key: cord-0824758-zt21qic4
authors: Garg, Nikita; McClafferty, Brendan; Ramgobin, Devyani; Golamari, Reshma; Jain, Rahul; Jain, Rohit
title: Cardiology and COVID-19: do we have sufficient information?
date: 2020-10-30
journal: Future cardiology
DOI: 10.2217/fca-2020-0126
sha: 8b886becacec8962a8414158d0f7f51cea887ede
doc_id: 824758
cord_uid: zt21qic4

Novel coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2, which originated in Wuhan (China), transformed into a worldwide pandemic. The short span associated with the spread of the virus and its varied manifestations presents a steep learning curve for many clinicians on the front-line of treatment. Cardiology is one such affected area. This paper details the signs and symptoms of cardiovascular disease resulting from COVID-19, including its proposed pathophysiology, signs and symptoms, treatments and outcomes under investigation. The consensus is that COVID-19 patients with cardiovascular injury have a shorter duration from symptom onset to deterioration, higher mortality and higher prevalence in older populations. Diagnosis and intervention for patients with underlying cardiovascular comorbidities is critical.

ECG findings demonstrated diffuse ST-elevation in various studies. Laboratory analysis also has demonstrated elevated high-sensitivity troponin T and NT-proBNP [6, 11] . Indirect myocardial injury: This may occur via multiple mechanisms including direct damage to the myocardium in the setting of cytokine release related to activation of Type 1 and Type 2 T-helper cells. Patients also have higher levels of C-reactive protein (CRP), procalcitonin, ferritin, D-dimer, IL-2, IL-7, granulocyte-colony stimulating factor, IgG-induced protein 10, chemokine ligand 3 and TNF-α [12] [13] [14] . Additional cardiovascular considerations for these patients are hypoxemia secondary to respiratory failure, microvascular thrombosis due to hypercoagulability, adverse effects of various antiviral or corticosteroid medications, rupture of plaque and myocardial infarction via systemic inflammation, stress cardiomyopathy, electrolyte imbalance and hemodynamic derangement [9, 15, 16] . Comprehending the full scope of indirect injury to the myocardium because of SARS-CoV-2 infection will require further investigation into the interplay of how the various cytokines, proteins, systemic inflammation, etc. interact during and after an acute illness from SARS-CoV-2.

Underlying cardiac disease is one of the major risk factors in acquiring COVID-19. One of the earlier studies done in Wuhan showed that pre-existing cardiovascular disease had an associated case fatality rate of 10.5% [17] . In a study done by Shi et al. looking at cardiac injury and mortality, 10.6% of the population had underlying coronary heart disease and 4.1% had heart failure [12] . Underlying cardiac disease is also associated with a higher prevalence of infection, accounting for up to ∼42% in another US-based study by Arentz et al. [18] . A separate study indicated that cardiocerebrovascular disease accounted for 40% of populations affected by COVID-19 as evidenced by Chen et al. [19] . Specifically, pre-existing disease processes, such as acute coronary syndrome, myocardial infarction, myocarditis, reverse Takotsubo syndrome, left ventricular systolic dysfunction, heart failure and arrhythmias, are also reported to be exacerbated by COVID-19 virus [12, 20, 21] .

The signs and symptoms of cardiovascular injury from this disease range from chest pain, dyspnea, palpitations, hypotension, cardiogenic shock, to sudden cardiac death [22, 23] . Patients presenting with symptoms such as dyspnea and hypoxia without evidence of infection may be incorrectly presumed as having alternate respiratory sources of illness when in fact, they may have a concurrent cardiac etiology. These patients must have troponin and NT-pro-BNP along with other inflammatory biomarkers evaluated.

When it comes to signs, acute cardiac injury is defined as a high-sensitivity troponin I (TnI) above the 99th percentile upper reference limit is the most common [9] . Guo et al. studied 187 COVID-19 patients, of whom 52 (27.8%) had a myocardial injury as determined by elevated levels of TnT [24] . The incidence of cardiac injury ranged anywhere between 8 and 12% in various studies; the incidence being 13-fold higher in the ICU/severe category [8, 25] . Moreover, the patients admitted to the ICU had a 2.2-fold higher troponin level when compared with the nonintensive care units. Also, patients who neared death had significantly elevated TnT and NT-proBNP levels when compared with admission labs [24] .

Cardiomyopathy developed in around 33% of patients in a study by Arentz et al. [18] . Dong et al. reported four cases of heart failure. Two cases presented with severe symptoms and two with mild symptoms. The patients who were critically ill had a troponin I level of more than 20-fold [21] . Cardiogenic shock accounted for 7% fatalities in a study by Ruan et al. [26] . There was also a report of a case of fulminant myocarditis as evidenced by myocardial wall edema and extensive transmural late gadolinium enhancement on the chest MRI [27] .

COVID-19 patients have an increased risk of ST-segment elevation myocardial infarction (STEMI) with variable presentations and were noted to have a higher prevalence of nonobstructive disease and a poor prognosis [28] .

Temporary occurrence of S1Q3T3 and subsequent transient, nearly complete A-V block may reflect transient pulmonary artery hypertension secondary to trachea secretive obstruction, which may cause extensive small pulmonary artery compression [29] . The development of ST-elevation and ventricular tachycardia can have multiple triggers, such as hypoxia, hydroxychloroquine-induced arrhythmias, among others [29] . A study carried out by Wang et al. reported a 16.7% incidence of arrhythmia, more so in the intensive care unit (ICU) admissions [1] .

High prevalence of thrombosis (16.7%) has been noted in a prospective cohort study, particularly in COVID-19 patients admitted to the ICU for hypoxemic acute respiratory failure even despite theraputic or prophylactic anticoagulation. In addition, the incidence of pulmonary embolism was higher in COVID-19 acute respiratory distress syndrome patients (11.7%) compared with non-COVID-19 patients (2.1%). This study discussed how the mechanism involved in COVID-19 thrombosis remains unclear despite obvious endothelial inflammation as evidenced by high leves of von Wilibrand factor antigen and factor VIII. They hypothesized that hypoxemia in pulmonary capillaries leads to vasoconstriction reducing blood flow promoting occlusion in addition to activation of hypoxia-inducible factors inhibiting tissue factor and plasminogen-activator inhibitor-1 [30] .

For many patients with COVID-19, treatment has been mainly supportive and directed at relieving the associated symptoms of the virus. This holds for patients with mild clinical presentations who can manage themselves at home. For those who develop more severe complications such as acute respiratory distress syndrome (ARDS), sepsis, pneumonia and acute kidney injury, hospitalization is indicated [31] .

In terms of cardiac injury, prompt evaluation with cardiac biomarkers (as discussed above), echocardiogram and or a coronary angiogram should be made depending on patient presentation. Earlier in 2020, the controversy surrounding the continued use of ACE inhibitors/angiotensin receptor blockers existed; however, the current consensus is that these medications should be continued in older patients with increased risk of heart failure or patients with frank heart failure [32, 33] . Also, a large cohort analysis of 5894 SARS-CoV-2 positive patients found no substantial increase in the likelihood of a positive COVID-19 test or risk of severe COVID-19 associated with five common classes of antihypertensive medications [34] .

Remdesivir has been shown to have activity against SARS-CoV-2 in vitro [35] . Preliminary results of a randomized placebo-controlled trial for Remdesivir involving 1063 patients by the US National Institute of Allergy and Infectious Diseases indicated that treatment with this medication resulted in a 31% faster time to recovery (median of 11 vs 15 days with placebo) for patients to be discharged and no longer require supplemental oxygen (p < 0.001) [36] . However, there was also a double-blind randomized study of 237 patients with severe COVID-19 that indicated that Remdesivir compared with placebo for 10 days did not show a statistically different time to clinical improvement [37] . This same study indicated that a higher proportion of patients being treated with Remdesivir than placebo had dosing stopped prematurely because of adverse events such as aminotransferase or bilirubin increases, anorexia, nausea, vomiting and worsened cardiopulmonary status. We expect the further investigation into this medication to provide deeper insight as to its role in treating COVID-19 patients with cardiopulmonary disease.

In patients who have severe disease progression, vasopressors, mechanical ventilation and extracorporeal membrane oxygenation (ECMO) have proven to be successful [38] .

Clinical trials are also underway to further investigate the role of convalescent plasma therapy (CPT). A systematic review of 5 studies encompassing 27 patients reported that all studies found CPT significantly reduced the viral load and increased the level of neutralizing antibodies over time. Also, all studies reported zero mortality after receiving CPT at varying doses. However, the authors of the review indicated that while the studies reported good outcomes, they were considered at risk of bias due to a combination of non-randomized evaluations, duration of therapy, dosage, confounding and poor methodological conduct for participant selection [39] .

A recent study of 2104 patients who received dexamethasone and 4321 patients receiving usual care demonstrated a one-third reduced 28-day mortality in patients who received invasive mechanical ventilation (29.0 vs 40.7%, RR 0.65 [95% CI: 0.51-0.82]; p < 0.001). This is compared with one-fifth reduced 28-day mortality in patients who received oxygen without invasive mechanical ventilation (21.5 vs 25.0%, RR 0.80 [95% CI: 0.70-0.92]; p = 0.002). No change in mortality was demonstrated in patients that did not receive respiratory support (17.0 vs 13.2%, RR 1.22 [95% CI: 0.93-1.61]; p = 0.14) [40] .

Regarding diagnosis and treatment of venous thromboembolism in COVID-19 patients, an article published by the Journal of Thrombosis and Haemostasias in May of 2020 recommended following standard-of-care objective testing for diagnosis of suspected venous thromboembolism based on clinical index of suspicion in COVID-19 patients [41] . Venous thromboembolism prophylaxis in nonintensive care unit hospitalized COVID-19 patients is recommended (Table 1) . For these patients, routine thromboprophylaxis with low-molecular weight heparin or standard dose unfractionated heparin was the treatment of choice. For patients that are in the intensive care unit, the study recommended prophylactic-dose unfractionated heparin or low-molecular weight heparin. High risk bleed patients were recommended to receive intermediate-dose low-molecular weight heparin. The study indicated that treatment dose heparin should not be considered until further trials are available in this setting. Mechanical thromboprophylaxis (intermittent pneumonic compression devices) was also recommended. Duration of venous thromboembolism for hospitalized COVID-19 patients was recommended for all hospitalized COVID-19 patients Created using data from [12] .

that meet high venous thromboembolism risk criteria with duration of post-discharge prophylaxis of approximately 14-30 days [41] . 5%]) in those with elevated troponin but without the pre-existing disease. Mortality was significantly higher in those with elevated TnT levels (59.6%, i.e., 31 of 52) than in those with normal TnT levels (8.9%, i.e., 12 of 135) [24] . It should be noted that patients with cardiovascular diseases have a significantly increased risk of death when infected with SARS-CoV-2 (p < 0.001) [26] . In a cohort study by Shi et al. specifically looking at outcomes, 19.7% of patients had a cardiac injury (Figure 1 ). The patients with cardiac injury had higher inflammatory markers and other cardiac biomarkers, such as CRP, procalcitonin, CK-MB, myohemoglobin (MYO), TnI and NT-proBNP. These patients required greater proportions of invasive and noninvasive mechanical ventilation when compared with patients without cardiac injury. The same study also noted a higher risk of death at the time of symptom onset, as well as higher admissions in patients with underlying cardiac dysfunction [12] .

Similarly, an analysis of heart injury laboratory parameters in 273 COVID-19 patients, researchers found that elevated concentrations of CK-MB, MYO, Tnl and NT-proBNP in venous blood were associated with the severity and case fatality rate in COVID-19 [42] .

In a risk-adjusted study, NT-pro-BNP was found to be independently correlated with in-hospital death [43] .

Cardiac dysfunction is a well-known complication of COVID-19. ACE-2 receptors present in the heart may be the source of viral entry leading to myocardial damage. Pre-existing cardiac diseases in any form may predispose patients to be more susceptible to acquiring SARS-CoV-2. Cardiac injury can be measured by cardiac biomarkers such as troponins and NT-Pro-BNP and the presence of elevated cardiac biomarkers may indicate a worse prognosis. These cardiac biomarker elevations may be correlated with a rise in other inflammatory makers. The interplay between these cardiac biomarkers and inflammatory markers is under investigation. With the proposed mechanisms of myocardial injury summarized in Box 1. Clinical trials to evaluate multiple therapies are underway and their role in cardiology will become more apparent as research progresses. Management at this time is mainly supportive, in severe cases, ECMO may be utilized. 

We believe that over the course of the next 5-10 years, the work of scientists around the world will continue to illuminate the exact pathophysiology behind the various cardiovascular sequela of COVID-19. As understanding of the disease improves, recommendations for treatment will also continue to evolve. Potential negative impacts of these therapeutic interventions on the cardiovascular system may not present for years. In addition, new therapies will continue to arise with currently unknown benefits to prevention and treatment of cardiovascular complications of COVID-19. Finally, we expect larger retrospective studies to shed light into what worked to protect patients and what may have caused increased mortality.

• Coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) was originally recognized as a disease that affects the lungs and may cause complications such as acute respiratory distress syndrome. • Cardiology is an area of medicine that has been greatly impacted by this disease. Proposed pathophysiology • Direct damage via macrophage infiltration resulting in myocarditis (increased wall thickness, diffuse biventricular hypokinesis and left ventricular dysfunction). • Indirect damage via cytokine release related to T-cell activation, hypoxemia secondary to respiratory failure, microvascular thrombosis, adverse effects of medications, plaque rupture, myocardial infarction, stress cardiomyopathy, electrolyte imbalances and hemodynamic derangement.

• Underlying cardiovascular disease is associated with increased mortality, as well as a higher prevalence of infection.

• Cardiovascular symptoms from COVID-19 range from chest pain, dyspnea, palpitations, hypotension, cardiogenic shock, to sudden cardiac death. Treatment • Preliminary results of treatments showing improved patient outcomes at this time include supportive therapy, remdesivir, convalescent plasma, dexamethasone and anticoagulation. • The current consensus is that angiotensin-converting enzyme inhibitors/angiotensin receptor blocker medications should be continued in older patients with increased risk of heart failure or patients with frank heart failure. • The exact recommendations for anti-coagulation for COVID-19 patients is evolving. Outcomes • One study determined that 19.7% of COVID-19 positive patients had a cardiac injury.

• Patients with elevated troponin levels and existing cardiovascular disease had higher mortality rates. 

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This article is important as it describes current recommendations for thromboembolism diagnosis and treatment in different types of COVID-19 patients

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Special Report Garg, McClafferty, Ramgobin, Golamari & Jain

The authors have no relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript. This includes employment, consultancies, honoraria, stock ownership or options, expert testimony, grants or patents received or pending, or royalties.No writing assistance was utilized in the production of this manuscript.