COVID-19 Cardiovascular Complications

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1] Associate Editor(s)-in-Chief: Mitra Chitsazan, M.D.[2]Mandana Chitsazan, M.D. [3]Tayyaba Ali, M.D.[4]Ayesha Javid, MBBS[5]Mounika Reddy Vadiyala, M.B.B.S.[6]Sara Haddadi, M.D.[7]

Overview

Cardiovascular Complications

Acute Myocardial Injury

Coronavirus disease 2019 (COVID-19) is a rapidly expanding global pandemic which is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), resulting in significant morbidity and mortality. Some hospitalized patients can develop an acute COVID-19 myocardial injury, which can manifest with a variety of clinical presentations but often presents as an acute cardiac injury with cardiomyopathy, ventricular arrhythmias, and hemodynamic instability, acute coronary syndrome, cardiogenic shock. patents with preexisting cardiovascular disease have higher morbidity and mortality.

Myocardial injury

  • COVID-19 patients with cardiovascular comorbidities have higher mortality.
  • Hospitalized patients with COVID-19 and Cardiovascular disease seem to be more prevalent in both the USA and China. [1]
  • In a case series with 187 patients who had confirmed COVID-19, 27.8% of patients had a myocardial injury, which caused cardiac dysfunction and arrhythmias. The result was significantly higher mortality among patients with myocardial injury.
  • It seems to be advisable to triage patients with COVID-19 based on their underlying CVD for a more aggressive treatment plan.
  • The mortality during hospitalization was shown to be 7.62% for patients without underlying CVD and normal TnT levels, 13.33% for those with underlying CVD and normal TnT levels, 37.50% for those without underlying CVD but elevated TnT levels, and 69.44% for those with underlying CVD and elevated TnTs.[2]

Acute Coronary Syndromes

Pathophysiology

The mechanism of COVID-19 cardiovascular injury has not been fully understood and is likely multifactorial.

  • SARS-CoV-2 virus attaches to ACE 2 protein for ligand binding before entering the cell via receptor-mediated endocytosis.
    • Based on single-cell RNA sequencing more than 7.5% of myocardial cells have positive ACE2 expression. This protein can mediate the entry of SARS-CoV-2 and result in direct cardiotoxicity.
  • The cytokine release caused by the virus may lead to vascular inflammation, plaque instability, myocardial inflammation, a hypercoagulable state, or direct myocardial suppression.

Pathological changes:

  • In the level of cardiac tissue: minimal change to interstitial inflammatory infiltration and myocyte necrosis
  • In the level of vasculature: micro-thrombosis and vascular inflammation[1]

Signs and Symptoms

The signs and symptoms of acute coronary syndrome include:[3]

Treatment

In patients with ACS, and COVID-19, treatment should follow the guidelines of the updated Society for Cardiovascular Angiography and Interventions.[1] [4]

ST-Elevation Myocardial Infarction (STEMI)

A US model from 9 major centers showed a 38% drop in total STEMI activations during the COVID-19 pandemic. There is a 40% reduction noted in Spain as well. there was also a delay between the first presentation to a medical encounter up to 318 min. This is important since COVID-19 can potentially be a cause of STEMI through microthrombi, cytokine storm, coronary spasm, or direct endothelial injury.[5]

  • Potential etiologies for the reduction in STEMI PPCI activations:
    • avoidance of medical care due to social distancing or concerns of contracting COVID-19 in the hospital
    • STEMI misdiagnosis
    • increased use of pharmacological reperfusion due to COVID-19

It is very important to realize if patients' anxiety is the reason behind decreasing the presentation of STEMI to U.S. hospitals.[6]

  • Treatment of STEMI & COVID-19: The specific protocols for the treatment have been evolving. Early recommendations showed intravenous thrombolysis as first-line therapy for STEMI patients with confirmed COVID-19 since most hospitals do not have protected cardiac catheterization labs.[5]

Cardiogenic Shock

Myocarditis

Pathophysiology

Signs and symptoms

Clinical presentation of SARS-CoV-2 myocarditis varies among cases from mild to severe to fulminant.

According to a study, ventricular arrhythmias are also seen in the patients of myocarditis.[26]

Diagnostic testing

The American Heart Association (AHA) recommends further testing with 1 or more cardiac imaging methods such as an echocardiogram or cardiovascular magnetic resonance (CMR) for patients having signs consistent with myocarditis.[10] However, echocardiogram or cardiac imaging can be avoided or delayed until recovery from COVID-19 in the patients with COVID-19 and myocardial injury who are hemodynamically and electrophysiologically stable with mild to moderate elevations of troponin unless the patient clinically deteriorates and develops hemodynamic instability, shock, ventricular arrhythmias, or a severely elevated or rapidly rising troponins.[36]

  • Cardiac Computed Tomography
  • Endomyocardial biopsy:
    • Endomyocardial biopsy (EMB) has been recommended as the definitive diagnostic tool for myocarditis by the American Heart Association (AHA) and European Society of Cardiology (ESC).[41] In non–COVID-19 cases, endomyocardial biopsy has traditionally been recommended in fulminant presentations to exclude the rare presentation of eosinophilic, hypersensitive,and giant-cell myocarditis.[42] However, in COVID-19, it may not be feasible because of the instability of the patient, requirement of expertise, false-negative rate and risk of contagiousness, especially if the biopsy results would not change clinical management.[9][10][39]
    • EMB samples if obtained should be tested for inflammatory infiltrates and for the presence of viral genomes by DNA/RNA extraction.[9]
    • In a COVID-19 case reported, EMB showed diffuse T-lymphocytic inflammatory infiltrates with huge interstitial edema and no replacement fibrosis, suggesting an acute inflammatory process. SARS-CoV-2 genome was absent within the myocardium in molecular analysis.[14]

Treatment

Pericarditis

Pericarditis is a rare manifestation of COVID-19. There are very few case reports of pericarditis in COVID-19 patients.[45][12][46][47]

Pathophysiology

  • Viral infections are a common cause of pericarditis. It is hypothesized that viruses cause pericardial inflammation via direct cytotoxic effects or via immune-mediated mechanisms.[48]
  • COVID-19 has been reported to trigger an exaggerated inflammatory response in patients which might be leading to pericarditis and subsequent pericardial effusion in certain patients; however, the exact mechanism is unclear.

Signs and Symptoms

Diagnostic testing

Treatment

Arrhythmias

Pathophysiology:

Signs and Symptoms:

Arrhythmia or conduction system disease is the nonspecific clinical presentation of COVID-19. Patients may be tachycardic (with or without palpitations) in the setting of other COVID-19-related symptoms (eg, fever, shortness of breath, pain, etc).

  • Palpitations: According to a study done in Hubei province,palpitations were reported as a presenting symptom by 7.3 percent of patients.[51][52]
  • Prolong QT Interval: According to a multicenter study done in New York that involved 4250 COVID-19 patients, 260 patients (6.1 percent) had corrected QT interval (QTc) >500 milliseconds at the time of admittance. However, in another study that involved 84 patients who got hydroxychloroquine and azithromycin, the baseline QTc interval was 435 milliseconds before receiving these medications.[53][54]
  • Atrial Arrhythmia: According to a study, among 393 patients with COVID-19, atrial arrhythmias were more common among patients requiring invasive mechanical ventilation than noninvasive mechanical ventilation (17.7 versus 1.9 percent).[55]
  • Ventricular Arrhythmia: According to a study done in Wuhan, China. among 187 hospitalized patients with COVID-19, 11 patients (5.9 percent) developed ventricular tachyarrhythmias.[2]
  • Cardiac Arrest: According to a Lombardia Cardiac Arrest Registry (Lombardia CARe) of the region Lombardia in Italy. Out of 9806 cases of COVID-19, 362 cases of out-of-hospital cardiac arrest were reported during the study time frame in 2020. During a similar period in 2019, 229 cases of out-of-hospital cardiac arrest were reported, which means an increment of 58% was observed in 2020 among COVID-19 patients. According to the records from a tertiary care hospital in Wuhan. Out of 761 patients with severe COVID-19, 151 patients developed in-hospital cardiac arrest. 136 patients received resuscitation. Out of 136 patients, 119 patients had a respiratory cause. 10 patients had a cardiac cause. 7 patients had other causes. Ventricular fibrillation or pulseless ventricular tachycardia was observed in 8 patients (5.9%), Pulseless electrical activity in 6 patients (4.4%), and asystole in 122 COVID-19 patients (89.7%).[56][57]

Diagnostic Testing:

  • ECG: Most patients with the severe COVID-19, and especially patients who receive QT-prolonging medications, should have a baseline electrocardiogram (ECG) performed at the time of admission to the hospital.The best technique to get the QT interval is with a 12-lead electrocardiogram (ECG). However, to scale back exposure to hospital workers, this could not perpetually be possible. A single-lead ECG might underestimate the QT interval, and there ought to be an effort to use a multiple-lead telemetry system to observe the QT interval.[58][59]
  • Transthoracic echocardiography: Transthoracic echocardiography is recommended for an inpatient with heart failure, arrhythmia, ECG changes, or newly diagnosed cardiomegaly on chest x-ray or CT-chest.[12]

Treatment:

  • Polymorphic Ventricular Tachycardia (torsades de pointes): All patients with torsades de pointes (TdP) should be determined if they are hemodynamically stable or unstable through immediate evaluation of the symptoms, vital signs, and level of consciousness.[60]
    • Unstable patients: Patients with COVID-19 with sustained torsades de pointes (TdP) usually become hemodynamically unstable, severely symptomatic because of perfusion failure, or pulseless and should be treated according to standard resuscitation algorithms, including cardioversion/defibrillation. Initial treatment with antiarrhythmic medications is not indicated for hemodynamically unstable or pulseless patients except intravenous (IV) magnesium.
    • Stable patients: In a patient with a single episode of TdP, treatment with IV magnesium along with correction of metabolic/electrolyte disturbances or removal of any inciting medications may be sufficient. The patient should be kept under observation until the electrolytes, and the QT interval nearly normalizes. An IV bolus of 2-gram magnesium sulfate is the standard therapy for an adult. This is equivalent to a dose of 8.12 mmol of magnesium. The clinical situation of a patient determines the rate of magnesium infusion. Infusion occurs over one to two minutes in patients with pulseless cardiac arrest. The infusion should occur over 15 minutes in patients without cardiac arrest as a rapid IV bolus of magnesium can result in hypotension and asystole. Some patients are given a continuous bolus of IV magnesium at a rate of 3 to 20 mg/min until the QT interval is below 0.50 seconds.[61][62]
  • Other Cardiac arrhythmia: The treatment for other arrhythmias in COVID-19 patients is the same as in patients with arrhythmias without COVID-19 infection.

Out-of-hospital cardiac arrest and Sudden Cardiac Death

The sudden cardiac death is defined as the death that occurs within one hour of onset of symptoms in witnessed cases and within 24 hours of last being seen alive when it is unwitnessed.[63] Out-of-hospital cardiac arrest means cessation of cardiac mechanical activity that occurs outside of the hospital setting and is confirmed by the absence of signs of circulation.

Pathophysiology

  • Drug induced:

Since the COVID-19 pandemic, several pharmacological therapies have been proposed, one of them is of two anti-malarial and antirheumatic drugs called Chloroquine or Hydroxychloroquine. Due to their cost-effectiveness and easy availability, there is a surge in the use of Chloroquine and Hydroxychloroquine, with or without Azithromycin. The clinical trials in order to estimate their efficacy are still in the preliminary stage, however, a notable concern is of their cardiac adverse effects. This includes QT prolongation and Torsade de pointes (TdP) leading to sudden cardiac death. The risk is there when these drugs are prescribed separately, however it increases several folds when these drugs are administered together, especially in patients with underlying hepatic disease or renal failure.[64]

  • Genetic susceptibility:

Epidemiological studies have shown that African Americans have higher COVID-19 associated morbidity and mortality as compared to people from other ethnic groups. Recent studies show that this ethnic predilection is due to the genetic factors which contribute to a common ion channel variant p.Ser1103Tyr-SCN5A which confer an increased risk of drug-induced long QT syndrome (DI-LQTS) and drug-induced sudden cardiac death (DI-SCD). p.Ser1103Tyr-SCN5A generates late or persistent sodium current which is further aggravated by hypoxia or respiratory acidosis secondary to lungs involvement in COVID-19. This has and has been linked to an increased risk of ventricular arrhythmia (VA) such as torsade de pointes and sudden cardiac death (SCD) in African Americans.[65]

  • Cytokine storm and heart damage:
  • Pre-existing heart disease

Epidemiology

  • Incidence

There is a two-times rise in the incidence of Out of hospital Sudden cardiac arrest (OHCA) during the COVID-19 pandemic as compared to the non-pandemic time period.[66]

  • Mortality

There is a significant increase in the mortality rate of the OHCA patients.[66]

  • Age

Mean age 69.7 years is observed among patients who experienced Out of hospital Sudden cardiac arrest (OHCA) .[66] .

  • Gender

Studies show that males have a slightly higher incidence of Out of hospital Sudden cardiac arrest (OHCA) as compared to the females.[66]

  • Race

A higher incidence is seen among African-Americans as compared to the Caucasians.[65][67]

Diagnosis

Treatment

  • Cardiopulmonary resuscitation
  • Implantable Cardioverter Defibrillator (ICD)
  • Pharmacologic therapy in survivors of sudden cardiac arrest
Prevention

Spontaneous Coronary Artery Dissection

Spontaneous coronary artery dissection (SCAD) is a non-iatrogenic non-traumatic separation of the coronary arterial wall. It could be either atherosclerotic or non-atherosclerotic.

Pathophysiology

  • SCAD could be secondary to an atherosclerotic (A-SCAD) or non-atherosclerotic (NA-SCAD) lesion.
  • In COVID-19 patients due to high inflammatory load, a localized inflammation of the coronary adventitia and periadventitial fat can occur. This could lead to the development of sudden coronary artery dissection in a susceptible patient with underlying cardiovascular disease.

Signs and symptoms

SCAD can present as acute coronary syndrome and NSTEMI. The signs and symptoms include;

  • Sudden onset of retrosternal pain chest pain which remains persistent in a COVID-19 seropositive patient or in a patient with recent cough and dyspnea raises suspicion of SCAD.
  • The chest pain can radiate to the left arm.
  • It can be associated with;
  • Dyspnea
  • Syncope
  • Nausea and vomiting.

Diagnosis

Laboratory tests
  • Elevated serum troponin level.
  • Increased high-sensitivity cardiac troponin T-test (hs-cTnT).
  • Increased D-dimer.
  • Blood count is usually in the normal range.
  • Inflammatory markers are usually in the normal range.
ECG
  • new ST-T abnormalities in the precordial leads which are not present earlier.
  • inverted T waves in the inferior leads.
Coronary angiography
  • Invasive coronary angiography is the "gold standard" used for the diagnosis of SCAD.
Echocardiogram
  • Left ventricular dysfunction with decreased ejection fraction is seen.
  • Akinesia or hypokinesia is seen in the affected territory of the heart.
Intravascular ultrasound (IVUS) and optical coherence tomography (OCT)
  • These imaging modalities show detailed morphology about the intramural lesion in situations when angiographic images are not clear. IVUS is important in followup of the treatment of SCAD patients.
Optical coherence tomography (OCT)

Treatment

  • Medical management
  • Percutaneous coronary artery intervention (PCI)
  • Surgery
  • Coronary Artery Bypass Graft (CABG):

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