Extremes of Coronary Artery Disease and Normality:CAD Extremes

Coronary Artery Disease Clinical Trial

Official title: Extremes of Coronary Artery Disease and Normality: Understanding Novel Causative and Protective Factors in the Development of Coronary Artery Disease (CAD Extremes)

Status Recruiting

Clinical Trial Summary

In the field of cardiovascular medicine, there are two differing groups of patients that remain puzzling to clinicians: patients who are not expected to have coronary artery disease (CAD) yet are diagnosed with significant CAD; and those who are have multiple risk factors for CAD but do not have CAD. Bats exhibit unique phenotypes including long lifespans and likely reduced atherosclerosis. Prior work has identified multiple molecular mechanisms of suppressing the activation of inflammasomes, causally linked to atherosclerosis. The investigators hypothesize there are different molecular markers that confer protection or increased risk for CAD, some of which may be similar to bats. Thus, the aim of this study is to identify molecular markers that contribute to or are protective against acute coronary syndrome (ACS) through analyzing the genetics, peripheral blood and atherosclerotic samples from both extreme patient groups using single-cell RNA sequencing and multi-omics approach. In addition, novel anti-atherosclerotic mechanisms and factors from bat studies will be assessed in the human samples. Identification of novel targets that prevent or cause CAD has the potential to aid in the early identification of high-risk patients and development of new therapeutics to combat this growing epidemic. To conduct this study, patients who have undergone a coronary angiogram or a CT coronary angiogram that fall into the both extremes will be recruited and blood samples will be taken for the above analysis. These will be compared to a group of controls (low risk without disease and high risk with disease).

Clinical Trial Description

Cardiovascular disease (CVD) imposes much mortality and morbidity worldwide. Large population-based studies in Western cohorts (eg. Framingham Heart Study) have formed the foundations of knowledge on the traditional risk factors of cardiovascular disease. Despite this, large gaps in the knowledge of CVD still exist. The clinical conundrum of the extremes of spectrums of CVD continues to baffle clinicians and researchers alike. These include patients without any major cardiovascular risk factors developing acute coronary syndromes (ACS) at a young age. At the other end of the spectrum, there are not uncommonly patients with "full-house" cardiovascular risk factors with minor or no coronary artery disease. Similar to the phenotype observed in patients with risk factors with little coronary artery disease, the animal bats exhibit unique phenotypes including long lifespans and likely reduced atherosclerosis. A study has shown that the animal bats are able to have plaque-free arteries despite being on a high-fat diet with high plasma cholesterol, which are associated to the development of atherosclerosis. The pathogenesis of atherosclerosis has been linked to inflammasome activation, an intracellular multi-protein complexes that engage in innate immune defenses. An inflammasome typically consists of a sensor that detects pathogens or danger signals, an adaptor, and an effector that initiates pro-inflammatory responses. Aberrations in inflammasomes have been causally linked to numerous diseases, including viral infections, autoimmune, metabolic, and neurodegenerative diseases. However, no effective treatment options have been established thus far. Importantly, multiple molecular mechanisms of suppressing the activation of inflammasomes, causally linked to atherosclerosis, have already been identified in bats. These include dampened sensors and complementary regulation of the effector and downstream cytokine , which could be protective factors of atherosclerosis. These make bats excellent model for anti-atherosclerosis research. Recent advancements in technology have led to exciting developments in our understanding of the development and prevention of CVD. The use of "big data" and "deep learning", advancements in genomics, metabolomics, proteomics have the possibility of transforming this field. Recent modern prospective population-based studies (eg. The MURDOCK study) aim to reclassify cardiovascular risk using integrated clinical and molecular biosignatures. However, these studies are based primarily in Western populations. Ethnic differences in CVD exist and currently in Asia, there is a dearth of such advanced data. The aim of this study is thus to identify molecular and inflammasome markers that contribute or are protective against ACS using single-cell sequencing and multi-omics approach, and on top of that, using animal models of bats and mice as comparison to humans. Genomic, metabolomics, proteomics, and scRNA-seq may seek to help answer some of this questions and better improve understanding of the development of CVD, potentially developing novel preventive and management strategies. The specific aims of the project are as follows: To use advanced genomic, metabolomics, proteomic and single-cell RNA sequencing (scRNA-seq) analysis to understand novel factors influencing the development of coronary artery disease, as well as protection against coronary artery disease To assess and validate the novel anti-atherosclerotic mechanisms and factors from bat studies in the human samples To aid in the development of novel preventive and treatment strategies for coronary artery disease. Study population The primary focus will be on two patient groups. Group 1 patients will be recruited to study the novel factors influencing the development of coronary artery disease. This will include patients with known significant coronary artery disease but without any significant major cardiovascular risk factors. Group 2 patients will be recruited to study the novel factors protective against the development of CAD. This will include patients at high risk of developing CAD but no significant CAD a group of controls will be recruited (Group 3 and Group 4) for comparison (high risk with CAD and low risk with no CAD). Participants from Group 4 may be obtained from existing registries/cohorts. Patients will be recruited from two sources: 1. Prospective recruitment from the coronary catheterization lab, CT lab, ward or clinic 2. Retrospective review of angiograms from the coronary catheterization lab and CT coronary angiogram Informed consent will be obtained. If the patient is agreeable to take part, clinical data will be obtained from his medical records. The patient will also be required to fill up a questionnaire on the patient's demographics, lifestyle and medical history etc. Blood will be obtained from the patients for genetic, proteomic, and metabolic screening. Other data will be collected if available as part of routine care. 1. Demographic and clinical characteristics data 2. Quality-of-life, 3. Basic blood investigations. Basic blood investigations include: FBC, renal panel, HbA1c, fasting glucose, LFT, fasting lipids, hs-CRP, ESR, ANA, anti-dsDNA, RF, anticardiolipin antibodies, homocysteine, protein C, protein S, thyroid function tests, etc 4. Investigations: ECG, CT, Echo, MRI, holter, nuclear imaging, etc 5. Biobanking and WGS 6. Metabolomic panel Clinical Follow-up data: 1. Mortality data 2. Stroke/MI/heart failure/Revascularization data 3. Coronary angiograms and other investigations as part of clinical follow up 2. Readmissions 3. Quality of life 4. Costs 5. Other clinical outcomes These will be obtained from medical records or local, hospital or national databases. ;

Related Conditions & MeSH terms

• Coronary Artery Disease
• Coronary Disease
• Myocardial Ischemia

• NCT number: NCT05775445
• Study type: Observational
• Source: National Heart Centre Singapore
• Contact: Aishah Toh
• Phone: 67042282
• Email: aishah.toh@nhcs.com.sg
• Status: Recruiting
• Start date: May 30, 2023
• Completion date: December 2027