key: cord-0781414-8r79785m
authors: Koch, Vitali; Gruenewald, Leon D.; Albrecht, Moritz H.; Eichler, Katrin; Gruber-Rouh, Tatjana; Yel, Ibrahim; Alizadeh, Leona S.; Mahmoudi, Scherwin; Scholtz, Jan-Erik; Martin, Simon S.; Lenga, Lukas; Vogl, Thomas J.; Nour-Eldin, Nour-Eldin A.; Bienenfeld, Florian; Hammerstingl, Renate M.; Graf, Christiana; Sommer, Christof M.; Hardt, Stefan E.; Mazziotti, Silvio; Ascenti, Giorgio; Versace, Giovanni Antonio; D'Angelo, Tommaso; Booz, Christian
title: Lung Opacity and Coronary Artery Calcium Score: A Combined Tool for Risk Stratification and Outcome Prediction in COVID-19 Patients
date: 2022-02-28
journal: Acad Radiol
DOI: 10.1016/j.acra.2022.02.019
sha: 57193f50e5c7115f9ee6e2a6c126b73a45c59249
doc_id: 781414
cord_uid: 8r79785m

Purpose: To assess and correlate pulmonary involvement and outcome of SARS-CoV-2 pneumonia with the degree of coronary plaque burden based on the CAC-DRS classification (Coronary Artery Calcium Data and Reporting System). Methods: This retrospective study included 142 patients with confirmed SARS-CoV-2 pneumonia (58 ± 16 years; 57 women) who underwent non-contrast CT between January 2020 and August 2021 and were followed up for 129 ± 72 days. One experienced blinded radiologist analyzed CT series for the presence and degree of calcified plaque burden according to the visual and quantitative HU-based CAC-DRS score. Pulmonary involvement was automatically evaluated with a dedicated software prototype by another two experienced radiologists and expressed as Opacity Score. Results: CAC-DRS Scores derived from visual and quantitative image evaluation correlated well with the Opacity Score (r=0.81, 95% CI 0.76 to 0.86, and r=0.83, 95% CI 0.77 to 0.89, respectively; p<0.0001) with higher correlation in severe than in mild stage SARS-CoV-2 pneumonia (p<0.0001). Combined, CAC-DRS and Opacity Scores revealed great potential to discriminate fatal outcomes from a mild course of disease (AUC 0.938, 95% CI 0.89 to 0.97), and the need for intensive care treatment (AUC 0.801, 95% CI 0.77 to 0.83). Visual and quantitative CAC-DRS Scores provided independent prognostic information on all-cause mortality (p=0.0016 and p<0.0001, respectively), both in univariate and multivariate analysis. Conclusions: Coronary plaque burden is strongly correlated to pulmonary involvement, adverse outcome, and death due to respiratory failure in patients with SARS-CoV-2 pneumonia, offering great potential to identify individuals at high risk.

Since the first case of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) in December 2019, the novel coronavirus has spread rapidly across the globe [1] . While most infected patients remain asymptomatic or present mild symptoms, SARS-CoV-2 is capable to cause respiratory distress syndrome and multiorgan failure, ultimately requiring ventilation support and intensive care [2] .

Previous studies reported an underlying cardiovascular disease in up to 50% of patients with SARS-CoV-2, which was associated with adverse outcome and higher mortality [3] [4] [5] . However, potential mechanistic pathways responsible for fatal outcomes in patients with cardiovascular history remain incompletely understood [6] [7] [8] . Identification of patients at risk therefore represents one of the most important goals to prevent complications arising from a delayed treatment.

Over the past decade, many scoring systems have been developed to facilitate standardized reporting and management of different diseases, offering specific treatment recommendations according to disease severity [9; 10] . Regarding the evaluation of coronary artery calcium (CAC), the CAC-DRS (Coronary Artery Calcium Data and Reporting System) reporting system was established [11] . CAC scanning is part of the risk assessment to prevent atherosclerotic cardiovascular disease offering a direct evaluation of coronary calcified plaque burden [12] . Per 2019 ACC/AHA Guideline on the Primary Prevention of Cardiovascular Disease, CAC testing is recommended for asymptomatic individuals at the age of 40-75 years with intermediate risk for atherosclerotic cardiovascular disease or selectively in patients with borderline risk who show a family history of premature coronary artery disease [12; 13] . In this context, accumulating evidence points to a pivotal role of CAC for predicting outcomes of SARS-CoV-2 patients with coronary heart disease or heart failure [5; 8; 14-16] . To the best of our knowledge, no previous study has examined the value of CAC-DRS reporting in risk assessment and outcome prediction in patients suffering from SARS-CoV-2 pneumonia.

As such, it is tempting to speculate that risk classification of patients according to the CAC-DRS Score might correlate with disease severity of SARS-CoV-2 pneumonia and facilitate classification of patients into different risk groups. Thus, the purpose of this study was to quantitatively assess pulmonary involvement and to evaluate the prognostic value of the CAC-DRS reporting system in patients with SARS-CoV-2 pneumonia.

The institutional ethical review board approved this retrospective study, which comply with the Declaration of Helsinki. Written informed consent was waived.

A total of 158 patients with confirmed SARS-CoV-2 on reverse transcriptionpolymerase chain reaction and corresponding clinical symptoms who had undergone non-contrast chest CT scans between January 2020 and September 2021 were candidates for study inclusion. Indications to perform non-contrast CT scans included severity assessment of SARS-CoV-2 pneumonia, searching after complications of SARS-CoV-2 due to persistent symptoms, and position control of implanted central venous catheters. The study was performed at two sites, the *BLINDED* and the *BLINDED*. Searching for appropriate patients was performed on PACS (picture archiving and communication system) and internal patient database using the following terms: 'SARS-CoV-2', 'COVID-19', and 'pneumonia'. Exclusion criteria were artefacts (e.g., due to dorsal instrumentation, insufficient image quality, or excessive pleural effusion), implanted coronary stents, previous coronary artery bypass grafting, and patient age <18 years.

Data about demographics, symptoms, laboratory, hospital stay, and outcomes were obtained from medical reports. Extracted laboratory values included hs-Troponin T (hs-TnT), N-terminal pro brain natriuretic peptide (NT-proBNP), leucocytes, C-reactive protein, and procalcitonin. All values were determined at the peak of symptoms and analyzed with regards to possible correlations with the automated quantification of lung opacities and coronary plaque burden. Follow-up was performed by extracting outcome information from all available databases, including internal hospital files and data from collaborating clinics, and analyzed for the endpoint death. Follow-up time was not limited to a defined number of days and comprised all available information.

Non-contrast chest CT scans were conducted in craniocaudal scan direction on a third-generation dual-source dual-energy CT scanner (Somatom Force;

Siemens Healthineers, Forchheim, Germany), and on a 128-slices multislice CT scanner (Somatom Definition AS, Siemens Healthineers, Forchheim, Germany). All scans were not ECG-gated and performed using a conventional protocol with the following parameters: 120 kV, 70 mAs 0,6 mm slice thickness, and 1 mm collimation.

For evaluation of SARS-CoV-2 pneumonia, axial, coronal, and sagittal (slice thickness of 1 mm, interscan spacing 1.5 mm) images were reconstructed from each CT scan. Three-dimensional visualization and quantification of SARS-CoV-2 related lung abnormalities was performed using a previously described software prototype [6] . Briefly, the software allowed for automated segmentation and calculation of pneumonic densities, such as consolidations and ground glass opacities, which are finally displayed as Opacity Score with a corresponding lung severity score. In this context, maximal density of opacities was defined by a threshold of -200 Hounsfield Units (HU). The software was developed and constructed for research purposes by using algorithms based on artificial intelligence [6; 17] . The Opacity Score ranged from 0-20 relative units (RU), representing all affected areas from both lungs. A value of zero indicates no pulmonary involvement, while an Opacity Score of 20 is associated with the maximal pulmonary opacification of both lungs. Each automated examination of lung opacities was proven and confirmed by two radiologists (*BLINDED*, board-certified radiologist with 5 years of experience, and *BLINDED*, board-certified radiologist with 6 years of experience) in consensus sessions.

Automated postprocessing of lung opacities is illustrated in Figure 1 showing example axial and coronal grayscale CT images from a 51-year-old male with SARS-CoV-2 pneumonia at a moderate level (9.4 RU).

For the assessment of CAC, images were reconstructed with the following parameters: section thickness 3 mm, interscan spacing 1.5 mm, field of view (FOV) limited to the heart of 18 cm. CAC-DRS categories were subjectively assessed by applying a visual score as well as objectively by using a HU-based quantitative score (referred to as visual and quantitative analysis in the manuscript). Regarding the visual assessment of coronaries, one radiologist (*BLINDED*, board-certified radiologist with 8 years of experience) analyzed each coronary artery for the presence and extent of CAC using a visual scale ranging from V0 to V3. Hereby, a CAC-DRS category of V0 indicates no CAC with very low risk, a score of V1 mild coronary affection with mildly increased risk, V2 moderate CAC with moderately increased risk, and a score of V3 severe coronary calcium with high risk [11] . The quantitative HU-based score represents a semi-automated tool to objectively assess the extent of CAC, where 0 is assigned to a CAC-DRS category of A0, a score of 1-99 to A1, 100-299 to A2, and a score of > 300 to A3 [11] . For the quantitative evaluation of CAC, the region of interest was manually placed in each coronary artery with subsequent automatically calculated CAC for each coronary and in total by summation of all scores, as previously described [18] [19] [20] [21] . Software-based automated calculation was performed by applying a threshold of 130 HU within ≥3 contiguous pixels, resulting in a minimum area of 1.05 mm 2 .

All postprocessing steps were performed on a commercially available workstation (syngo.via, version VB10B; Siemens Healthineers). The three radiologists could freely modify window settings and scroll through the whole stack of CT scans. No case required manual adjustment of opacity areas that were not correctly recognized by the automated software prototype. After each examination, overall assessment time of image analysis was noted.

Commercially available software was used for statistical analysis (MedCalc for Windows, Version 13; MedCalc). Normal distribution of datasets was assessed by using the Kolmogorov-Smirnov and Shapiro-Wilk test. Results are expressed as mean ± standard deviation (SD), count (percentages), or median (interquartile range, IQR), where appropriate. Comparisons between continuous variables were conducted using one-way ANOVA, chi-square statistic tests, or two-tailed Student's ttest, where appropriate. Pearson's correlation was used to test the association between SARS-CoV-2 opacities and clinical or laboratory parameters. An r value of less than 0.40, 0.41-0.60, 0.61-0.80 and >0.80 was considered as poor, moderate, strong, and very strong, respectively. Cox regression analysis was performed to explore independent factors associated with CAC-DRS Score of patients with SARS-CoV-2 considering all parameters. Those with p<0.05 in univariate analysis were transferred into the multivariate linear regression model. Receiver operating characteristic (ROC) curves were plotted and areas under the curves (AUCs) were calculated together with their 95% confidence intervals (95% CI). The diagnostic performance was calculated for every single score as well as for the combination of them, which was defined as the Composite Score. Interrater agreement was assessed by using weighted κ statistics [22] , where values of <0, <0.20, 0.21-0.40, 0.41-0.60, 0.61-0.80, and >0.80 were regarded as poor, slight, fair, moderate, substantial, and excellent, respectively. A p<0.05 was considered statistically significant.

A total of 142 patients (58 ± 16 years; range, 21-87), consisting of 85 men (60%; 57 ± 14 years; range, 28-81) and 57 women (40%; 59 ± 18 years; range, 21-87), were included in the study. The time gap between admission, clinical evaluation, laboratory test sampling, and CT scanning was 18 ± 4 hours for all enrolled patients. 16 patients had previously been excluded due to large pleural effusion (11 patients Interestingly, the need for ventilation was positively associated with the extent of coronary plaque burden (54% of patients with CAC-DRS Score of 3 vs. 15% with a Score of 0). The rate of comorbidities was significantly lower in patients who survived (23% vs. 77%, p=0.036), particularly with regards to arterial hypertension, family history, and smoking. Of the 28 deaths, 21 patients died because of respiratory failure, 6 patients due to cardiogenic shock, and 1 patient due to gastric hemorrhage.

Baseline characteristics of patients with SARS-CoV-2 are depicted in Table 1 .

Characteristics of imaging scores are displayed in Table 2 . Opacities were present in all CT scans with an Opacity Score ranging from 0.58 to 19.74 RU. The overall Opacity Score comprising both lungs was 7.5 ± 4.5 RU, where patients with a visual CAC-DRS Score of V3 (12.4 ± 3.2 RU) revealed higher opacities than patients with a score of V2 (8.5 ± 2.9 RU), V1 (5.4 ± 2.9 RU), and V0 (2.9 ± 1.9 RU) (all 

Visual and quantitative evaluation of calcified plaque area were highly correlated to the Opacity Score (r=0.81, 95% CI 0.76 to 0.86 for visual, and r=0.83, 95% CI 0.77 to 0.89 for quantitative score, respectively; p<0.0001), without significant difference between the two correlation coefficients (p=0.3504). Bivariate correlation analysis revealed not only a significant correlation of the Opacity Score with the visual CAC-DRS Score, but also with hs-TnT (r=0.58, 95% CI 0.51 to 0.65; p<0.0001) and parameters of inflammatory response like C-reactive protein (r=0.53, 95% CI 0.49 to 0.57; p<0.0001), procalcitonin (r=0.59, 95% CI 0.54 to 0.64), and leucocytes p=0.0404), which is expressed as the Composite Score in Figure 5 .

Combining the Opacity Score with both CAC-DRS Scores allowed for a good discrimination of patients that required intensive care treatment with an AUC of 0.801 (95% CI 0.77 to 0.83). Cox-regression revealed that the visual and quantitative CAC-DRS Score provide independent prognostic information for death (p=0.0016 and p<0.0001, respectively). Results remained significant after adjustment for potential confounders that have been identified in the univariate analysis (Table 3) . Determination of CAC on CT scans was found to be a robust predictor of cardiovascular events in asymptomatic patients, especially in those at intermediate risk [12] . According to the 2017 Expert Consensus Statement from the Society of Cardiovascular Computed Tomography (SCCT), measurement of CAC is recommended in case of an atherosclerotic cardiovascular disease 10-year risk ranging between 5 and 20% as well as in selected patients showing a family history of premature coronary artery disease at values inferior to 5% [12] . Clear management strategies are of particular importance since, as the SARS-CoV-2 pandemic revealed, even mild cases are at increased risk for adverse outcomes.

Pneumocytes are primarily vulnerable for SARS-CoV-2, which makes the pulmonary status of patients to the principal determinant of disease severity and outcome [25] . As early abnormalities remain often hidden on chest X-rays with a which enabled successful rule-out of severe pulmonary involvement of disease with a high negative predictive value of 96.3% [28] . Other studies found similar radiological manifestation patterns using the semiquantitative assessment method, such as peripheral distribution, crazy-paving pattern, involvement of lower parenchymal areas of lung, or reticulation patterns after recovery [7; 29-32] . The concept of standardized and structured reporting of diseases through comprehensive documents has become increasingly important to provide data collection from different international centers and facilitate uniform patient management by closing knowledge gaps about outcome data across all populations [11] .

Our study clearly demonstrates first that the composite score of lung opacities and the degree of coronary plaque burden according to the visual or quantitative HUbased CAC-DRS Score is able to predict all-cause mortality during a follow-up period of 129 ± 72 days. The predictive value has to be underlined as the most striking aspect of our study results. In this context, quantitative CAC assessment based on measurement of Hounsfield Units allowed for a slightly more precise outcome prognosis than the visual assessment of coronary calcifications (p<0.0001 vs.

p=0.0016, respectively). High coronary plaque burden is associated with more severe pulmonary manifestations of SARS-CoV-2 pneumonia, expressed as percentual affection of both lungs. In accordance with previous studies [3-5; 8; 14-16; 33] , patients with coronary artery disease were prone to a complicated clinical course, including the need for intensive care treatment, an increased risk for mechanical ventilation, the use of vasoactive agents, and higher mortality. A high CAC-DRS score in patients with SARS-CoV-2 pneumonia may therefore reflect an ongoing inflammatory cascade with susceptibility to complications and higher mortality. Dillinger et al. described first that the extent of coronary artery calcifications is associated with a worse outcome in hospitalized patients with COVID-19 using the Agatston scoring on non-cardiac gated CT chest [14] . Although the evaluation of CAC is traditionally conducted using ECG synchronization, our findings suggest a good correlation between CAC and outcome using non-gated chest CT scans in accordance with previous publications [15; 18-21; 34; 35] . Regarding possible cardiac motion artifacts in chest CT scans without ECG synchronization, our included examinations were not significantly affected by motion artifacts facilitating accurate evaluation of coronary plaque burden.

In a clinical context, the combined assessment of CAC and pulmonary involvement of SARS-CoV-2 consolidations in non-dedicated, non-gated chest CT scans adds incremental prognostic information allowing for cardiovascular risk stratification without additional costs. Therefore, this combined approach may represent an elegant method in daily clinical routine to save radiation exposure by avoiding specific cardiac CT scans. Furthermore, patient comfort can considerably be increased obviating the need for repeated transport of immobile patients.

CAC scoring is a simple, highly reproducible tool for assessment of atherosclerotic diseases providing tailored personalized therapy [11; 13] . It offers a direct objective assessment of coronary plaque burden and may therefore assist in evaluating the individual optimal therapeutic guidance. In combination with the reported opacity score, this novel assessment tool may be especially useful for intermediate-risk patients with SARS-CoV-2 pneumonia who fall into grey zones where frequently only epidemiological or empirical data are used to provide further guidance in therapy.

Given its high predictive value, CAC scanning might motivate patients to change their lifestyle and to raise their awareness regarding potential complications, such as myocardial infarction. In a prospective randomized trial with 2,137 middleaged study participants and a meta-analysis of 11,256 patients from six studies, randomization to CAC scanning was associated with superior control of cardiovascular risk factors and a higher likelihood of continuation of cardioprotective medical therapy and lifestyle modification [36; 37] . However, CAC scanning might not only be useful in estimating net benefits from preventive pharmaceutical treatment, but also in providing therapeutic goals and subsequent regulation of treatment intensity in patients suffering from SARS-CoV-2 pneumonia.

This study had several limitations. First, our examinations were conducted as a retrospective study with a limited number of patients. Validation of our study findings in larger patient cohorts is required. Second, the automated determination of Opacity Score using a software prototype assumed the extent of pulmonary opacities as a surrogate for the severity of SARS-CoV-2 pneumonia without histological confirmation. Third, the automated evaluation of chest CT scans was performed at different stages of SARS-CoV-2 pneumonia, which potentially has led to over-or underestimation of disease severity. Fourth, laboratory parameters were collected only at the peak of symptoms without considering dynamic changes over time. Fifth, our study findings are currently only reproducible on a dedicated vendor-specific CT setup with the possibility for postprocessing of chest CT scans. Therefore, our results may not be transferable to devices and technologies merchandised by other manufacturers. Sixth, CT scans were performed during the peak of SARS-CoV-2 pneumonia which possibly has led to inclusion of more patients with severe disease than those with milder symptoms. Finally, though we have thoroughly checked all databases for follow-up data, 14 patients were lost to follow-up.

To summarize, the present study shows that the degree of coronary artery plaque burden based on the CAC-DRS classification correlates well with the severity of SARS-CoV-2 pneumonia and provides independent prognostic information on allcause mortality. Furthermore, the CAC-DRS classification facilitates high diagnostic performance to discriminate patients at risk for complicated courses of disease from those with mild outcomes. Therefore, measurement of CAC in not ECG-gated chest-CT scans of patients with SARS-CoV-2 pneumonia may assist physicians in clinical decision making by allocating patients to a certain risk category. 

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Extensive affection of lung parenchyma on both sides is shown in axial (1A), coronal (1B), and sagittal (1C) grayscale CT images. Figure 2 shows 3-vessel involvement of coronary artery sclerosis. CAC score was increased

Abbreviations: SARS-CoV-2, severe acute respiratory syndrome coronavirus type 2. RU, relative unit

PCI, percutaneous intervention. LAD, left anterior descending. CAC, coronary artery calcium. CAC-DRS, Coronary Artery Calcium Data and Reporting System. RCA, right coronary artery. Cx