key: cord-0695272-o9z2yown authors: Slipczuk, Leandro; Castagna, Francesco; Schonberger, Alison; Novogrodsky, Eitan; Dey, Damini; Jorde, Ulrich P.; Levsky, Jeffrey M.; Di Biase, Luigi; Garcia, Mario J. title: Incidence of new-onset atrial fibrillation in COVID-19 is associated with increased epicardial adipose tissue date: 2021-07-07 journal: J Interv Card Electrophysiol DOI: 10.1007/s10840-021-01029-4 sha: 35754e8c04a40d958411e3faa39cbfb3014023a1 doc_id: 695272 cord_uid: o9z2yown PURPOSE: Coronary artery calcium (CAC) and epicardial adipose tissue (EAT) can predict AF in the general population. We aimed to determine if CAC and EAT measured by computed tomographic (CT) scanning can predict new-onset AF in patients admitted with COVID-19 disease. METHODS: We performed a retrospective, post hoc analysis of all patients admitted to Montefiore Medical Center with a confirmed COVID-19 diagnosis from March 1st to June 23rd, 2020, who had a non-contrast CT of the chest within 5 years prior to admission. We determined ordinal CAC scores and quantified the EAT volume and examined their relationship with inpatient mortality. RESULTS: A total of 379 patients were analyzed. There were 16 events of new-onset AF (4.22%). Patients who developed AF during the index admission were more likely to be male (75 vs 47%, p < 0.001) and had higher EAT (129.5 [76.3–197.3] vs 91.0 [60.0–129.0] ml, p = 0.049). There were no differences on age (68 [56–71] vs 68 [58–76] years; p = 0.712), BMI (28.5 [25.3–30.8] vs 26.9 [23.1–31.8] kg/m(2); p = 0.283), ordinal CAC score (3 [1–6] vs 2 [0–4]; p = 0.482), or prevalence of diabetes (56.3 vs 60.1%; p = 0.761), hypertension (75.0 vs 87.3%, p = 0.153), or coronary artery disease (50.0 vs 39.4%, p = 0.396). Patients with new-onset AF had worse clinical outcomes (death/intubation/vasopressors) (87.5 vs 44.1%; p = 0.001). CONCLUSION: Increased EAT measured by non-contrast chest CT identifies patients hospitalized with COVID-19 at higher risk of developing new-onset AF. Patients with new-onset AF have worse clinical outcomes. Coronavirus disease , caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has rapidly spread globally. Although most cases recover, COVID-19 still appears to retain an elevated mortality with the number of deaths escalating to over 2.5 million worldwide through March 2021 [1] . Initial reports from China suggested an incidence of COVID-19 arrhythmias of 17% with higher incidence in patients admitted to the ICU (up to 44%) [2] . Further studies in different populations showed an incidence of new onset AF of around 4-8% [3, 4] . Consequences of AF in COVID-19 are still uncertain; some authors reported possible worse outcomes [5] , whilst others did not [6] . Computed tomographic (CT) scanning can be used to detect and quantify visceral fat. In the past few years, epicardial adipose tissue (EAT) has attracted a lot of interest as an independent risk factor for new-onset AF, possibly due to pro-inflammatory cytokines and fibrosis of the atrial myocardium [7, 8] . EAT is a metabolically active fat depot that makes up for approximately 20% of total heart weight, lies between serous epicardium and the fibrous pericardium, and can be quantified from non-gated non-contrast chest CT [9] . CT scanning can also identify the presence and extent of coronary atherosclerosis. The coronary artery calcification scoring (CAC) is an established and extensively validated imaging biomarker for cardiovascular risk, allowing enhanced risk reclassification for the prediction of all cause and cardiac specific mortality in asymptomatic subjects [10] . Moreover, CAC at a single time point and its progression have been associated with an increased risk for AF [11] . Although the traditional Agatston method for measuring CAC requires ECG-gated acquisition, good correlation has been demonstrated between CAC identified on non-gated CT scans and ordinal scores obtained from gated CT scans [12] . Our hypothesis was that EAT and/or CAC, as markers of a pro-inflammatory milieu and coronary atherosclerosis, respectively, are predictors of new-onset AF during COVID-19 hospitalization. As many patients hospitalized with COVID-19 currently undergo chest CT examinations, EAT analysis could be readily available and provide additional clinical value for appropriate monitoring. We conducted a retrospective, post hoc analysis of all patients who were admitted to Montefiore Medical Center with a confirmed COVID-19 diagnosis by polymerase chain reaction (PCR) from March 1st to June 23rd, 2020. Sample for RT-PCR was obtained by either nasopharyngeal or oropharyngeal swab. The follow-up period was from March 1st to June 26th, 2020. Patients who had a non-contrast CT of the chest at our facility after March 1st, 2015, constituted the main study cohort. Baseline demographic, clinical, and laboratory variables (including inflammatory biomarkers) were retrieved from our electronic medical record system. Baseline characteristics and outcomes were compared with patients who were admitted with COVID-19 but did not have a CT study performed. The investigators had direct access to primary data. The study was approved by our Institutional Review Board (Office of Human Research Affairs at Albert Einstein College of Medicine). Patients were imaged on the following CT scanners without contrast administration or electrocardiographic gating: GE Optima 660, GE Lightspeed VCT, Neurologica Corp Caretom, Siemens Somatom Sensation 16, and GE Optima CT 540. Images were reconstructed at 2.5 mm slice thickness. Scans with reconstructions at different slice thickness were excluded. Two readers blinded from clinical data calculated ordinal scores from standard non-gated chest CT studies using the methods described by Shemesh et al. for patients without history of myocardial revascularization [12] . Briefly, the right coronary artery, left main, left anterior descending, and left circumflex arteries were each given a score of 0-3 for presence and extent of calcium with 0 (none), 1 (< 1/3 of the artery length calcified), 2 (≥ 1/3 to < 2/3 calcified), and 3 (≥ 2/3 calcified). These scores were summed across the 4 arteries, providing a range of possible scores from 0 to 12 (see Fig. 1A and B). We calculated the inter-observer variability based on a random sample. Agreement for severity class was high (interclass correlation coefficient = 0.980, p < 0.001). For the measurement of EAT, we used QFAT software. As previously described [13] , QFAT uses convolutional deep learning for fully automated quantification of epicardial and thoracic volumes. Accuracy and reproducibility of QFAT have been previously validated [14, 15] . Contours were reviewed by an expert user and manually modified when needed. Superior and inferior limits of the pericardium were identified as the bifurcation of the pulmonary trunk and the posterior descending artery, respectively. EAT was defined as adipose tissue within the pericardium (see Fig. 1C ). Patients with significant artifacts from ICDs or poor acquisition were excluded. Continuous data are displayed as mean ± standard deviation or median (25-75% interquartile range) and compared with the Student's t-test, or Wilcoxon ranks-sum, as appropriate. Categorical data are presented as percent and compared by the chi-squared test. A binomial logistic regression was performed to ascertain the effect of CAC and EAT on the likelihood of developing AF. Kaplan-Meier survival analysis and log rank were conducted to compare the freedom from the composite event of intubation, pressor need, or death. June 26th, 2020, was the end of the censoring period. A p < 0.05 was considered statistically significant. Statistical analysis was performed with SPSS (IBM Corp, ver. 25, Armonk, NY). From 4311 patients who were hospitalized at Montefiore between March 1st and June 23rd, 2020, with confirmed COVID-19 by PCR, we identified 504 patients who had a non-contrast chest CT performed during or within 5 years prior to admission. A total of 125 patients were excluded, 114 due to prior AF, and 11 due to uninterpretable CT. A total of 379 patients were finally included for analysis. Overall median age was 68 (IQR 58-76) years, 48.3% were male, and 39.3% Hispanic. Diabetes (DM) (59.9%), hyperlipidemia (70.7%), and hypertension (86.8%) were highly prevalent, whereas CAD and asthma/COPD were present in < 50% of patients (39.8 and 49.5%, respectively). There was no difference on CHA 2 DS 2-VASc score between the group without and with new-onset AF (4 [3] [4] [5] . Incidence of new-AF for the cohort without prior CT was not significantly different when compared to the group without prior CT lower than one with prior CT (4 vs 5%; p = 0.987). Our cohort also had no difference in mechanical ventilation (23.9 vs 21.5%; p = 0.213) but higher requirement for pressors (23.9 vs 19.1%; p = 0.012), and death rates (40.0 vs 28.2%; p < 0.001). Ordinal CAC score was calculated in 379 patients. CAC > 0 was present in 231 patients with 116 patients having mild (1-3), 72 moderate (4-6), and 43 severe (7-12) CAC with an overall population median CAC score of 2 (IQR 0.0-4.3). There was no difference in CAC score between the newonset and no AF groups ( EAT was calculated in 357 patients. Median volume in the overall population was 92 ml (60-130 ml). Patients who developed Afib had a higher EAT compared to the patients who did not ( Fig. 3B The main finding in our study is the association of EAT with new-onset AF in a large cohort of patients admitted with COVID-19. Moreover, in our study, patients with new-onset AF showed worse clinical outcomes. To our knowledge, this represents the first study to show an association of EAT with new-onset AF in COVID-19 patients. We showed that the group with new-onset AF had worse clinical outcomes with higher composite of intubation/pressors/death (Fig. 2) and higher EAT (Fig. 3B) . Also, for each ml increase in EAT, new-onset AF increased by 0.8%. On a regression model, EAT > median has a HR = 3.8, p = 0.042. Moreover, both higher CAC and EAT predicted worse clinical outcomes (Fig. 4) . A number of published papers have investigated the relation between AF and clinical outcomes in patients with COVID-19; however, the results have not been consistent. Our results show that new-onset AF in particular could also be linked to adverse outcomes. Population studies have established increased body mass index as a predictor of AF [16] . However, heterogeneity of fat distribution could explain differences in AF within same BMI [17] . It has been demonstrated that EAT is a metabolically active fat with its own ganglionated plexi. Multiple studies have found a prognostic role of EAT for new-onset, persistent AF, and clinical outcomes. A meta-analysis by Wong et al. involving 352,275 individuals found a strong and graded association with each increase of 1-SD associated with 2.6-fold higher odds of AF [18] . Moreover, the association was greater than for measures of abdominal or overall adiposity. Possible mechanisms include fatty infiltration [19] , atrial myocardial fibrosis (possibly through secretion of TGF-β) [20] , local inflammation [21] , oxidative stress [22] , adipocyte-related gene expression [23] , autonomic dysfunction [24] , and diastolic dysfunction [25] . Gauss et al. found a significant association between CAC, EAT, and systemic inflammatory markers [26] . Severity of COVID-19 infection has been associated to an immune dysregulation. In particular, monocytes from COVID-19 patients have sustained expression of the cytokines tumor necrosis factor (TNF) and interleukin-6 (IL-6) [27] . Mazurek et al. found that EAT is a source of several inflammatory mediators in high-risk cardiac patients with local expression of monocyte chemotactic protein (MCP)-1, IL-6, and TNF-α [28] . Moreover, ACE2 internalization after binding with COVID-19 results in a reduction of ACE2 in the cell surface. Loss of ACE2 promotes EAT inflammation, pericarditis, and the development of pericardial effusion, all of which may predispose to the development of AF [29] . It is also known that baseline pro-inflammatory risk factors (such as diabetes, hypertension, CAD, and COPD) B A Fig. 4 Clinical outcomes for CAC ≥ 4, EAT ≥ median. Kaplan-Meier curves show freedom from intubation/pressor/death in days according to CAC score (A) and EAT (B). p = 0.001 for both exacerbate the cytokine storm related to severe cases of COVID-19 [30] . We showed here that EAT, possibly through a pro-inflammatory local response, has predictive value of new-onset AF in patients admitted with COVID-19. The most accurate imaging technique to assess epicardial fat burden is volumetric quantification [17] . Measurement of EAT by CT has represented in the past a cumbersome process limiting its clinical applicability. Fully automated quantification by QFAT, through the use of a convolutional neural network approach, brings measurement process to a clinically useful and readily available tool with an average quantification time of 1.57 s [15] . Data from multiple cohorts shows that CAC effectively stratifies patients for risk of long-term all-cause and cardiovascular mortality better than traditional risk-factors [10, [31] [32] [33] . Likewise, data from MESA by O'Neal et al. showed that CAC predict incidence of AF [11] . The pathophysiologic link between CAC and AF remains unclear. One possibility is through their common association with cardiovascular risk factors. Imaging studies have shown that patients with higher CAC usually have larger atria and pulmonary veins, anatomical findings which have been associated with development of AF. In the MESA study, presence and progression of CAC seem to be independent predictors of AF [34] . Higher levels of inflammatory biomarkers have also been associated with development of CAC [35] and AF [36] . In our study, however, we did not find an association between CAC and new-onset AF in COVID-19 hospitalized patients. It is possible that the association between AF and coronary atherosclerosis is established over long term and is not relevant in acutely ill patients with respiratory failure. Moreover, van der Hooft et al. have described an association between high-dose corticosteroids and development of AF [37] . Even though the difference in corticosteroids between groups in our study was small, it is possible that this factor played an additional role in new-onset AF. Additionally, CHA 2 DS 2-VASc score has been associated with worse outcomes in COVID-19 [38] . We did not find an association between CHA 2 DS 2-VASc score and new-onset AF. Lastly, it has been suggested that the incidence and associated increase in mortality are not specific to COVID-19 but rather a generalized response to the systemic inflammation of severe viral illnesses [4] . It is therefore possible that our findings could be similarly present in other severe viral illnesses. The inclusion of only patients who had a prior chest CT selected a higher risk population; however, the incidence of new-AF was similar to those without prior CT. Many inflammatory markers were not routinely collected at the beginning of the pandemic and we cannot therefore evaluate their interaction. We did not find an association with the development of AF during COVID-19 admission and CAC. Possible explanations may be the older population in our study given that association in MESA was stronger in younger patients < 62 years of age, and differences in pathophysiologic triggers in patients with acute respiratory failure. Moreover, new-onset AF may be underestimated as not all patient had telemetry monitoring. Finally, our cohort was collected during the earliest period of the COVID-19 pandemic, during which limited therapeutic strategies most likely contributed to worse outcomes. Increased EAT measured by non-contrast chest CT identifies patients hospitalized with COVID-19 at higher risk of developing new-onset AF. Patients with new-onset AF have worse clinical outcomes. Since a significant number of patients hospitalized with COVID-19 currently undergo chest CT examinations, EAT analysis could be readily available and provide additional clinical value. Mortality analyses -Johns Hopkins Coronavirus Resource Center Clinical characteristics of 138 hospitalized patients with 2019 novel coronavirus-infected pneumonia in Wuhan, China COVID-19 and cardiac arrhythmias. Heart Rhythm Atrial fibrillation in patients hospitalized with COVID-19: incidence, predictors, outcomes and comparison to influenza New-onset atrial fibrillation during COVID-19 infection predicts poor prognosis Natural history of COVID-19: Risk factors for hospitalizations and deaths among >26 million U.S. Medicare beneficiaries Epicardial and thoracic fat -noninvasive measurement and clinical implications. Cardiovasc Diagn Ther Pericardial fat is independently associated with human atrial fibrillation Epicardial fat volume measured on nongated chest CT is a predictor of coronary artery disease Coronary artery calcium score combined with Framingham score for risk prediction in asymptomatic individuals Coronary artery calcium and risk of atrial fibrillation (from the multi-ethnic study of atherosclerosis) Ordinal scoring of coronary artery calcifications on low-dose CT scans of the chest is predictive of death from cardiovascular disease The relationship between epicardial fat volume and incident coronary artery calcium Interscan reproducibility of computeraided epicardial and thoracic fat measurement from noncontrast cardiac CT Deep learning for quantification of epicardial and thoracic adipose tissue from non-contrast CT Obesity and the risk of new-onset atrial fibrillation Epicardial fat and atrial fibrillation: current evidence, potential mechanisms, clinical implications, and future directions Associations of epicardial, abdominal, and overall adiposity with atrial fibrillation electroanatomical, and structural remodeling of the atria as consequences of sustained obesity Human epicardial adipose tissue induces fibrosis of the atrial myocardium through the secretion of adipo-fibrokines Relation of proinflammatory activity of epicardial adipose tissue to the occurrence of atrial fibrillation Ascorbate attenuates atrial pacinginduced peroxynitrite formation and electrical remodeling and decreases the incidence of postoperative atrial fibrillation Atrial fibrillation and rapid acute pacing regulate adipocyte/adipositas-related gene expression in the atria Long-Term suppression of atrial fibrillation by botulinum toxin injection into epicardial fat pads in patients undergoing cardiac surgery: one-year follow-up of a randomized pilot study Pericardial fat, intrathoracic fat, and measures of left ventricular structure and function Association of systemic inflammation with epicardial fat and coronary artery calcification Complex immune dysregulation in COVID-19 patients with severe respiratory failure Human epicardial adipose tissue is a source of inflammatory mediators COVID-19 associated atrial fibrillation: incidence, putative mechanisms and potential clinical implications. IJC Heart Vasc Clinical features of patients infected with 2019 novel coronavirus in Wuhan Interplay of coronary artery calcification and traditional risk factors for the prediction of all-cause mortality in asymptomatic individuals Long-Term prognosis associated with coronary calcification. Observations from a registry of 25,253 patients Coronary calcium scoring for long-term mortality prediction in patients with and without a family history of coronary disease Coronary artery calcium progression and atrial fibrillation: the multi-ethnic study of atherosclerosis Associations of inflammatory markers with coronary artery calcification: results from the Multi-Ethnic Study of Atherosclerosis Inflammation as a risk factor for atrial fibrillation Corticosteroids and the risk of atrial fibrillation Atrial fibrillation in patients with COVID-19. Usefulness of the CHA2DS2-VASc score: an analysis of the international HOPE COVID-19 registry