View clinical trials related to Atherosclerosis.
Filter by:The goal of this study is to understand and compare an alternative model of care in comparison to the usual model of care in include male and female participants ≥18 years of age with a history of ASCVD (hear and blood vessels diseases) or high-risk participants who have elevated bad cholesterol (LDL-C ≥1.8 mmol/L). The alternative model of care includes telephone support calls from a study nurse (after visits 1,2 and 4) and text messages to your mobile phone with healthy heart information. The main question it aims to answer is to understand and compare an alternative model of care in comparison to the usual model of care by evaluating the study participants bad cholesterol values after 180 and 365 days of the study. Each participant will take their medications as per usual care but may have the addition of Inclisiran, 284 mg 1.5 ml liquid in a single-use prefilled syringe for under skin administration. In accordance with the current medical practice guidelines for treating heart related conditions, Inclisiran and its product information will be made available for use in both care models. All the participants who decide to take part in this study will be requested to do the following: - Answer any questions from the study doctor or the study staff as accurately as possible when asked about changes in health status, medications, heart health, visits to other doctors or hospital admissions, planned surgery, even if they think none of these are related to the study. - Study doctor will be able to inform them of which medications you can and cannot take as part of this study. - To use mobile phone to receive text messages and/or questionnaires as proposed in the new model of care. - Advise the study doctor if they plan to move away from the geographical area where the study is being conducted during the study period. - Take the medications for cholesterol lowering treatment (such as a statin and/or ezetimibe) that are prescribed by the study doctor. - Tell the study doctor or study staff as soon as possible about suspected participant / participant partner pregnancy. - Tell the study doctor or study staff if they change their mind about taking part in the study. - Attend all the visits (screening visit, visits 1, 2, 3, 4 and visit 5). - Provide all the information that will enable the study team to contact them, i.e., inform the study staff if contact details change, provide contact details of a family member, etc.
The rupture or erosion of an atherosclerotic plaque with thrombosis or embolization often underlie heart attacks and strokes. The early identification of patients with atherosclerotic plaques prone to rupture or erosions, vulnerable plaques (VP), and their treatment before the occurrence of events is, therefore, one of the greatest cardiovascular challenges today. Possible approaches for early detection of VP include imaging techniques allowing visualization of plaque structure, circulating biomarkers and better understanding of the pathophysiologic mechanisms of the disease. In the carotid plaque imaging project the investigators study human atherosclerotic plaques (that are removed by endarterectomy) to disclose their underlying structure and mechanisms, finding possible novel therapeutic targets or markers for VP. The investigators also study plaque structure with imaging methods and try to develop new ways to detect VP using circulating or imaging markers.
The goal of this randomized controlled trial is to assess the impact of disclosing a high polygenic risk result for coronary artery disease on change in cardiovascular health over one year.
Cerebral hyperperfusion syndrome (CHS) was initially described as a clinical syndrome following carotid endarterectomy (CEA), but it may present in both CEA and carotid artery stenting, and is characterised by throbbing ipsilateral frontotemporal or periorbital headache, and sometimes diffuse headache, eye and face pain, vomiting, confusion, macular oedema, and visual disturbances, focal motor seizures with frequent secondary generalisation, focal neurological deficits, and intracerebral or subarachnoid haemorrhage. Knowledge of CHS among physicians is limited. Most studies report incidences of CHS of 1-3% after carotid endarterectomy. CHS is most common in patients with increases of more than 100% in perfusion compared with baseline after carotid revascularization procedures and is rare in patients with increases in perfusion less than 100% compared with baseline. The pathophysiological mechanism of CHS remains only partially understood. The chronic lowflow state induced by severe carotid disease results in a compensatory dilation of cerebral vessels distal to the stenosis, as part of the normal autoregulatory response, to maintain adequate cerebral blood flow (CBF). In this chronically dilated state, the vessels lose their ability to autoregulate vascular resistance in response to changes in blood pressure. In fact, it has been shown that this dysautoregulation is proportional to the duration and severity of chronic hypoperfusion. After revascularization and reperfusion, the impaired cerebral autoregulation could then contribute to a cascade of intracranial microcirculatory changes, as explained above, with an inability of reaction toward the augmentation of the CBF after the carotid recanalization. Although most patients have mild symptoms and signs, progression to severe and life-threatening symptoms can occur if CHS is not recognised and treated adequately. Because CHS is a diagnosis based on several non-specific signs and symptoms, patients may be misdiagnosed as having one of the better-known causes of perioperative complications like thromboembolism.
Primary Study Objective : To compare the effects of low-dose rivaroxaban plus aspirin versus aspirin on atherosclerotic plaque inflammation using serial FDG Positron Emission Tomography/Computed Tomography(PET-CT) imaging of carotid artery and ascending aorta. Secondary Study Objective : To compare the effects of low-dose rivaroxaban plus aspirin versus aspirin on biomarkers including high-sensitivity C-Reactive Protein(CRP) and lipid profiles.
The study will show the influence of inflammatory bowel disease on the risk of development of atherosclerosis
Interventional study to compare standard of care vs standard of care plus the use of a medication therapy management smartphone app (mediteo m+, Mediteo GmbH, Heidelberg) in patients with atherosclerotic cardiovascular disease and indication to start high intensity statin therapy.
To determine whether treating to an LDL-C target of 25 to <70 mg/dL is superior to an LDL-C target of 70 to <100 mg/dL with respect to major cardiovascular events (cardiovascular death, myocardial infarction, stroke, hospitalization for unstable angina, or coronary revascularization) in patients aged ≥75 years with atherosclerotic cardiovascular disease (ASCVD). To determine whether treating to an LDL-C target of 25 to <70 mg/dL is non-inferior to an LDL-C target of 70 to <100 mg/dL with respect to major safety events (hemorrhagic stroke, new-onset diabetes, muscle-related events, neurocognitive adverse events, new or recurrent cancer, cataract, or hepatic disorder [Alanine aminotransferase (ALT)/Aspartate aminotransferase (AST) >3× ULN, or total bilirubin >2× ULN]) in patients aged ≥75 years with ASCVD.
This study aims to confirm the effectiveness of ezetimibe add-on therapy on LDL-C levels compared to atorvastatin monotherapy, especially in very high-risk patients. We intend to lay the foundation for a standard treatment for these patients through ezetimibe add on lipid-lowering therapy.
BACKGROUND AND RATIONALE OF THE STUDY The analysis of the composition of the clot constitutes a promising tool for investigating the possible pathogenetic mechanisms underlying ischemic stroke. This analysis was made possible thanks to the numerous mechanical thrombectomy operations which have now become routine. Several studies have attempted to explore the possible relationship between the primary site of thrombus formation and clot composition, reporting that cardioembolic stroke may have a higher percentage of platelet-rich areas than noncardioembolic thrombosis. However, the data are conflicting and do not seem to support an association between clot histology and etiology. Furthermore, thrombus composition appears to influence thrombolysis and the efficacy of thrombectomy. For example, fibrin-rich thrombi appear to reduce the effectiveness of thrombolytic treatment and require more steps with mechanical thrombectomy treatment. Primary ENDPOINT: Evaluate how clot composition relates to stroke etiology according to the TOAST classification. Secondary ENDPOINT: - relationship between different clot components and the degree of thrombectomy recanalization as defined by treatment modified cerebral ischemia score (mTICI). - relationship between the different components of the clot and the number of steps required to achieve recanalization. - relationship between the different clot components and outcome indicators (NIHSS score and mRS score). TARGET POPULATION Patients with ischemic stroke with occlusion of large intracranial vessels will be included in the study if deemed suitable for mechanical thrombectomy therapy in accordance with national and international guidelines. INCLUSION CRITERIA - age > 18 years; - Patients diagnosed with large vessel occlusion stroke in the emergency room CT Angio-study, undergoing mechanical thrombectomy procedure. - Recovered thrombus available for analysis EXCLUSION CRITERIA ● Lack of written informed consent. MATERIALS AND METHODS The clot will be portioned. Part of the sample will be fixed in a 10% formalin solution (3.7% formaldehyde), part will be frozen in liquid nitrogen. Within 24-48 hours of fixation, formalin-fixed thrombi will be dehydrated by increasing the concentration of ethanol (70%, -80%, -95%, 100%) and paraffin-embedded allowing good preservation of tissue morphology and easy long-term storage. The included samples will be sectioned along the major axis of the thrombus, in slices with a thickness between 4 and 5 µm. Base staining will be used to visualize RBC, PLT and fibrin. - Hematoxylin and Eosin (H&E) will allow visualization of general thrombus structures and identification of aggregates of fibrin/platelets (colored pink), red blood cells (red), and nucleated cells (dark blue). - Martius Scarlet Blue (MSB), selectively stains fibrin (dark pink/red), red blood cells (yellow) and collagen (blue - Mallory-Azan for collagen and phosphotungstic acid hematoxylin for fibrin. - immunohistochemistry to detect the presence of - Platelets (CD42-Gp-Ib+, CD41a-Gp-IIb/IIIa+, CD61-GpIIIa), - white blood cells (CD45+, common leukocyte antigen), or monocytes/macrophages (CD14+, CD1a+, CD68+), - T lymphocytes (CD3+, CD8/CD4+), or natural killers (CD16+, CD56+), or mobile premature endothelial cells and blood progenitors (CD34+), or neutrophils (CD45+, CD16+), or fibrinogen or von Willebrand factor.