Validation of Quantitative Myocardial Tissue Characterization Through Non-gated CT

Patients scheduled to undergo contrast-enhanced cardiac CT and meeting inclusion criteria will be proposed enrolment in the study, and as such they will be informed on the study aims and design and will be invited to sign a specific informed consent. All potential enrollees will be invited to undergo an additional CT acquisition as part of their cardiac CT examination, to estimate CT-MRE, blood tests, and a contrast-enhanced CMR scan. All those meeting exclusion criteria (contraindications to CMR, previous allergic reactions to gadolinium-based contrast agents, pregnancy, severe obesity, claustrophobia) will be consequently excluded from the study. Patients with a previous diagnosis of COVID-19 will not be excluded if they are declared negative according to the procedure provided for by the regulations in force.

For all those eventually included to participate in the study, the CT examination will include the addition of a non-gated 5-min delayed acquisition, allowing the assessment of CT-MRE. All enrolled patients will then undergo blood tests including the assessment of haematocrit for the calculation of ECV and CT-MRE, and serological testing for COVID-19 antibodies. An additional blood sample (for a total of 30 ml of venous blood) will be tested for myocardial fibrosis biomarkers (Troponin, Osteopontin, ST, and Osteocalcin), and the remaining samples will be long-term bio-banked pending patients' approval.

All enrolled patients will then undergo a CMR examination within 10 days of the cardiac CT scan, including the intravenous administration of a macrocyclic gadolinium-based contrast agent, including cine sequences for myocardial function and strain assessment, and native- and contrast-enhanced T1 mapping for myocardial ECV calculation.

Myocardial CT-MRE and CMR-derived ECV calculation will be conducted according to methods previously described by the two centres. All CT and CMR exams will be anonymized, and segmentation for such purposes will be performed by readers with extensive experience in cardiovascular CT and CMR. Additionally, myocardial strain will be calculated from CMR cine sequences, through dedicated software.

Taking into consideration the known correlation between CT- and CMR-derived ECV and given the correlation between CT-MRE and CT-derived ECV noted in a previous study from our group, we would expect the coefficient of the correlation between CT-MRE and CMR-derived ECV not to be lower than 0.3. On these grounds, aiming for an α error of 0.05 and a statistical power (1 - β) of 0.90, we would require a sample size of 113 patients for our principal aim. Considering a potential maximum dropout rate around 40% (mostly due to the refusal to undergo CMR on a subsequent date from cardiac CT), we aim to enrol 188 patients for our study.

Normality will be evaluated using Shapiro-Wilk test. In case of normal distribution, t-tests will be used to assess differences between groups, and Pearson's r will be used for correlations. In case of non-normal distributions, Mann-Whitney and Wilcoxon tests will be used to assess differences, and Spearman's ρ for correlations. P-values ≤0.05 will be considered as indicative of statistical significance.