conditions. The study will use existing national audit data linked to routine healthcare datasets.
Chest computed tomography of patients having coronavirus disease (COVID-19) will be analyzed with regards to vascular abnormalities (pulmonary embolism and vascular thickening), and their association with lung inflammation. The prevalence, severity, distribution, and prognostic value of chest CT findings will be assessed. Patients with vascular abnormalities will be compared to patients without, which is supposed to provide insights into the prognostic role of such abnormalities, and the potential impact on treatment strategy.