Introduction COVID-19 has been linked to cardiovascular complications, including myocarditis and vascular dysfunction. Cardiac troponin elevation is relatively common in hospitalised patients with COVID-19, but not usually associated with myocarditis. The prevalent rise in cardiac troponin associated with COVID-19 remains largely unexplained. We hypothesised cardiac troponin elevation associated with COVID-19 is linked to systemic vascular injury. Methods This was a prospective, multicentre cohort study in the West of Scotland, involving post-COVID-19 patients enrolled during their hospitalisation or shortly after discharge (CISCO-19; NCT04403607). Convalescent COVID-19 patients underwent comprehensive phenotyping, including blood biomarker analysis and imaging (MRI, Siemens 3.0T PRISMA; CT chest and pulmonary angiography, Canon Aquilion ONE). Myocarditis was adjudicated using the Modified Lake Louise Criteria. Plasma proteomics (SOMAscan) analysed 7,288 proteins at enrolment and 28–60 days The statistical analysis of SOMAscan proteins was performed using R (v4.4.1) and Python (v3.11.5) using the Searchlight2 workflow. Differential gene expression with Benjamini-Hochberg adjustment and pathway analysis (GO-CC) were performed for participants with adjudication available and plasma proteomics at enrolment (n=155) and follow-up (n=154). An adjusted two-tailed pResults Among participants with plasma proteomics (n=155, mean age: 55 years; 43% female), 72 (47%) had a history of cardiovascular disease. A high likelihood of myocarditis was adjudicated in 12.9%. Peak admission troponin (n=192, median=4.00ng/L, IQR=9.0), ranged from 0.5ng/L to 40,404ng/L. There was downregulation of actin and myosin-related pathways figure 1. Myosin light (MYL) proteins (MYL3, MYL5, MYL6, MYL6B, MYL9, MYL11, MYL12A, MYL12B) were downregulated at follow-up. These MYL proteins are expressed mainly in skeletal and vascular smooth muscle cells (Human Protein Atlas v24.0 table 1). At enrolment, differentially expressed MYL proteins were positively correlated with hsTnI (n=208), but did not have a consistent positive correlation with NT-proBNP (n=208). No consistent positive correlations were observed with strain measurements obtained from cardiac MRI, including right (n=155) or left (n=155) ventricular global longitudinal strain, left ventricular circumferential strain (n=154), or radial strain (n=154). Phosphorylated myosin light chain antibody uptake was greater in COVID-19 arterioles (40.1%) versus controls (10.0%, pConclusion This study provides novel insights to explain commonly observed troponin elevations not associated with clinically significant sequelae.
Ang et al. (Wed,) studied this question.
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