View clinical trials related to Coronary Heart Disease.
Filter by:Coronary heart disease (CHD) combined with chronic kidney disease (CKD) affects a substantial portion of the population and carries a significant disease burden, often leading to poor outcomes. Despite efforts to strictly control traditional risk factors, the efficacy in improving outcomes for patients with both CHD and CKD has been limited. Recent advancements in lipid metabolism research have identified new lipid metabolites associated with the occurrence and prognosis of CHD and CKD. Our preliminary trial has shown that levels of certain lipid metabolites, such as Cer(18:1/16:0), HexCer(18:1/16:0), and PI(18:0/18:1), are notably elevated in patients with CHD and reduced kidney function compared to those with relatively normal kidney function. This suggests that dysregulation of these non-traditional lipid metabolites may contribute to residual risk for adverse outcomes in these patients. Furthermore, the emerging concept of "cardiovascular-kidney-metabolic syndrome" and the availability of new treatment options highlight the urgent need for a risk stratification tool tailored to modern management strategies and treatment goals to guide preventive measures effectively. To address this, we propose to conduct a prospective cohort study focusing on CHD combined with CKD. This study aims to comprehensively understand the clinical characteristics, diagnosis, treatment status, and cardiovascular-kidney prognosis in these patients. Through advanced metabolomics analysis, we seek to identify lipid metabolism profiles and non-traditional lipid metabolites associated with the progression of coronary artery disease in CHD-CKD patients. Leveraging clinical databases and metabolomics data, we will develop a robust risk prediction model for adverse cardiovascular-kidney outcomes, providing valuable guidance for clinical diagnosis, treatment decisions, and ultimately improving patient prognosis.
Participants are being recruited at the inpatient department of the National Medical Research Center of Cardiology on a 'all-comers' basis. The enrolled participants will be divided into the main group (diagnosed with atherosclerotic cardiovascular disease (ASCVD)) and control (not diagnosed with ASCVD). The participants will have whole blood and serum collected at enrollment for further biobanking. A genome-wide association study will be carried out to determine the genetic determinants associated with atherosclerosis, coronary heart disease, acute coronary syndrome, etc., including a search for pathogenic variants.
Cardiovascular disease (CVD) is the leading cause of human mortality worldwide, imposing substantial societal and economic burdens. Traditionally, high-density lipoprotein (HDL) has been branded as the "beneficial" lipoprotein. The Framingham study found that for every 1mg/dl increase in HDL, the risk of coronary heart disease (CHD) was reduced by 2% in men and 3% in women. Subsequent studies further affirmed the inverse correlation between HDL and the risk of CHD. However, these findings were first challenged by Mendelian randomization studies which failed to identify a causal relationship between HDL and CHD. Moreover, randomized controlled trials demonstrated that therapeutically increasing plasma HDL concentrations did not reduce the risk of CHD events, prompting doubts about HDL's status as "good cholesterol." The relationship between HDL and CHD might be more intricate than previously believed, possibly not just mediated by the quantity of HDL but also intimately linked with its function. Several cross-sectional studies have confirmed the relationship between HDL subtypes and the severity of disease in CHD patients, yet findings are inconsistent. Conventional testing methods lack a universally accepted standard for defining or describing HDL subfractions, with issues like expensive equipment, poor repeatability, cumbersome operation, slow analysis, and low throughput. Microfluidic electrophoresis technology combines the merits of electrophoresis with microfluidic chip technology. This method facilitates efficient separation of substances in microchannels on a substrate, providing rapid and consistent results. Utilizing the latest microfluidic chip technology for HDL subfraction detection offers quick, accurate, and straightforward analysis with minimal sample volume and automation. It precisely reflects the serum concentrations of HDL subfractions HDL2b and HDL3, addressing the current pitfalls of clinical HDL subfraction analysis methods. This approach is poised to become the standard method for HDL subfraction testing. In conclusion, existing studies on the association between HDL subtypes and CHD remain inconsistent, with most having a small sample size. Our study, leveraging microfluidic chip technology for HDL subfraction detection, aims to further investigate: the prognostic value of HDL subtypes for the long-term outcomes of CHD patients, building a risk prediction model for adverse cardiovascular events that includes HDL subtypes.
The aim of this observational study is to compare the prognostic outcomes of various PCI strategies in elderly patients with complex coronary calcified lesions. The patients will be classified into two groups and assigned different PCI strategies, either stenting or stenting combined with pharmacologic balloon implantation. The investigators will assess the one-year prognosis for major adverse cardiovascular events in these patients.
This Phase 2a clinical trial will evaluate the effectiveness, safety, and tolerability of increasing dose strengths of an oral daily medication, DFV890, administered for 12 weeks, or a single s.c. dose of MAS825, to reduce key markers of inflammation related to CVD risk, such as IL-6 and IL-18, in approximately 28 people with known coronary heart disease and TET2 or DNMT3A CHIP (VAF ≥2%).
This study will test a controlled investigation of the efficacy and effectiveness of iATROS digital therapy management for risk factor adjustment in patients with coronary heart disease (CHD).
This Phase 2a clinical trial will evaluate the effectiveness, safety, and tolerability of increasing dose strengths of an oral daily medication, DFV890, administered for 12 weeks, to reduce key markers of inflammation related to CVD risk, such as IL-6 and IL-18, in approximately 24 people with known heart disease and an elevated marker of inflammation, hsCRP.
The study aims to assess the effect of smart watches and continuous glucose measuring devices on cardiovascular risk factors.
This project is part of the ACHIEVE GREATER (Addressing Cardiometabolic Health Inequities by Early PreVEntion in the GREAT LakEs Region) Center (IRB 100221MP2A), the purpose of which is to reduce cardiometabolic health disparities and downstream Black-White lifespan inequality in two cities: Detroit, Michigan, and Cleveland, Ohio. The ACHIEVE GREATER Center will involve three separate but related projects that aim to mitigate health disparities in risk factor control for three chronic conditions, hypertension (HTN, Project 1), heart failure (HF, Project 2) and coronary heart disease (CHD, Project 3), which drive downstream lifespan inequality. All three projects will involve the use of Community Health Workers (CHWs) to deliver an evidence-based practice intervention program called PAL2. All three projects will also utilize the PAL2 Implementation Intervention (PAL2-II), which is a set of structured training and evaluation strategies designed to optimize CHW competence and adherence (i.e., fidelity) to the PAL2 intervention program. The present study is Project 3 of the ACHIEVE GREATER Center.
Assess the usability and acceptance of the P-STEP app, through allowing participants with specific chronic conditions to pilot the app for 12-weeks.