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Journal of the American Heart Association: Cardiovascular and Cerebrovascular Disease logoLink to Journal of the American Heart Association: Cardiovascular and Cerebrovascular Disease
. 2022 Jan 20;11(3):e023473. doi: 10.1161/JAHA.121.023473

Cardiac Dysfunction and Arrhythmias 3 Months After Hospitalization for COVID‐19

Charlotte B Ingul 1,2,, Jostein Grimsmo 2, Albulena Mecinaj 3, Divna Trebinjac 2, Magnus Berger Nossen 4, Simon Andrup 4, Bjørnar Grenne 1,5, Håvard Dalen 1,5,6, Gunnar Einvik 7,8, Knut Stavem 7,8,9, Turid Follestad 10, Tony Josefsen 4, Torbjørn Omland 3,8, Torstein Jensen 11
PMCID: PMC9238505  PMID: 35048715

Abstract

Background

The extent of cardiac dysfunction post‐COVID‐19 varies, and there is a lack of data on arrhythmic burden.

Methods and Results

This was a combined multicenter prospective cohort study and cross‐sectional case‐control study. Cardiac function assessed by echocardiography in patients with COVID‐19 3 to 4 months after hospital discharge was compared with matched controls. The 24‐hour ECGs were recorded in patients with COVID‐19. A total of 204 patients with COVID‐19 consented to participate (mean age, 58.5 years; 44% women), and 204 controls were included (mean age, 58.4 years; 44% women). Patients with COVID‐19 had worse right ventricle free wall longitudinal strain (adjusted estimated mean difference, 1.5 percentage points; 95% CI, −2.6 to −0.5; P=0.005) and lower tricuspid annular plane systolic excursion (−0.10 cm; 95% CI, −0.14 to −0.05; P<0.001) and cardiac index (−0.26 L/min per m2; 95% CI, −0.40 to −0.12; P<0.001), but slightly better left ventricle global strain (−0.8 percentage points; 95% CI, 0.2–1.3; P=0.008) compared with controls. Reduced diastolic function was twice as common compared with controls (60 [30%] versus 29 [15%], respectively; odds ratio, 2.4; P=0.001). Having dyspnea or fatigue were not associated with cardiac function. Right ventricle free wall longitudinal strain was worse after intensive care treatment. Arrhythmias were found in 27% of the patients, mainly premature ventricular contractions and nonsustained ventricular tachycardia (18% and 5%, respectively).

Conclusions

At 3 months after hospital discharge with COVID‐19, right ventricular function was mildly impaired, and diastolic dysfunction was twice as common compared with controls. There was little evidence for an association between cardiac function and intensive care treatment, dyspnea, or fatigue. Ventricular arrhythmias were common, but the clinical importance is unknown.

Registration

URL: http://clinicaltrials.gov. Unique Identifier: NCT04535154.

Keywords: arrhythmias, cardiac function, COVID‐19, dyspnea, intensive care

Subject Categories: Echocardiography, Arrhythmias


Nonstandard Abbreviations and Acronyms

EDV

end‐diastolic volume

GLS

global longitudinal strain

HUNT4

fourth wave of the Trøndelag Health Study

NSVT

nonsustained ventricular tachycardia

RVLS

right ventricle free wall longitudinal strain

TAPSE

tricuspid annular plane systolic excursion

Clinical Perspective

What Is New?

  • By comparing echocardiography of patients 3 months after hospitalization for COVID‐19 with matched controls, we found mild right ventricular dysfunction and diastolic dysfunction in half of the patients with COVID‐19.

  • Cardiac arrhythmias of unknown clinical importance were common 3 months after COVID‐19 hospitalization, with premature ventricular beats present in 20% and nonsustained ventricular tachycardia present in 5%.

  • Half of the patients had persistent dyspnea, and nearly two‐thirds had fatigue 3 months after hospitalization for COVID‐19, but these symptoms were not associated with echocardiographic measures of cardiac function.

What Are the Clinical Implications?

  • Left ventricular dysfunction is not common after COVID‐19 infection, and the mild right ventricular dysfunction was likely associated with pulmonary pathology.

  • Patients with symptomatic palpitations 3 months after COVID‐19 should be considered for at least 24‐hour monitoring of heart rhythm.

  • Persistent dyspnea and fatigue after COVID‐19 are more likely caused by pulmonary pathology than cardiac dysfunction.

COVID‐19 is caused by the severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) and primarily affects the lungs. 1 During the pandemic course, persistent organ dysfunction and symptoms, such as dyspnea and fatigue, during the convalescence have been emphasized. 2 , 3 Preexisting cardiovascular disease is common and associated with an increased risk of severe acute COVID‐19. 4 Studies in hospitalized patients with COVID‐19 have demonstrated impaired right ventricular (RV) and left ventricular (LV) function. 5 , 6 These findings have been associated with an increased risk of COVID‐19 mortality. 5 , 6 A prospective multicenter study of patients 2 to 3 months after COVID‐19 infection found a high rate of diastolic dysfunction and signs of pulmonary hypertension, but few had LV dysfunction. 7 In contrast, an Italian single‐center study compared survivors of COVID‐19 with matched controls 41 days after hospital discharge and found no considerable structural or functional differences in cardiac function assessed by echocardiography. 8

Direct cardiac involvement attributed to the virus has recently been shown in magnetic resonance imaging studies and from autopsies. 9 , 10 , 11 Conduction system damage and drug treatment could lead to arrhythmias. 12 In a multicenter study with non–intensive care unit (ICU) hospitalized patients with COVID‐19, 28% developed supraventricular tachycardia, and serious arrhythmias were rare. 13 Whether dyspnea or fatigue after COVID‐19 are related to cardiac function is not known.

There is limited information if hospitalized patients with COVID‐19 will fully recover or have sustained impairment of the myocardium and the heart's electrical system. Therefore, we aimed to assess cardiac function and arrhythmias 3 to 4 months after hospitalization for COVID‐19. We hypothesized that the patients had impaired cardiac function compared with controls and increased prevalence of arrhythmia. Furthermore, we hypothesized that the patients with the most severe disease, requiring ICU care, would have more pronounced cardiac dysfunction than patients with less severe disease not requiring ICU and that persistent dyspnea and fatigue would be associated with cardiac dysfunction.

Methods

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Participant Population and Study Design

PROLUN (Patient‐Related Outcomes and Lung Function After Hospitalization for COVID‐19) is a multicenter prospective cohort study at 6 major hospitals in Norway, where patient‐reported outcomes and lung function after hospital admission for COVID‐19 were investigated. 3 Between February and June 2020, patients aged ≥18 years who had been admitted for >8 hours with a discharge diagnosis of COVID‐19 or viral pneumonia combined with a positive severe acute respiratory syndrome coronavirus 2 polymerase chain reaction test, were considered eligible. Exclusion criteria included living outside the hospitals’ catchment areas, inability to provide informed consent, or participation in the World Health Organization Solidarity trial.

A total of 388 patients were eligible for PROLUN, and of these, 69 patients did not respond to the invitation, and 55 patients declined participation.

This substudy included patients from 5 hospitals because 1 hospital (n=28) lacked the resources to perform echocardiography. In total, 236 consenting patients in PROLUN were invited to this substudy (Figure S1). Informed consent was obtained by returning a written signed consent form or through a secure digital consent form (Services for Sensitive Data, services for sensitive data [TSD], University of Oslo). The study was approved by the Regional Ethics Committee for South‐Eastern Norway (no. 125384) and by data protection officers at each participating center and registered with the ClinicalTrials.gov database (NCT04535154).

Clinical Data Collection

Baseline demographic characteristics (sex, age), comorbidities, and data from the COVID‐19 hospital admissions were obtained from the electronic patient records. World Health Organization Ordinal Scale for Clinical Improvement was used to score the severity of the COVID‐19. 14 Height, weight, body mass index (BMI), current smoking status, and history of hypertension were collected by interview at follow‐up after 3 months.

Controls and Matching

The controls comprised participants from HUNT4 (the fourth wave of the Trøndelag Health Study; 2017–2019), a Norwegian population‐based cohort. The HUNT4 echocardiography study collected data from a random sample and included 2448 participants. 15 A total of 204 patients with COVID‐19 were matched with 204 controls from the HUNT4 echocardiography study on age, sex, BMI, systolic blood pressure, and comorbidity (previous myocardial infarction, congestive heart disease, chronic obstructive pulmonary disease, diabetes; Figure S1). A mixed model was used to match the controls with the patients with COVID‐19. Sex and comorbidity were matched individually and age, BMI, and systolic blood pressure on a group level. From the total population of 2448 HUNT4 echocardiography study participants, the control population was matched according to mean (SD) for age, BMI, and systolic blood pressure.

Echocardiography in Patients With COVID‐19

A 2‐dimensional transthoracic echocardiography of patients in the left lateral decubitus position was performed by 4 experienced operators according to standard methods 16 using commercially available ultrasound systems (Vivid E 95, GE Horten, Norway). Motion‐mode was used in the apical 4‐chamber view to measure tricuspid annular plane systolic excursion (TAPSE) and mitral annular plane systolic excursion. Pulsed tissue Doppler S’, e’, and A’ velocities were obtained from the septal and lateral walls of the mitral annulus. Left atrial volume and end‐diastolic volume (EDV) were measured in the apical 4‐chamber and 2‐chamber views and indexed to body surface area (EDV index). LV ejection fraction (EF) was calculated using Simpson’s biplane method. Mitral valve E/A ratio, diastolic dysfunction, and E/e' were assessed according to the international recommendations from 2016 17 (Data S1). Systolic pulmonary artery pressure was calculated from the peak tricuspid regurgitant velocity and adding this to an estimate of right atrial pressure. LV global longitudinal strain (LV GLS) and RV free wall longitudinal strain (RVLS) were quantified by semiautomatic 2‐dimensional speckle tracking software Automated functional imaging (AFI) based on the apical 4‐chamber, 2‐chamber, and long‐axis views and the RV focus view. 18 Data were stored digitally for offline analysis (GE EchoPAC PC SWO versions 203 and 204). Analyses were performed blinded, and only study‐specific patient identifications were known. The LHL Hospital Gardermoen served as the echocardiography core laboratory.

Echocardiography HUNT4 Reference Population

Echocardiographic recordings were performed according to standard operating procedures aligned with the current recommendations, which were the same used for the COVID‐19 group. 16

A total of 2 sonographers performed the echocardiography. Of these sonographers, 1 experienced in strain analyses performed offline analysis using the AFI package in EchoPAC SWO (203 version). The RV strain analyses were performed offline as for the patients using EchoPAC 204 version by a cardiologist experienced in strain analyses. The same ultrasound systems were used as for the patients with COVID‐19.

Ambulatory 24‐Hour Electrocardiography Registration

A 24‐hour ECG was obtained using Schiller Medilog FD12 Plus (Germany) and Philips DigiTrak XT (Germany) in the patients with COVID‐19, but not in controls. Schiller Medilog Darwin 2 (Germany) and Philips Holter 2010 Plus (Germany) with Zymed Algorithm (Release 3.0.1.1. 2015) were used for the analysis. Clinically significant arrhythmias were defined as ventricular tachycardia (nonsustained or sustained), premature ventricular contractions (PVCs) >200/24 hours or coupled PVCs, atrial fibrillation/flutter, second‐degree atrioventricular block type 2, complete atrioventricular block, sinoatrial block >3 seconds, premature atrioventricular nodal beats in bigeminy, supraventricular tachycardia >30 seconds, and extreme sinus bradycardia with <30 beats/min.

Biochemistry

Nonfasting venous blood samples were collected during the hospital stay and at the 3‐month follow‐up to measure NT‐proBNP (N‐terminal pro–brain natriuretic peptide) and hs‐cTnT (high‐sensitive cardiac troponin T) (Roche Diagnostics, Rotkreuz, Switzerland).

Assessment of Dyspnea

The modified Medical Research Council (dyspnea scale is a self‐rating tool to measure the degree of disability that breathlessness poses on day‐to‐day activities on a scale from 0 (no dyspnea) to 4 (maximum dyspnea). 19

Assessment of Fatigue

Fatigue was assessed using the Chalder Fatigue Scale. 20 A bimodal scoring algorithm was used, where each item response was dichotomized 0 (0–1) or 1 (2–3) and summed to a scale of 0 to 11. Conventionally, fatigue case status (fatigued versus nonfatigued) was defined using this scale with ≥4 denoted as fatigued. 20 , 21

Outcome Measures

The primary outcome measures were RVLS, LV GLS, and arrhythmias. The secondary outcome measures were RV dimension, TAPSE, systolic pulmonary artery pressure, pulmonary vein flow, mitral annular plane systolic excursion, S', EF, EDV index, cardiac index, mitral valve E/A ratio, e´, E/e', and diastolic dysfunction.

Data Storage

All collected data were stored in Services for Sensitive Data (TSD, University of Oslo, Norway), designed for storing and postprocessing sensitive data in compliance with the Norwegian Personal Data Act 22 and Health Research Act. 23

Statistical Analysis

Data are summarized as mean (SD), median (25th–75th percentiles), or number (percentage), as appropriate. Echocardiography variables were compared between the patients with COVID‐19 and the controls using multiple regression analysis, adjusting for age, sex, BMI, resting systolic blood pressure, chronic obstructive pulmonary disease, diabetes, previous heart failure, and previous myocardial infarction. Because of the partly individual matching of controls, linear mixed models were first fitted to account for potential within‐pair correlations. However, these correlations turned out to be very small, and thus ordinary regression models were used. The normal distribution for residuals from linear regression models was assessed by the Anderson‐Darling test and visual inspection of normal QQ‐plots. Generalized linear regression models using a gamma distribution with identity link were used when such models improved residual model fit compared with linear models. Logistic regression was used for dichotomized diastolic dysfunction. Similar models were used to compare the echocardiography variables between non‐ICU and ICU patients with COVID‐19, patients with or without dyspnea, and with or without fatigue, adjusting for age and sex. Correlations between variables were assessed using the Spearman correlation coefficient (ρ).

Normal values from similar populations before the pandemic were used to compare the echocardiographic variables for the patients with COVID‐19 and controls using z scores, that is, the z score indicates the difference from the mean of the age‐specific and sex‐specific stratums of the reference population reported in number of SDs. Where possible, we used age‐specific and sex‐specific reference values from the Norwegian HUNT4 study, a large population‐based cohort. 24 , 25

Other large population‐based cohorts were used in addition. 16 , 26 , 27

The z scores for the patients with COVID‐19 and the matched controls were calculated from normal values for means and SDs, specified by age group (<40, 40–60, >60 years) and sex. The z scores are summarized as medians with 2.5 and 97.5 percentiles.

All statistical analyses were performed using R version 3.4.4 (R Foundation for Statistical Computing, Vienna, Austria) or Stata version 16.1 (StataCorp., College Station, TX). To give some protection against false‐positive results attributed to multiple testing, P values <0.01 were considered statistically significant.

Results

Participant Characteristics

In total, 204 consented to participate in the substudy. The examinations were conducted a median of 102 days (range, 70–172 days) after discharge from the hospital. Of the patients, 3 did not undergo a 24‐hour ECG and were excluded from this analysis. Baseline demographics and data from the hospital stay, laboratory measures, dyspnea rating, fatigue score, and World Health Organization ordinal scale are presented in Table 1.

Table 1.

Baseline Demographics, Data From Hospital, Risk Factors, and Comorbidity (n=204)

No. (%) Mean (SD) (range) Median (25th–75th percentiles)
Age at hospital discharge, y 58.5 (13.6) (30–83)
Laboratory
hs‐cTn peak, hospitalization, ng L−1 169 (83) 10 (6–17)
hs‐cTn at 3 mo, ng L−1 169 (83) 8 (5–11)
NT‐proBNP peak, hospitalization, ng L−1 174 (85) 186 (70–526)
NT‐proBNP at 3 mo, ng L−1 174 (85) 58 (41–120)
CRP peak, hospitalization, mg L−1 201 (99) 112 (39–190)
ICU stay 41 (20)
Intubated and invasively ventilated 25 (12)
No. of days in ICU 41 10.7 (2–22)
No. of days on ventilator 24 11.9 (5–18)
Length of stay in hospital, d 203 10.2 (1–55)
mMRC dyspnea scale 163 (80)
0 77 (47)
1 50 (31)
2 26 (16)
3 8 (5)
4 2 (1)
mMRC 0 vs 1–4 86 (53)
Chalder Fatigue Scale 163 (80)
<4 62 (38)
≥4 101 (62)
WHO Ordinal Scale for Clinical Improvement 203 (99)
3 71 (35)
4 97 (48)
5–7 35 (17)

CRP indicates C‐reactive protein; hs‐cTn; high‐sensitivity cardiac troponin; ICU, intensive care unit; mMRC, modified Medical Research Council; NT‐proBNP, N‐terminal pro–brain natriuretic peptide; and WHO, World Health Organization.

There were 114 (56%) men. A total of 5 patients (3%) were current daily smokers, and 76 (41%) were former daily smokers. Table 2 summarizes the most important comorbidities.

Table 2.

Summary Statistics for the Additional Covariates in the Multiple Regression Models

Controls COVID‐19 P value*
No. Mean (SD) or n (%) No. Mean (SD) or n (%)
Age, y 204 58.4 (13.4) 204 58.5 (13.6) 0.980
Male patients 204 114 (56%) 204 114 (56%) 1.000
Body mass index, kg/m2 204 28.1 (4.1) 202 28.2 (4.6) 0.796
Systolic blood pressure, mm Hg 204 135.8 (18.3) 199 135.8 (18.6) 0.976
Previous myocardial infarction 196 14 (7%) 203 14 (7%) 0.923
Congestive heart failure 192 7 (4%) 203 8 (4%) 0.878
COPD 196 7 (4%) 203 7 (3%) 0.947
Diabetes 201 18 (9%) 203 19 (9%) 0.888

COPD indicates chronic obstructive pulmonary disease.

*

Chi‐square tests for dichotomous variables; t tests for continuous variables.

Hypertension was found in 65 (32%) patients. The majority were White patients (82%), followed by Asian patients (8%) and African American patients (7%). Mean BMI was 28.3 (4.5) kg/m2, and obesity (BMI >30 kg/m2) was found in 70 patients (34%). In total, 32/236 (14%) of the patients invited from the main study did not participate in our substudy. The nonparticipants were older (61.3 years), and there were more men (73%) compared with the participants. There was no difference in comorbidity, World Health Organization severity scale, or dyspnea, but fewer nonparticipants had fatigue (41%).

Cardiac Function and Morphology

Cardiac function and morphology are detailed in Table 3.

Table 3.

Summary Statistics and Estimated Mean Differences Between COVID‐19 and Reference Population From Multiple Regression for the Echocardiographic Variables

Control COVID‐19 COVID‐19 vs control
No. Mean (SD) or n (%) No. Mean (SD) or n (%) No. Estimate* (95% CI) P value
LV systolic function
LV GLS, % 171 −17.8 (2.6) 187 −18.5 (2.8) 338 −0.8 (−1.3 to −0.2) 0.008
Ejection fraction, % 194 58.4 (7.2) 196 56.5 (6.7) 368 −1.7 (−3.1 to −0.3) 0.015
MAPSE, cm 202 1.5 (0.3) 201 1.4 (0.2) 382 −0.10 (−0.14 to −0.05) <0.001
S', cm/s 199 8.3 (1.8) 183 8.0 (1.6) 361 −2.4 (−5.6 to 0.8) 0.135
Cardiac index, L/min per m2 196 2.9 (0.8) 193 2.6 (0.7) 369 −0.26 (−0.40 to −0.12) <0.001
LV volumes
EDV index, mL/m2 194 58.7 (15.9) 186 49.5 (13.8) 360 −8.8 (−11.4 to −6.1) <0.001
LV diastolic function
MV E/A ratio 191 1.1 (0.4) 200 1.1 (0.4) 371 0.01 (−0.06 to 0.07) 0.860
e', cm/s 198 9.1 (2.7) 193 8.4 (2.4) 370 −6.0 (−9.8 to −2.2) 0.002
E/e' 194 8.3 (2.3) 188 8.4 (3.1) 362 −0.03 (−0.46 to 0.40) 0.886
RV function and dimensions
RV free wall strain, % 168 −26.2 (4.7) 165 −24.6 (5.0) 315 1.5 (0.5 to 2.6) 0.005
RVD, cm 136 3.8 (0.7) 196 3.9 (0.6) 314 0.11 (−0.03 to 0.25) 0.111
TAPSE, cm 187 2.5 (0.5) 199 2.4 (0.5) 366 −0.16 (−0.27 to −0.06) 0.002
SPAP, mm Hg 96 28 (6.8) 157 23.8 (8.7) 239 −3.9 (−6.1 to −1.8) <0.001
Left atrial size and PV flow
LA volume index, mL/m2 198 33.1 (14.3) 190 27.1 (8.3) 368 −5.0 (−7.0 to −3.1) <0.001
PV systolic/diastolic ratio 170 1.3 (0.4) 174 1.4 (0.4) 326 0.09 (0.01 to 0.16) 0.023
Heart rate 200 68.2 (13.2) 201 66.9 (11.7) 379 −1.0 (−3.4 to 1.4) 0.409
Diastolic dysfunction* 200 29 (15%) 201 60 (30%) 380 2.4 (1.4 to 4.2) 0.001
DD with normal EF 11 (6%) 15 (8%)
DD grade 1 with reduced EF 13 (6%) 38 (19%)
DD grade 2 with reduced EF 3 (2%) 4 (2%)
DD grade 3 with reduced EF 2 (1%) 3 (2%)

DD indicates diastolic dysfunction; e', mean value of septal and lateral early diastolic pulsed tissue Doppler velocities; E/e', filling pressure; EDV, end‐diastolic volume; EF, ejection fraction; GLS, global longitudinal strain; LA, left atrial; LV, left ventricular; MAPSE, mitral annular plane systolic excursion; MV E/A, mitral valve E wave velocity and A wave velocity ratio; PV, pulmonary vein; RV, right ventricular; RVD, right ventricular dimension; S', peak systolic tissue Doppler velocity; SPAP, systolic pulmonary artery pressure; and TAPSE, tricuspid annular plane systolic excursion.

*

Estimate is odds ratio from multiple logistic regression on dichotomized diastolic dysfunction, otherwise estimated mean difference. Estimates are adjusted for age, sex, body mass index, systolic blood pressure, previous myocardial infarction, heart failure, chronic obstructive pulmonary disease, and diabetes.

In a linear regression model adjusted for age, sex, BMI, blood pressure, and several comorbidities (Table 3), there was evidence of worse RVLS and slightly better LV GLS in the COVID‐19 group versus controls. Cardiac index and EDV index were lower in the COVID‐19 group than controls. Only weak or little evidence was found for a difference in EF or mitral annular plane systolic excursion between the COVID‐19 group and controls. Patients with COVID‐19 had lower e´, and 30% had diastolic dysfunction compared with 15% of the controls. There was evidence for reduced TAPSE, but no evidence for a difference in RV dimension or pulmonary vein flow compared with the controls. In the COVID‐19 group, the median of the individual z scores was highest for RVLS, RDV, and LV GLS (Table 4). For the controls, LV GLS, RV dimension, and Left atrial volume index had the highest median z scores (Table 4).

Table 4.

The Z Scores Derived From Normal Populations and Calculated for Controls and COVID‐19

Control COVID‐19
Median 2.5 percentile 97.5 percentile Median 2.5 percentile 97.5 percentile
LV systolic function
LV GLS, % 1.67 −0.19 4.07 1.48 −0.37 3.79
Ejection fraction, % −0.72 −5.11 1.38 −1.20 −4.20 1.40
MAPSE, cm −0.13 −2.07 2.15 −0.56 −2.10 1.25
S', cm/s 0.13 −2.42 3.09 −0.17 −2.23 2.78
Cardiac index, L/min per m2 −0.20 −1.68 2.38 −0.50 −1.84 1.83
LV volumes
EDV index, mL/m2 0.74 −1.52 4.04 −0.05 −2.66 2.81
LV diastolic function
MV E/A ratio −0.43 −1.53 1.41 −0.48 −1.67 1.51
e', cm/s 0.39 −1.43 2.08 0.52 −1.13 2.22
E/e' 0.46 −0.84 2.64 0.39 −1.67 3.37
RV function and dimensions
RV free wall strain, % 1.04 −1.41 3.92 1.47 −1.08 4.15
RVD, cm 1.19 −2.37 5.56 1.50 −1.25 4.50
TAPSE, cm 0.11 −2.33 3.11 0.00 −2.57 2.86
SPAP, mm Hg −0.22 −2.19 3.34 −1.08 −3.73 2.49
Left atrial size and PV flow
LA volume index, mL/m2 1.47 −1.12 6.80 0.72 −1.32 3.88
PV systolic/diastolic ratio −0.20 −2.29 2.08 −0.06 −1.30 2.63

DD indicates diastolic dysfunction; e' indicates mean value of septal and lateral early diastolic pulsed tissue Doppler velocities; E/e', filling pressure; EDV, end‐diastolic volume; EF, ejection fraction; GLS, global longitudinal strain; LA, left atrial; LV, left ventricular; MAPSE, mitral annular plane systolic excursion; MV E/A, mitral valve E wave velocity and A wave velocity ratio; PV, pulmonary vein; RV, right ventricular; RVD, right ventricular dimension; S', peak systolic tissue Doppler velocity; SPAP, systolic pulmonary artery pressure; and TAPSE, tricuspid annular plane systolic excursion.

Cardiac Function in Subgroups

When the COVID‐19 group was differentiated into ICU stay or ward, the RVLS was slightly worse after ICU stay (23% [5.2%] versus 25.1% [4.8%]; adjusted mean difference, −2.2 percentage points; 95% CI, −3.9 to −0.4; P=0.016), and there was no difference in LV GLS (−18.2% [3.8%] versus −18.6% [2.5%]; adjusted mean difference, 0.2 percentage points; 95% CI, −0.8 to −1.3; P=0.63; Tables S1 and S2). There was little or no evidence of differences in other cardiac function variables. Moreover, there was little or no evidence of any differences in cardiac function if dyspnea or fatigue were present (Tables S2 through S4).

All patients with pulmonary hypertension (n=6) had reduced RVLS, and half of the patients (n=3) had both pulmonary hypertension and diastolic dysfunction.

In total, 60 of the patients with COVID‐19 had diastolic dysfunction (Table 3). There was no difference in age (P=0.22), BMI (P=0.83), comorbidities (P=0.07), EF (P=0.21), RVLS (P=0.02), or cardiac index (P=0.26) compared with those without diastolic dysfunction. Diastolic dysfunction was the same for patients treated at ICU compared with no ICU treatment (37% versus 29%; P=0.21).

Arrhythmias

Cardiac arrhythmias were detected in 27% of the patients with COVID‐19 (Table 5). PVCs were the most frequent cardiac arrhythmia. More than 200 PVCs per day were observed in 37 patients (18%), with a mean of 1300 PVC/day, and in 35 (95%) of these patients, the PVCs were polymorphic (Table 5). Nonsustained ventricular tachycardia (NSVT) was found in 10 (5%) of the patients with COVID‐19. Of the patients with NSVT, 5 had previous cardiovascular diseases: coronary heart disease (n=1), atrial fibrillation (n=1), venous thromboembolism (n=2), and heart failure (n=4). The patients presenting with atrial fibrillation on 24‐hour ECG all had atrial fibrillation before hospitalisation for COVID‐19. Sinoatrial block >3 seconds was only observed in 1 patient.

Table 5.

Cardiac Arrhythmias (n=201)

No. Percentage
Nonsustained ventricular tachycardia 10 5.0
Premature ventricular contractions >200/24 h 37 18
Atrial fibrillation/flutter* 7 4
Second degree or complete atrioventricular block 0 0
Extreme sinus bradycardia (<30 bpm) 0 0
Sinoatrial block >3 s 1 0
Premature atrioventricular‐nodal beats in bigeminy 0 0
Supraventricular tachycardia >30 s 3 2

bpm indicates beats per minute.

*

Paroxysmal, persisting, or chronic.

Cardiac Function, Arrhythmias, and Correlations With Biochemical Markers

PVCs showed a weak positive correlation with hs‐cTn during hospitalization (ρ=0.30; 95% CI, 0.15–0.43; P=0.0001) and at 3 months (ρ=0.33; 95% CI, 0.20–0.46; P<0.001) and to peak NT‐proBNP level during hospitalization (ρ=0.21; 95% CI, 0.06–0.35; P=0.007) and at 3 months (ρ=0.30; 95% CI, 0.17–0.43; P<0.001). There was a weak negative correlation between RVLS and NT‐proBNP during hospitalization (ρ=−0.20; 95% CI, −0.35 to −0.04; P=0.02) but not at 3 months (ρ=−0.08; 95% CI, −0.23 to 0.08; P=0.34). There was no correlation between RVLS and hs‐cTn during hospitalization or at 3 months.

Discussion

This combined cohort and cross‐sectional case‐control study reports the severity of cardiac dysfunction in patients with COVID‐19 3 months after hospitalization compared with matched controls and describes the prevalence of cardiac arrhythmia. The main findings were worse RV strain and TAPSE suggesting RV dysfunction and increased arrhythmic burden.

Recently, RV dilatation, reduced RV fractional area change, and TAPSE were demonstrated in hospitalized patients with COVID‐19. 28 Another study showed that RVLS was reduced by 4.4 percentage points compared with controls in a hospitalized COVID‐19 cohort. 6 We demonstrated slightly reduced RVLS compared with controls, with a value around the lower limits of normality. 27

Patients with severe COVID‐19 treated at an ICU exhibited a higher prevalence of pulmonary vascular defects, leading to pulmonary hypertension and subsequent RV dysfunction. 5 There was weak evidence in our study that patients with ICU treatment had worse RVLS than those without ICU treatment.

It is possible that decreased RV function may be attributed to abnormal pulmonary physiology from more severe COVID‐related lung disease because there was no relationship between cardiac troponin and RV strain. In the acute and subacute settings, NT‐proBNP production may be more responsive to increased RV stretch secondary to lung pathology than cardiac troponin release. This may partially explain the closer association observed between NT‐proBNP and RVLS than between hs‐cTn and RVLS. Elevated NT‐proBNP can be seen in RV dysfunction related to pulmonary pathology. 29 Increased afterload and elevated pulmonary arterial pressure can affect the assessment of RV function. RV dysfunction in patients with COVID‐19 could reflect impaired lung function and not myocardial function.

There was a tendency to a poorer LV cardiac function by EF and mitral annular plane systolic excursion among the patients with COVID‐19. The difference in LV GLS was statistically significant, but hardly clinically different. The z scores for LV GLS indicated that LV GLS was worse than the normal values for patients with COVID‐19 as well as controls. LV function by EF in patients with COVID‐19 vary from relatively well preserved to a range of dysfunction between 11% and 20%. 28 , 30

The cardiac index and EDV index were significantly lower in our patients compared with the controls. These findings may be attributed to inactivity over time. 31 We have recently shown in the same study population a reduction in peak oxygen uptake in every third patient with COVID‐19 caused by deconditioning in the majority. 32

A prospective multicenter study reported a high rate of diastolic dysfunction at 3 (55%) months after COVID‐19. 7 We found that the odds ratio of diastolic dysfunction for patients with COVID‐19 was 2.4 compared with the controls. The majority of the patients had mild diastolic dysfunction.

It was recently shown that hospitalized patients with COVID‐19 had a higher likelihood of heart failure with preserved ejection fraction associated with structural and functional cardiac alterations and myocardial injury. 33 , 34 However, of 30% with diastolic dysfunction, only 25% of the patients with diastolic dysfunction had a normal ejection fraction.

Information concerning persisting cardiac arrhythmias has, to our knowledge, not been reported in previous studies of patients with COVID‐19. In a worldwide survey of 4526 hospitalized patients with COVID‐19, associated arrhythmias were common and found in 18%. 35 In a meta‐analysis comprising 9 studies, cardiac arrhythmias during hospitalization with COVID‐19 were found in 19% of patients, 36 slightly lower compared with our study. The clinical implications of persistent ventricular arrhythmia following COVID‐19 are not clear, but ventricular ectopy has been linked to an increased risk of cardiac disease, including cardiomyopathy and sudden cardiac death. 37 Ventricular ectopy is usually a benign arrhythmia, 38 but may in some patients cause persisting palpitations, chest pain, and dizziness leading to reduced quality of life. 39 Potential serious ventricular arrhythmias such as NSVT were observed in 5%, which is twice as many compared with a Norwegian population‐based study with 2.6% NSVT among 498 participants, and in total, 9% had complex ventricular ectopy (bigeminy, trigeminy, or NSVT). 40 Frequent PVCs (>5 per hour, 120 per 24 hours) were observed in 9% and were associated with significantly higher concentrations of NT‐proBNP and high‐sensitivity troponin I. 40 We found twice as many PVCs using a stricter definition (>200 PVCs per 24 hours). In healthy volunteers, >200 PVCs per 24 hours were observed in 3% and NSVT in 0.7%. 41 However, without a matched control group, it is difficult to conclude the relation to COVID‐19. A modest correlation between PVCs and NT‐proBNP and hs‐cTn levels during hospitalization and at 3 months was found in our study. These arrhythmias may be more closely related to myocardial damage reflected in increased hs‐cTn concentrations than RV function because there was no correlation between RVLS and hs‐cTn. A recent retrospective cohort study, conducted by reviewing electronic medical records from a global federated health research network, showed that 718 365 patients with COVID‐19 (6.5%) developed new‐onset perimyocarditis. 42 The extent of micro scars is unknown in COVID‐19, which could be triggers for arrhythmias.

Persistent dyspnea was common among our patients and were not associated with cardiac dysfunction. When performing cardiopulmonary exercise testing in the same study population, dyspneic participants were characterized by lower exercise capacity as a result of obesity and lower ventilatory efficiency. 32

Earlier studies have demonstrated a lower cardiac index and in individuals with high fatigue than in individuals with moderate and low fatigue. 43 Fatigue was common among our patients but was not associated with cardiac dysfunction.

Limitations

This study has some important limitations. RVLS and LV GLS could not be analyzed in 19% and 8% of the patients, respectively, similar to other studies. 29 , 44 The inconsistency in LV GLS with a 0.8 percentage point higher value (ie, better GLS) among patients with COVID‐19 was not clinically significant and could be operator dependent.

Although there are limitations estimating tricuspid regurgitation jet velocity, it is included in the present guidelines for estimation of diastolic dysfunction, which we used.

Some variables, such as history of hypertension and cardiac disease, were self‐reported and might not be precise, but this would be equal in the compared groups and should not cause differential misclassification. Dyspnea and fatigue represent subjective phenomena, which were based on self‐reported questionnaires.

Being a multicenter study, the statistical analyses should ideally account for the possibility of center effects. However, the controls used in the primary analyses were population based, and 2 of the 5 centers had few patients.

The patients included in this study were reasonably representative of the patients hospitalized with COVID‐19 in Norway, as it comprised about 25% of those discharged alive with COVID‐19 in Norway as of June 1, 2020. The mean for age and BMI in our population was similar to those discharged in the whole country.

Conclusions

At 3 months after COVID‐19 hospitalization, patients had mildly impaired RV function, reduced diastolic function, and mainly preserved left ventricular function compared with matched controls. Premature ventricular contractions and nonsustained ventricular tachycardia were common, but the relation to COVID‐19 is unknown. Patients treated in an ICU had similar cardiac function as those not admitted to an ICU. Persistent dyspnea or fatigue were not found to be associated with cardiac function.

Sources of Funding

This work was supported by The National Association for Heart, Lung Diseases, the Norwegian Health Association, and Akershus University Hospital.

Disclosures

Ingul and Grimsmo have received fees for lectures from Bayer AG. Omland has received consultancy and speaker honoraria from Abbott Diagnostics, Bayer, CardiNor, Roche Diagnostics, and Siemens and research support via Akershus University Hospital from Abbott Diagnostics, Novartis, SomaLogic, and Roche Diagnostics. Omland also has financial interests and serves as a fiduciary officer in Cardinor AS. Andrup has received fees for lectures from Bayer AG and Novartis. The remaining authors have no disclosures to report.

Supporting information

Data S1

Tables S1–S4

Figure S1

Acknowledgments

Bioengineer Vilde Bertelsen has contributed greatly to the 24‐hour ECGs and for help with organizing the study. Nurse Katrine Onshus Eriksen has contributed to the 24‐hour ECGs. The HUNT (Trøndelag Health Study) is a collaboration between the HUNT Research Centre (Faculty of Medicine and Health Sciences, Norwegian University of Science and Technology), Nord‐Trøndelag County Council, Central Norway Regional Health Authority, and the Norwegian Institute of Public Health. Drs Ingul, Stavem, and Follestad had full access to all of the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. Drs Ingul, Jensen, Grimsmo, Einvik, and Stavem contributed to the study concept and design; Drs Ingul, Grimsmo, Jensen, Josefsen, Mecinaj, Berger Nossen, Andrup, Grenne, Dalen, and Trebinjac contributed to the acquisition, analysis, or interpretation of data; Drs Ingul, Jensen, Grimsmo, Einvik, Stavem, Dalen, Grenne, Omland, Follestad, Berger Nossen, Andrup, Grenne, Dalen, and Trebinjac contributed to manuscript drafting; Drs Ingul, Jensen, Grimsmo, Einvik, Stavem, Dalen, Grenne, Omland, and Follestad contributed to the critical revision of the manuscript for important intellectual content; Drs Follestad, Ingul, and Stavem contributed to the statistical analysis; Drs Ingul and Einvik obtained funding; Drs Stavem, Einvik, Ingul, and Omland contributed to the administrative, technical, or material support; and Drs Ingul, Jensen, Grimsmo, Josefsen, and Mecinaj provided study supervision.

Supplemental Material for this article is available at https://www.ahajournals.org/doi/suppl/10.1161/JAHA.121.023473

For Sources of Funding and Disclosures, see page 9.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Data S1

Tables S1–S4

Figure S1


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