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Acute viral myocarditis often confounds with ischemic injury
Frontline health care workers are facing escalating challenges with rapidly spreading coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection.1 Hospitalists will often deal with various manifestations of acute cardiac injury, controversial withholding of ACE inhibitors (ACEI) or angiotensin receptor blockers (ARBs), arrhythmic toxicities from such drug therapies as hydroxychloroquine.
Presentation and cardiac risks from COVID-19
Patients with COVID-19 often have presented with noncardiac symptoms, usually a febrile illness associated with cough or shortness of breath. Recent reports from Italy and New York have suggested patients also can present with isolated cardiac involvement without any other symptoms that can portend a grim prognosis.2 Cardiac effects include myocarditis, acute coronary syndrome, malignant arrhythmias ultimately cardiogenic shock and cardiac arrest.3
The mortality rate correlates with older age, preexisting health conditions, and availability of medical resources. A recent meta-analysis including 53,000 COVID-19 patients found the most common comorbidities were hypertension (19%), diabetes (8 %) and cardiovascular disease (CVD) (3%).4 Half of the cases died from respiratory failure and one-third have died from concomitant respiratory and heart failure. Acute heart failure alone accounted for about 7% of cases.5
Overall mortality rate can be better understood with the largest case series to-date of COVID-19 in mainland China published by the Chinese Center for Disease Control and Prevention. The overall case-fatality rate was 2.3% (1,023 deaths among 44,672 confirmed cases), but the mortality reached 10.5% in patients with underlying CVD.6
Acute cardiac injuries in COVID-19
Acute cardiac injury (ACI) is defined as troponin elevation above the 99th percentile of the upper reference limit.7 A practical description of ACI in COVID-19 patients should also include broader definition with new abnormalities in ECG since not all patients with acute cardiac effects have developed troponin elevation.3 More recent reports showed up to 28% of hospitalized patients had a myocardial injury.3
It is not uncommon to see a patient with COVID-19 myocarditis as a mimicker of acute ST-elevation myocardial infarction (STEMI). The mechanism of ACI is unknown, though several hypotheses have been proposed based on case series and retrospective reviews. These include direct viral invasion into myocardial cells leading to myocarditis, oxygen demand-supply mismatch, acute coronary syndrome from plaque rupture, stress, or cytokine-mediated cardiomyopathy.3 The exact incidence of true MI from occlusive coronary disease in the COVID-19 population is yet unknown.
In some cases, troponin elevation may be a late manifestation of COVID-19. As coronavirus disease progressed slowly, a rapid rise of troponin was noted when patients developed acute respiratory failure after 10 days of illness. Among nonsurvivors, a steady rise in troponin was observed from day 4 through day 22.8
ACI is associated with ICU admission and mortality. Both troponin and BNP levels increased significantly during the course of hospitalization in those who ultimately died, but no such changes were evident in survivors.3 ACI was higher in nonsurvivors (59%) than in survivors (1%).8 ACI was higher in ICU patients (22%), compared with non-ICU patients (2%).9 Patients with CVD were more likely to exhibit elevation of troponin levels (54%), compared with patients without CVD (13%).3
Higher troponin levels and the presence of CVD are directly proportional to severe disease and death. Patients with elevated troponin developed more frequent complications including acute respiratory distress syndrome, malignant arrhythmias including ventricular tachycardia/ventricular fibrillation, acute coagulopathy, and acute kidney injury.3,8 Death was markedly higher in patients with elevated troponin, compared with normal levels: 60% versus 9%. Only 8% with no CVD and normal troponin died, whereas 69% of people with underlying CVD and elevated troponin died.3
The median duration from illness onset to death was 23 (8-41) days in the group with elevated troponin. Patients with CVD and escalation of troponin levels had the shortest survival of 1-5 days. The dynamic rise of cardiac biomarkers and increased incidence of malignant arrhythmias during the course of illness shows that myocardial injury played a greater role in the fatal outcome of COVID-19 than the presence of preexisting CVD itself.3
Management of acute cardiac issues in COVID-19
There are no established therapeutic options with randomized, clinical trials specific to the management of COVID-19 patients at this point. Standard supportive care and individualized treatment plan based on existing guidelines is probably the best approach. Disposition of cases and cardiac testing should be tailored, based on local protocols, availability of resources and expertise.10
There seems to be a consensus that baseline troponin levels should be obtained in all admitted patients. Repeat troponin levels can be obtained based on the severity of illness, for example, daily troponin checks are reasonable in ICU patients and every-other-day troponin testing may be reasonable in general inpatients. Routine troponin testing in minimally symptomatic or asymptomatic patients will likely not change any outcome.3,11,12
Daily ECG is reasonable in severe COVID-19. However, routine transthoracic ECGs are not reasonable, unless it will change further treatment plans. Transthoracic electrocardiograms (TTE) are reasonable in patients with significant troponin elevation, a decline in central venous oxygen saturation, new heart failure, shock, new persistent arrhythmias, or significant new ECG changes.12
Limited TTEs for a focused exam enough to answer the clinical question should be ordered to minimize the risk of viral exposure to the sonographers. Transesophageal echo will rarely be needed, and its use should be minimized to reduce direct contact exposure and because of anesthesia risks.13 Routine stress testing should not be ordered in active COVID-19 and should be deferred for outpatient evaluation, if clinically indicated, once the patient recovers from the infection.12
Myocarditis and pericarditis are potential manifestations of acute cardiac injury. Recent case reports have suggested evidence of myocarditis confirmed with cardiac MRI.11 Because of high fatality rates with cardiac involvement and no proven therapies yet, the role of routine advanced cardiac imaging such as cardiac CT, cardiac MRI, or cardiac biopsy is unclear.
Myocarditis can likely be caused either by the virus itself, or the body’s immune and inflammatory response (cytokine storm) to the virus.2,3 The use of anti-inflammatory drugs like colchicine, ibuprofen, steroids, or statins is not yet established.10,12 Drugs like remdesivir, lopinavir-ritonavir, hydroxychloroquine, chloroquine, and anti-interleukin-6 agents have been invariably used with some anecdotal success and randomized clinical trials for some of these drugs are presently undergoing.
Physicians may encounter situations to call a STEMI code or not in COVID-19 patients.2,11 Patients may have substernal pain, diffuse or regional ST elevations in ECG and reduced left ventricular dysfunction with regional wall motion abnormalities on ECG. These findings may be casued by myocarditis, acute type 1 MI, or stress-induced cardiomyopathy. Clinicians should make their judgment based on the overall pretest probability for type 1 MI, incorporating risk factor profiles and the presence of typical symptoms.
Treatment practice for questionable STEMI cases will likely vary across the country as we are learning more about the virus. Cath lab operators are at risk for COVID-19 infection through direct contact with patients. Few cardiologists were admitted after COVID-19 infections in the ICU at a New York hospital after they were involved in a acute MI case in a cath lab.14 Based on the Chinese experience, some have suggested the idea of lytic therapy first with follow-up cardiac CT to assess the recanalization of perfusion status, but at this point, this strategy remains controversial in the United States. In addition, if the patient has myocarditis instead, there will be a risk for pericardial effusion and hemorrhagic complications with lytic therapy.
Case examples
1. A 70-year-old male presents with fevers, chest pain, cough, shortness of breath. He has a history of metabolic syndrome and 30 pack-years of smoking. His ECG showed 1.5 mm ST elevation in inferior leads with reciprocal ST depressions in lateral leads, and his initial troponin is 2. Echocardiogram showed reduced left ventricle ejection fraction of 32% and inferior wall hypokinesis. He is suspected COVID-19 and his PCR result is pending. How would you manage this patient?
This patient presented with febrile illness and, but he had a very high pretest probability for obstructive coronary artery disease based on his age, male sex, and multiple risk factors. He may have a viral syndrome and it is a stressful situation for him. This may have precipitated plaque rupture causing acute MI.
Activating the STEMI pathway for emergent left heart catheterization is likely appropriate in this case. Coronary angiogram in this patient showed a 100% occluded mid-right coronary artery with a fresh thrombus. Delaying cardiac cath would have possibly led to malignant arrhythmias and death from ischemic injury. We need to be cognizant patients can die from non–COVID-related emergencies also.
2. An 18-year-old healthy male presents with cough and chest pain and has bilateral lung infiltrates. ECG showed anterolateral 2 mm ST elevations and no reciprocal ST changes. Stat TTE showed anterior wall hypokinesis and LV function 30% and his initial troponin are 0.6 (normal is < .05). The nasopharyngeal swab is sent out and his COVID result is pending. How would you manage this patient?
A young patient with no cardiovascular risk factors has a very low pretest probability for obstructive coronary disease and the likelihood of having a true ischemic MI is low even though he has significant new ST elevations. Especially with presumed COVID-19 and risk of virus exposure to the cath lab personnel, it will be prudent to manage this patient with supportive therapy including beta-blockers, ACEIs, etc. Repeat echo in 7 days before discharge showed improved LVEF 45%.
Controversy on ACEI/ARB
The SARS-CoV-2 virus enters via cell-entry receptor namely angiotensin-converting enzyme 2 (ACE2). SARS-CoV-2 is thought to have a higher affinity for ACE2 than other SARS-viruses.15
ACE2 is expressed in the heart, lungs, vasculature, and kidneys. ACEI and ARBs in animal models increase the expression of ACE2,16 though this has not been confirmed in human studies. This has led to the hypothesis that ACEI and ARBs might worsen myocarditis or precipitate the acute coronary syndrome. It has also been hypothesized that the upregulation of ACE2 is therapeutic in COVID-19 and that ARBs might be protective during infection.17
The increased ACE2 expression induced by ACEI or ARB would aggravate lung injury of patients with COVID-19. However, a previous study showed a beneficial effect of ACEI/ARB in patients admitted with viral pneumonia, as it significantly reduced the pulmonary inflammatory response and cytokine release caused by virus infection.18
Therefore, this remains an area of investigation and it is unclear how these medications affect patients with COVID-19. In a recent review, with a limited number of patients, the mortality of those treated with or without the use of ACEI/ARB did not show a significant difference in the outcome.3
Both American and European cardiology societies recommend against routine discontinuation of ACEI and ARBs in patients with COVID-19 because of risks of uncontrolled hypertension and heart failure, stroke, or heart attack.19 However, it will be reasonable to hold off in inpatients in cases of acute kidney injury, hypotension, shock, etc.12
Cardiac concern about hydroxychloroquine and chloroquine
Hydroxychloroquine (HCQ) is an antimalarial drug shown to have in vitro (but not yet in vivo) activity against diverse RNA viruses, including SARS-CoV-1.20 An expert consensus group from China suggests that chloroquine improved lung imaging and shortened disease course.21 HCQ was found to be more potent than chloroquine in inhibiting SARS-CoV-2 in vitro.22
Based on limited in vitro and anecdotal clinical data from other countries, the U.S. Food and Drug Administration recently authorized emergency use of chloroquine and HCQ in hopes of slowing the progression of the disease when a clinical trial is not available, or participation is not feasible for use of these drugs in hospitalized patients. However, with no clear benefit, there is a concern for possible risks with cardiac toxicity.
HCQ is known to cause cardiomyopathy in a dose-dependent manner over several years. Given the anticipated short duration in COVID-19, it is not an expected risk. QT-segment prolongation and torsades de pointes, especially if administered in combination with azithromycin, is possible even in short term use.23
Given above, frequent ECG monitoring is indicated for patients being treated with chloroquine or HCQ. All other QT-prolonging drugs should be discontinued. Continuous telemetry monitoring while under treatment is reasonable. HCQ should not be started if baseline QTc is > 500 msec and it should be stopped if the patient develops ventricular arrhythmias.12
Dr. Subedi is a noninvasive cardiologist for Wellspan Health System in Franklin and Cumberland counties in south central Pennsylvania. He is a clinical assistant professor of medicine at Penn State College of Medicine, Hershey, Pa. He is an active member of the critical care committee at Wellspan Chambersburg (Pa.) Hospital. Dr. Tirupathi is the medical director of Keystone Infectious Diseases/HIV in Chambersburg and currently chair of infection prevention at Wellspan Chambersburg and Waynesboro Hospitals, all in Pennsylvania. He also is the lead physician for antibiotic stewardship at these hospitals. Dr. Areti is currently working as a hospitalist at Wellspan Chambersburg Hospital and is a member of the Wellspan pharmacy and therapeutics committee. Dr. Palabindala is hospital medicine division chief at the University of Mississippi Medical Center, Jackson.
Key points
- Acute cardiac injury or myocarditis is common among patients infected with COVID-19. Often, COVID myocarditis can mimic acute MI or stress cardiomyopathy and will present diagnostic and therapeutic challenges. On the other hand, isolated cardiac involvement can occur, even without symptoms and signs of interstitial pneumonia.
- A most important indicator of worse prediction is the degree of myocardial injury, regardless of preexisting conditions or underlying cardiovascular disease.
- Early recognition of cardiac involvement will be helpful in targeting more aggressive supportive therapies. Commonly available clinical tools like bloodwork, ECG, or echocardiogram should be adequate to diagnose carditis in most cases.
- Advanced cardiac imaging tests or cardiac biopsy are of uncertain benefits. Meticulous evaluation is needed for possible ischemic changes before taking the patient to the cardiac cath lab in order to reduce unnecessary virus exposure to the operators.
- ACEI/ARB should be continued in most cases in COVID patients based on cardiology societies’ recommendations.
- With the widespread use of antimalarial drugs like chloroquine or hydroxychloroquine, frequent ECG and continuous telemetry monitoring is reasonable to rule out ventricular arrhythmias like torsades.
- There is no specific treatment to date for acute cardiac injuries. Since there are no specific guidelines and information about the virus is rapidly changing, it will be prudent to follow common-sense approaches outlined by institutions like the Brigham and Women’s Hospital COVID-19 Critical Care clinical guidelines, which incorporate new clinical information on a daily basis ().
References
1. Rothan HA and Byrareddy SN. The epidemiology and pathogenesis of coronavirus disease (COVID-19) outbreak. J Autoimmun. 2020 May;109:102433. doi: 10.1016/j.jaut.2020.102433.
2. Kolata G. A heart attack? No, it was the coronavirus. New York Times 2020 Mar 27.
3. Guo T et al. Cardiovascular implications of fatal outcomes of patients with coronavirus disease 2019 (COVID-19). JAMA Cardiol. 2020 Mar 27. doi: 10.1001/jamacardio.2020.1017.
4. Zhao X et al. Incidence, clinical characteristics and prognostic factor of patients with COVID-19: a systematic review and meta-analysis. MedRxIV. 2020 Mar 20. doi: 10.1101/2020.03.17.20037572.
5. Ruan Q et al. Clinical predictors of mortality due to COVID-19 based on an analysis of data of 150 patients from Wuhan, China. Intensive Care Med. 2020 Mar 3. doi: 10.1007/s00134-020-05991-x.
6. Wu Z and McGoogan JM. Characteristics of and important lessons from the coronavirus disease 2019 (COVID-19) outbreak in China: Summary of a report of 72,314 cases from the Chinese Center for Disease Control and Prevention. JAMA. 2020 Feb 24. doi: 10.1001/jama.2020.2648.
7. Thygesen K et al. Fourth universal definition of myocardial infarction (2018). J Am Coll Cardiol. 2018 Oct;72:2231-64.
8. Zhou F et al. Clinical course and risk factors for mortality of adult inpatients with COVID-19 in Wuhan, China: a retrospective cohort study. Lancet. 2020 Mar 28;395(10229):1054-62.
9. Wang D et al. Clinical characteristics of 138 hospitalized patients with 2019 novel coronavirus-infected pneumonia in Wuhan, China. JAMA. 2020 Feb 7. doi: 10.1001/jama.2020.1585.
10. CDC: Therapeutic options for patients with COVID-19. Updated April 13, 2020.
11. Inciardi RM et al. Cardiac involvement in a patient with coronavirus disease 2019 (COVID-19). JAMA Cardiol. 2020 Mar 27. doi: 10.1001/jamacardio.2020.1096.
12. Brigham and Women’s Hospital COVID-19 Critical Care Clinical Guidelines.
13. American Society of Echocardiography Statement on COVID-19. 2020 Apr 1.
14. A cardiologist in Brooklyn infected with COVID-19. @jigneshpatelMD. 2020 Mar 20.
15. Paules CI et al. Coronavirus infections – more than just the common cold. JAMA. 2020 Jan 23. doi: 10.1001/jama.2020.0757.
16. Zheng YY et al. COVID-19 and the cardiovascular system. Nat Rev Cardiol. 2020 May;17(5):259-60.
17. Gurwitz D. Angiotensin receptor blockers as tentative SARS-CoV-2 therapeutics. Drug Dev Res. 2020 Mar 4. doi: 10.1002/ddr.21656.
18. Henry C et al. Impact of angiotensin-converting enzyme inhibitors and statins on viral pneumonia. Proc (Bayl Univ Med Cent). 2018 Oct 26;31(4):419-23.
19. HFSA/ACC/AHA statement addresses concerns re: Using RAAS antagonists in COVID-19. 2020 Mar 17.
20. Touret F and de Lamballerie X. Of chloroquine and COVID-19. Antiviral Res. 2020 May;177:104762. doi: 10.1016/j.antiviral.2020.104762.
21. Expert consensus on chloroquine phosphate for the treatment of novel coronavirus pneumonia. Chinese journal of tuberculosis and respiratory diseases. 2020 Mar 12;43(3):185-8.
22. Yao X et al. In vitro antiviral activity and projection of optimized dosing design of hydroxychloroquine for the treatment of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Clin Infect Dis. 2020 Mar 9. doi: 10.1093/cid/ciaa237.
23. Devaux CA et al. New insights on the antiviral effects of chloroquine against coronavirus: What to expect for COVID-19? Int J Antimicrob Agents. 2020 Mar 12:105938. doi: 10.1016/j.ijantimicag.2020.105938.
Acute viral myocarditis often confounds with ischemic injury
Acute viral myocarditis often confounds with ischemic injury
Frontline health care workers are facing escalating challenges with rapidly spreading coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection.1 Hospitalists will often deal with various manifestations of acute cardiac injury, controversial withholding of ACE inhibitors (ACEI) or angiotensin receptor blockers (ARBs), arrhythmic toxicities from such drug therapies as hydroxychloroquine.
Presentation and cardiac risks from COVID-19
Patients with COVID-19 often have presented with noncardiac symptoms, usually a febrile illness associated with cough or shortness of breath. Recent reports from Italy and New York have suggested patients also can present with isolated cardiac involvement without any other symptoms that can portend a grim prognosis.2 Cardiac effects include myocarditis, acute coronary syndrome, malignant arrhythmias ultimately cardiogenic shock and cardiac arrest.3
The mortality rate correlates with older age, preexisting health conditions, and availability of medical resources. A recent meta-analysis including 53,000 COVID-19 patients found the most common comorbidities were hypertension (19%), diabetes (8 %) and cardiovascular disease (CVD) (3%).4 Half of the cases died from respiratory failure and one-third have died from concomitant respiratory and heart failure. Acute heart failure alone accounted for about 7% of cases.5
Overall mortality rate can be better understood with the largest case series to-date of COVID-19 in mainland China published by the Chinese Center for Disease Control and Prevention. The overall case-fatality rate was 2.3% (1,023 deaths among 44,672 confirmed cases), but the mortality reached 10.5% in patients with underlying CVD.6
Acute cardiac injuries in COVID-19
Acute cardiac injury (ACI) is defined as troponin elevation above the 99th percentile of the upper reference limit.7 A practical description of ACI in COVID-19 patients should also include broader definition with new abnormalities in ECG since not all patients with acute cardiac effects have developed troponin elevation.3 More recent reports showed up to 28% of hospitalized patients had a myocardial injury.3
It is not uncommon to see a patient with COVID-19 myocarditis as a mimicker of acute ST-elevation myocardial infarction (STEMI). The mechanism of ACI is unknown, though several hypotheses have been proposed based on case series and retrospective reviews. These include direct viral invasion into myocardial cells leading to myocarditis, oxygen demand-supply mismatch, acute coronary syndrome from plaque rupture, stress, or cytokine-mediated cardiomyopathy.3 The exact incidence of true MI from occlusive coronary disease in the COVID-19 population is yet unknown.
In some cases, troponin elevation may be a late manifestation of COVID-19. As coronavirus disease progressed slowly, a rapid rise of troponin was noted when patients developed acute respiratory failure after 10 days of illness. Among nonsurvivors, a steady rise in troponin was observed from day 4 through day 22.8
ACI is associated with ICU admission and mortality. Both troponin and BNP levels increased significantly during the course of hospitalization in those who ultimately died, but no such changes were evident in survivors.3 ACI was higher in nonsurvivors (59%) than in survivors (1%).8 ACI was higher in ICU patients (22%), compared with non-ICU patients (2%).9 Patients with CVD were more likely to exhibit elevation of troponin levels (54%), compared with patients without CVD (13%).3
Higher troponin levels and the presence of CVD are directly proportional to severe disease and death. Patients with elevated troponin developed more frequent complications including acute respiratory distress syndrome, malignant arrhythmias including ventricular tachycardia/ventricular fibrillation, acute coagulopathy, and acute kidney injury.3,8 Death was markedly higher in patients with elevated troponin, compared with normal levels: 60% versus 9%. Only 8% with no CVD and normal troponin died, whereas 69% of people with underlying CVD and elevated troponin died.3
The median duration from illness onset to death was 23 (8-41) days in the group with elevated troponin. Patients with CVD and escalation of troponin levels had the shortest survival of 1-5 days. The dynamic rise of cardiac biomarkers and increased incidence of malignant arrhythmias during the course of illness shows that myocardial injury played a greater role in the fatal outcome of COVID-19 than the presence of preexisting CVD itself.3
Management of acute cardiac issues in COVID-19
There are no established therapeutic options with randomized, clinical trials specific to the management of COVID-19 patients at this point. Standard supportive care and individualized treatment plan based on existing guidelines is probably the best approach. Disposition of cases and cardiac testing should be tailored, based on local protocols, availability of resources and expertise.10
There seems to be a consensus that baseline troponin levels should be obtained in all admitted patients. Repeat troponin levels can be obtained based on the severity of illness, for example, daily troponin checks are reasonable in ICU patients and every-other-day troponin testing may be reasonable in general inpatients. Routine troponin testing in minimally symptomatic or asymptomatic patients will likely not change any outcome.3,11,12
Daily ECG is reasonable in severe COVID-19. However, routine transthoracic ECGs are not reasonable, unless it will change further treatment plans. Transthoracic electrocardiograms (TTE) are reasonable in patients with significant troponin elevation, a decline in central venous oxygen saturation, new heart failure, shock, new persistent arrhythmias, or significant new ECG changes.12
Limited TTEs for a focused exam enough to answer the clinical question should be ordered to minimize the risk of viral exposure to the sonographers. Transesophageal echo will rarely be needed, and its use should be minimized to reduce direct contact exposure and because of anesthesia risks.13 Routine stress testing should not be ordered in active COVID-19 and should be deferred for outpatient evaluation, if clinically indicated, once the patient recovers from the infection.12
Myocarditis and pericarditis are potential manifestations of acute cardiac injury. Recent case reports have suggested evidence of myocarditis confirmed with cardiac MRI.11 Because of high fatality rates with cardiac involvement and no proven therapies yet, the role of routine advanced cardiac imaging such as cardiac CT, cardiac MRI, or cardiac biopsy is unclear.
Myocarditis can likely be caused either by the virus itself, or the body’s immune and inflammatory response (cytokine storm) to the virus.2,3 The use of anti-inflammatory drugs like colchicine, ibuprofen, steroids, or statins is not yet established.10,12 Drugs like remdesivir, lopinavir-ritonavir, hydroxychloroquine, chloroquine, and anti-interleukin-6 agents have been invariably used with some anecdotal success and randomized clinical trials for some of these drugs are presently undergoing.
Physicians may encounter situations to call a STEMI code or not in COVID-19 patients.2,11 Patients may have substernal pain, diffuse or regional ST elevations in ECG and reduced left ventricular dysfunction with regional wall motion abnormalities on ECG. These findings may be casued by myocarditis, acute type 1 MI, or stress-induced cardiomyopathy. Clinicians should make their judgment based on the overall pretest probability for type 1 MI, incorporating risk factor profiles and the presence of typical symptoms.
Treatment practice for questionable STEMI cases will likely vary across the country as we are learning more about the virus. Cath lab operators are at risk for COVID-19 infection through direct contact with patients. Few cardiologists were admitted after COVID-19 infections in the ICU at a New York hospital after they were involved in a acute MI case in a cath lab.14 Based on the Chinese experience, some have suggested the idea of lytic therapy first with follow-up cardiac CT to assess the recanalization of perfusion status, but at this point, this strategy remains controversial in the United States. In addition, if the patient has myocarditis instead, there will be a risk for pericardial effusion and hemorrhagic complications with lytic therapy.
Case examples
1. A 70-year-old male presents with fevers, chest pain, cough, shortness of breath. He has a history of metabolic syndrome and 30 pack-years of smoking. His ECG showed 1.5 mm ST elevation in inferior leads with reciprocal ST depressions in lateral leads, and his initial troponin is 2. Echocardiogram showed reduced left ventricle ejection fraction of 32% and inferior wall hypokinesis. He is suspected COVID-19 and his PCR result is pending. How would you manage this patient?
This patient presented with febrile illness and, but he had a very high pretest probability for obstructive coronary artery disease based on his age, male sex, and multiple risk factors. He may have a viral syndrome and it is a stressful situation for him. This may have precipitated plaque rupture causing acute MI.
Activating the STEMI pathway for emergent left heart catheterization is likely appropriate in this case. Coronary angiogram in this patient showed a 100% occluded mid-right coronary artery with a fresh thrombus. Delaying cardiac cath would have possibly led to malignant arrhythmias and death from ischemic injury. We need to be cognizant patients can die from non–COVID-related emergencies also.
2. An 18-year-old healthy male presents with cough and chest pain and has bilateral lung infiltrates. ECG showed anterolateral 2 mm ST elevations and no reciprocal ST changes. Stat TTE showed anterior wall hypokinesis and LV function 30% and his initial troponin are 0.6 (normal is < .05). The nasopharyngeal swab is sent out and his COVID result is pending. How would you manage this patient?
A young patient with no cardiovascular risk factors has a very low pretest probability for obstructive coronary disease and the likelihood of having a true ischemic MI is low even though he has significant new ST elevations. Especially with presumed COVID-19 and risk of virus exposure to the cath lab personnel, it will be prudent to manage this patient with supportive therapy including beta-blockers, ACEIs, etc. Repeat echo in 7 days before discharge showed improved LVEF 45%.
Controversy on ACEI/ARB
The SARS-CoV-2 virus enters via cell-entry receptor namely angiotensin-converting enzyme 2 (ACE2). SARS-CoV-2 is thought to have a higher affinity for ACE2 than other SARS-viruses.15
ACE2 is expressed in the heart, lungs, vasculature, and kidneys. ACEI and ARBs in animal models increase the expression of ACE2,16 though this has not been confirmed in human studies. This has led to the hypothesis that ACEI and ARBs might worsen myocarditis or precipitate the acute coronary syndrome. It has also been hypothesized that the upregulation of ACE2 is therapeutic in COVID-19 and that ARBs might be protective during infection.17
The increased ACE2 expression induced by ACEI or ARB would aggravate lung injury of patients with COVID-19. However, a previous study showed a beneficial effect of ACEI/ARB in patients admitted with viral pneumonia, as it significantly reduced the pulmonary inflammatory response and cytokine release caused by virus infection.18
Therefore, this remains an area of investigation and it is unclear how these medications affect patients with COVID-19. In a recent review, with a limited number of patients, the mortality of those treated with or without the use of ACEI/ARB did not show a significant difference in the outcome.3
Both American and European cardiology societies recommend against routine discontinuation of ACEI and ARBs in patients with COVID-19 because of risks of uncontrolled hypertension and heart failure, stroke, or heart attack.19 However, it will be reasonable to hold off in inpatients in cases of acute kidney injury, hypotension, shock, etc.12
Cardiac concern about hydroxychloroquine and chloroquine
Hydroxychloroquine (HCQ) is an antimalarial drug shown to have in vitro (but not yet in vivo) activity against diverse RNA viruses, including SARS-CoV-1.20 An expert consensus group from China suggests that chloroquine improved lung imaging and shortened disease course.21 HCQ was found to be more potent than chloroquine in inhibiting SARS-CoV-2 in vitro.22
Based on limited in vitro and anecdotal clinical data from other countries, the U.S. Food and Drug Administration recently authorized emergency use of chloroquine and HCQ in hopes of slowing the progression of the disease when a clinical trial is not available, or participation is not feasible for use of these drugs in hospitalized patients. However, with no clear benefit, there is a concern for possible risks with cardiac toxicity.
HCQ is known to cause cardiomyopathy in a dose-dependent manner over several years. Given the anticipated short duration in COVID-19, it is not an expected risk. QT-segment prolongation and torsades de pointes, especially if administered in combination with azithromycin, is possible even in short term use.23
Given above, frequent ECG monitoring is indicated for patients being treated with chloroquine or HCQ. All other QT-prolonging drugs should be discontinued. Continuous telemetry monitoring while under treatment is reasonable. HCQ should not be started if baseline QTc is > 500 msec and it should be stopped if the patient develops ventricular arrhythmias.12
Dr. Subedi is a noninvasive cardiologist for Wellspan Health System in Franklin and Cumberland counties in south central Pennsylvania. He is a clinical assistant professor of medicine at Penn State College of Medicine, Hershey, Pa. He is an active member of the critical care committee at Wellspan Chambersburg (Pa.) Hospital. Dr. Tirupathi is the medical director of Keystone Infectious Diseases/HIV in Chambersburg and currently chair of infection prevention at Wellspan Chambersburg and Waynesboro Hospitals, all in Pennsylvania. He also is the lead physician for antibiotic stewardship at these hospitals. Dr. Areti is currently working as a hospitalist at Wellspan Chambersburg Hospital and is a member of the Wellspan pharmacy and therapeutics committee. Dr. Palabindala is hospital medicine division chief at the University of Mississippi Medical Center, Jackson.
Key points
- Acute cardiac injury or myocarditis is common among patients infected with COVID-19. Often, COVID myocarditis can mimic acute MI or stress cardiomyopathy and will present diagnostic and therapeutic challenges. On the other hand, isolated cardiac involvement can occur, even without symptoms and signs of interstitial pneumonia.
- A most important indicator of worse prediction is the degree of myocardial injury, regardless of preexisting conditions or underlying cardiovascular disease.
- Early recognition of cardiac involvement will be helpful in targeting more aggressive supportive therapies. Commonly available clinical tools like bloodwork, ECG, or echocardiogram should be adequate to diagnose carditis in most cases.
- Advanced cardiac imaging tests or cardiac biopsy are of uncertain benefits. Meticulous evaluation is needed for possible ischemic changes before taking the patient to the cardiac cath lab in order to reduce unnecessary virus exposure to the operators.
- ACEI/ARB should be continued in most cases in COVID patients based on cardiology societies’ recommendations.
- With the widespread use of antimalarial drugs like chloroquine or hydroxychloroquine, frequent ECG and continuous telemetry monitoring is reasonable to rule out ventricular arrhythmias like torsades.
- There is no specific treatment to date for acute cardiac injuries. Since there are no specific guidelines and information about the virus is rapidly changing, it will be prudent to follow common-sense approaches outlined by institutions like the Brigham and Women’s Hospital COVID-19 Critical Care clinical guidelines, which incorporate new clinical information on a daily basis ().
References
1. Rothan HA and Byrareddy SN. The epidemiology and pathogenesis of coronavirus disease (COVID-19) outbreak. J Autoimmun. 2020 May;109:102433. doi: 10.1016/j.jaut.2020.102433.
2. Kolata G. A heart attack? No, it was the coronavirus. New York Times 2020 Mar 27.
3. Guo T et al. Cardiovascular implications of fatal outcomes of patients with coronavirus disease 2019 (COVID-19). JAMA Cardiol. 2020 Mar 27. doi: 10.1001/jamacardio.2020.1017.
4. Zhao X et al. Incidence, clinical characteristics and prognostic factor of patients with COVID-19: a systematic review and meta-analysis. MedRxIV. 2020 Mar 20. doi: 10.1101/2020.03.17.20037572.
5. Ruan Q et al. Clinical predictors of mortality due to COVID-19 based on an analysis of data of 150 patients from Wuhan, China. Intensive Care Med. 2020 Mar 3. doi: 10.1007/s00134-020-05991-x.
6. Wu Z and McGoogan JM. Characteristics of and important lessons from the coronavirus disease 2019 (COVID-19) outbreak in China: Summary of a report of 72,314 cases from the Chinese Center for Disease Control and Prevention. JAMA. 2020 Feb 24. doi: 10.1001/jama.2020.2648.
7. Thygesen K et al. Fourth universal definition of myocardial infarction (2018). J Am Coll Cardiol. 2018 Oct;72:2231-64.
8. Zhou F et al. Clinical course and risk factors for mortality of adult inpatients with COVID-19 in Wuhan, China: a retrospective cohort study. Lancet. 2020 Mar 28;395(10229):1054-62.
9. Wang D et al. Clinical characteristics of 138 hospitalized patients with 2019 novel coronavirus-infected pneumonia in Wuhan, China. JAMA. 2020 Feb 7. doi: 10.1001/jama.2020.1585.
10. CDC: Therapeutic options for patients with COVID-19. Updated April 13, 2020.
11. Inciardi RM et al. Cardiac involvement in a patient with coronavirus disease 2019 (COVID-19). JAMA Cardiol. 2020 Mar 27. doi: 10.1001/jamacardio.2020.1096.
12. Brigham and Women’s Hospital COVID-19 Critical Care Clinical Guidelines.
13. American Society of Echocardiography Statement on COVID-19. 2020 Apr 1.
14. A cardiologist in Brooklyn infected with COVID-19. @jigneshpatelMD. 2020 Mar 20.
15. Paules CI et al. Coronavirus infections – more than just the common cold. JAMA. 2020 Jan 23. doi: 10.1001/jama.2020.0757.
16. Zheng YY et al. COVID-19 and the cardiovascular system. Nat Rev Cardiol. 2020 May;17(5):259-60.
17. Gurwitz D. Angiotensin receptor blockers as tentative SARS-CoV-2 therapeutics. Drug Dev Res. 2020 Mar 4. doi: 10.1002/ddr.21656.
18. Henry C et al. Impact of angiotensin-converting enzyme inhibitors and statins on viral pneumonia. Proc (Bayl Univ Med Cent). 2018 Oct 26;31(4):419-23.
19. HFSA/ACC/AHA statement addresses concerns re: Using RAAS antagonists in COVID-19. 2020 Mar 17.
20. Touret F and de Lamballerie X. Of chloroquine and COVID-19. Antiviral Res. 2020 May;177:104762. doi: 10.1016/j.antiviral.2020.104762.
21. Expert consensus on chloroquine phosphate for the treatment of novel coronavirus pneumonia. Chinese journal of tuberculosis and respiratory diseases. 2020 Mar 12;43(3):185-8.
22. Yao X et al. In vitro antiviral activity and projection of optimized dosing design of hydroxychloroquine for the treatment of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Clin Infect Dis. 2020 Mar 9. doi: 10.1093/cid/ciaa237.
23. Devaux CA et al. New insights on the antiviral effects of chloroquine against coronavirus: What to expect for COVID-19? Int J Antimicrob Agents. 2020 Mar 12:105938. doi: 10.1016/j.ijantimicag.2020.105938.
Frontline health care workers are facing escalating challenges with rapidly spreading coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection.1 Hospitalists will often deal with various manifestations of acute cardiac injury, controversial withholding of ACE inhibitors (ACEI) or angiotensin receptor blockers (ARBs), arrhythmic toxicities from such drug therapies as hydroxychloroquine.
Presentation and cardiac risks from COVID-19
Patients with COVID-19 often have presented with noncardiac symptoms, usually a febrile illness associated with cough or shortness of breath. Recent reports from Italy and New York have suggested patients also can present with isolated cardiac involvement without any other symptoms that can portend a grim prognosis.2 Cardiac effects include myocarditis, acute coronary syndrome, malignant arrhythmias ultimately cardiogenic shock and cardiac arrest.3
The mortality rate correlates with older age, preexisting health conditions, and availability of medical resources. A recent meta-analysis including 53,000 COVID-19 patients found the most common comorbidities were hypertension (19%), diabetes (8 %) and cardiovascular disease (CVD) (3%).4 Half of the cases died from respiratory failure and one-third have died from concomitant respiratory and heart failure. Acute heart failure alone accounted for about 7% of cases.5
Overall mortality rate can be better understood with the largest case series to-date of COVID-19 in mainland China published by the Chinese Center for Disease Control and Prevention. The overall case-fatality rate was 2.3% (1,023 deaths among 44,672 confirmed cases), but the mortality reached 10.5% in patients with underlying CVD.6
Acute cardiac injuries in COVID-19
Acute cardiac injury (ACI) is defined as troponin elevation above the 99th percentile of the upper reference limit.7 A practical description of ACI in COVID-19 patients should also include broader definition with new abnormalities in ECG since not all patients with acute cardiac effects have developed troponin elevation.3 More recent reports showed up to 28% of hospitalized patients had a myocardial injury.3
It is not uncommon to see a patient with COVID-19 myocarditis as a mimicker of acute ST-elevation myocardial infarction (STEMI). The mechanism of ACI is unknown, though several hypotheses have been proposed based on case series and retrospective reviews. These include direct viral invasion into myocardial cells leading to myocarditis, oxygen demand-supply mismatch, acute coronary syndrome from plaque rupture, stress, or cytokine-mediated cardiomyopathy.3 The exact incidence of true MI from occlusive coronary disease in the COVID-19 population is yet unknown.
In some cases, troponin elevation may be a late manifestation of COVID-19. As coronavirus disease progressed slowly, a rapid rise of troponin was noted when patients developed acute respiratory failure after 10 days of illness. Among nonsurvivors, a steady rise in troponin was observed from day 4 through day 22.8
ACI is associated with ICU admission and mortality. Both troponin and BNP levels increased significantly during the course of hospitalization in those who ultimately died, but no such changes were evident in survivors.3 ACI was higher in nonsurvivors (59%) than in survivors (1%).8 ACI was higher in ICU patients (22%), compared with non-ICU patients (2%).9 Patients with CVD were more likely to exhibit elevation of troponin levels (54%), compared with patients without CVD (13%).3
Higher troponin levels and the presence of CVD are directly proportional to severe disease and death. Patients with elevated troponin developed more frequent complications including acute respiratory distress syndrome, malignant arrhythmias including ventricular tachycardia/ventricular fibrillation, acute coagulopathy, and acute kidney injury.3,8 Death was markedly higher in patients with elevated troponin, compared with normal levels: 60% versus 9%. Only 8% with no CVD and normal troponin died, whereas 69% of people with underlying CVD and elevated troponin died.3
The median duration from illness onset to death was 23 (8-41) days in the group with elevated troponin. Patients with CVD and escalation of troponin levels had the shortest survival of 1-5 days. The dynamic rise of cardiac biomarkers and increased incidence of malignant arrhythmias during the course of illness shows that myocardial injury played a greater role in the fatal outcome of COVID-19 than the presence of preexisting CVD itself.3
Management of acute cardiac issues in COVID-19
There are no established therapeutic options with randomized, clinical trials specific to the management of COVID-19 patients at this point. Standard supportive care and individualized treatment plan based on existing guidelines is probably the best approach. Disposition of cases and cardiac testing should be tailored, based on local protocols, availability of resources and expertise.10
There seems to be a consensus that baseline troponin levels should be obtained in all admitted patients. Repeat troponin levels can be obtained based on the severity of illness, for example, daily troponin checks are reasonable in ICU patients and every-other-day troponin testing may be reasonable in general inpatients. Routine troponin testing in minimally symptomatic or asymptomatic patients will likely not change any outcome.3,11,12
Daily ECG is reasonable in severe COVID-19. However, routine transthoracic ECGs are not reasonable, unless it will change further treatment plans. Transthoracic electrocardiograms (TTE) are reasonable in patients with significant troponin elevation, a decline in central venous oxygen saturation, new heart failure, shock, new persistent arrhythmias, or significant new ECG changes.12
Limited TTEs for a focused exam enough to answer the clinical question should be ordered to minimize the risk of viral exposure to the sonographers. Transesophageal echo will rarely be needed, and its use should be minimized to reduce direct contact exposure and because of anesthesia risks.13 Routine stress testing should not be ordered in active COVID-19 and should be deferred for outpatient evaluation, if clinically indicated, once the patient recovers from the infection.12
Myocarditis and pericarditis are potential manifestations of acute cardiac injury. Recent case reports have suggested evidence of myocarditis confirmed with cardiac MRI.11 Because of high fatality rates with cardiac involvement and no proven therapies yet, the role of routine advanced cardiac imaging such as cardiac CT, cardiac MRI, or cardiac biopsy is unclear.
Myocarditis can likely be caused either by the virus itself, or the body’s immune and inflammatory response (cytokine storm) to the virus.2,3 The use of anti-inflammatory drugs like colchicine, ibuprofen, steroids, or statins is not yet established.10,12 Drugs like remdesivir, lopinavir-ritonavir, hydroxychloroquine, chloroquine, and anti-interleukin-6 agents have been invariably used with some anecdotal success and randomized clinical trials for some of these drugs are presently undergoing.
Physicians may encounter situations to call a STEMI code or not in COVID-19 patients.2,11 Patients may have substernal pain, diffuse or regional ST elevations in ECG and reduced left ventricular dysfunction with regional wall motion abnormalities on ECG. These findings may be casued by myocarditis, acute type 1 MI, or stress-induced cardiomyopathy. Clinicians should make their judgment based on the overall pretest probability for type 1 MI, incorporating risk factor profiles and the presence of typical symptoms.
Treatment practice for questionable STEMI cases will likely vary across the country as we are learning more about the virus. Cath lab operators are at risk for COVID-19 infection through direct contact with patients. Few cardiologists were admitted after COVID-19 infections in the ICU at a New York hospital after they were involved in a acute MI case in a cath lab.14 Based on the Chinese experience, some have suggested the idea of lytic therapy first with follow-up cardiac CT to assess the recanalization of perfusion status, but at this point, this strategy remains controversial in the United States. In addition, if the patient has myocarditis instead, there will be a risk for pericardial effusion and hemorrhagic complications with lytic therapy.
Case examples
1. A 70-year-old male presents with fevers, chest pain, cough, shortness of breath. He has a history of metabolic syndrome and 30 pack-years of smoking. His ECG showed 1.5 mm ST elevation in inferior leads with reciprocal ST depressions in lateral leads, and his initial troponin is 2. Echocardiogram showed reduced left ventricle ejection fraction of 32% and inferior wall hypokinesis. He is suspected COVID-19 and his PCR result is pending. How would you manage this patient?
This patient presented with febrile illness and, but he had a very high pretest probability for obstructive coronary artery disease based on his age, male sex, and multiple risk factors. He may have a viral syndrome and it is a stressful situation for him. This may have precipitated plaque rupture causing acute MI.
Activating the STEMI pathway for emergent left heart catheterization is likely appropriate in this case. Coronary angiogram in this patient showed a 100% occluded mid-right coronary artery with a fresh thrombus. Delaying cardiac cath would have possibly led to malignant arrhythmias and death from ischemic injury. We need to be cognizant patients can die from non–COVID-related emergencies also.
2. An 18-year-old healthy male presents with cough and chest pain and has bilateral lung infiltrates. ECG showed anterolateral 2 mm ST elevations and no reciprocal ST changes. Stat TTE showed anterior wall hypokinesis and LV function 30% and his initial troponin are 0.6 (normal is < .05). The nasopharyngeal swab is sent out and his COVID result is pending. How would you manage this patient?
A young patient with no cardiovascular risk factors has a very low pretest probability for obstructive coronary disease and the likelihood of having a true ischemic MI is low even though he has significant new ST elevations. Especially with presumed COVID-19 and risk of virus exposure to the cath lab personnel, it will be prudent to manage this patient with supportive therapy including beta-blockers, ACEIs, etc. Repeat echo in 7 days before discharge showed improved LVEF 45%.
Controversy on ACEI/ARB
The SARS-CoV-2 virus enters via cell-entry receptor namely angiotensin-converting enzyme 2 (ACE2). SARS-CoV-2 is thought to have a higher affinity for ACE2 than other SARS-viruses.15
ACE2 is expressed in the heart, lungs, vasculature, and kidneys. ACEI and ARBs in animal models increase the expression of ACE2,16 though this has not been confirmed in human studies. This has led to the hypothesis that ACEI and ARBs might worsen myocarditis or precipitate the acute coronary syndrome. It has also been hypothesized that the upregulation of ACE2 is therapeutic in COVID-19 and that ARBs might be protective during infection.17
The increased ACE2 expression induced by ACEI or ARB would aggravate lung injury of patients with COVID-19. However, a previous study showed a beneficial effect of ACEI/ARB in patients admitted with viral pneumonia, as it significantly reduced the pulmonary inflammatory response and cytokine release caused by virus infection.18
Therefore, this remains an area of investigation and it is unclear how these medications affect patients with COVID-19. In a recent review, with a limited number of patients, the mortality of those treated with or without the use of ACEI/ARB did not show a significant difference in the outcome.3
Both American and European cardiology societies recommend against routine discontinuation of ACEI and ARBs in patients with COVID-19 because of risks of uncontrolled hypertension and heart failure, stroke, or heart attack.19 However, it will be reasonable to hold off in inpatients in cases of acute kidney injury, hypotension, shock, etc.12
Cardiac concern about hydroxychloroquine and chloroquine
Hydroxychloroquine (HCQ) is an antimalarial drug shown to have in vitro (but not yet in vivo) activity against diverse RNA viruses, including SARS-CoV-1.20 An expert consensus group from China suggests that chloroquine improved lung imaging and shortened disease course.21 HCQ was found to be more potent than chloroquine in inhibiting SARS-CoV-2 in vitro.22
Based on limited in vitro and anecdotal clinical data from other countries, the U.S. Food and Drug Administration recently authorized emergency use of chloroquine and HCQ in hopes of slowing the progression of the disease when a clinical trial is not available, or participation is not feasible for use of these drugs in hospitalized patients. However, with no clear benefit, there is a concern for possible risks with cardiac toxicity.
HCQ is known to cause cardiomyopathy in a dose-dependent manner over several years. Given the anticipated short duration in COVID-19, it is not an expected risk. QT-segment prolongation and torsades de pointes, especially if administered in combination with azithromycin, is possible even in short term use.23
Given above, frequent ECG monitoring is indicated for patients being treated with chloroquine or HCQ. All other QT-prolonging drugs should be discontinued. Continuous telemetry monitoring while under treatment is reasonable. HCQ should not be started if baseline QTc is > 500 msec and it should be stopped if the patient develops ventricular arrhythmias.12
Dr. Subedi is a noninvasive cardiologist for Wellspan Health System in Franklin and Cumberland counties in south central Pennsylvania. He is a clinical assistant professor of medicine at Penn State College of Medicine, Hershey, Pa. He is an active member of the critical care committee at Wellspan Chambersburg (Pa.) Hospital. Dr. Tirupathi is the medical director of Keystone Infectious Diseases/HIV in Chambersburg and currently chair of infection prevention at Wellspan Chambersburg and Waynesboro Hospitals, all in Pennsylvania. He also is the lead physician for antibiotic stewardship at these hospitals. Dr. Areti is currently working as a hospitalist at Wellspan Chambersburg Hospital and is a member of the Wellspan pharmacy and therapeutics committee. Dr. Palabindala is hospital medicine division chief at the University of Mississippi Medical Center, Jackson.
Key points
- Acute cardiac injury or myocarditis is common among patients infected with COVID-19. Often, COVID myocarditis can mimic acute MI or stress cardiomyopathy and will present diagnostic and therapeutic challenges. On the other hand, isolated cardiac involvement can occur, even without symptoms and signs of interstitial pneumonia.
- A most important indicator of worse prediction is the degree of myocardial injury, regardless of preexisting conditions or underlying cardiovascular disease.
- Early recognition of cardiac involvement will be helpful in targeting more aggressive supportive therapies. Commonly available clinical tools like bloodwork, ECG, or echocardiogram should be adequate to diagnose carditis in most cases.
- Advanced cardiac imaging tests or cardiac biopsy are of uncertain benefits. Meticulous evaluation is needed for possible ischemic changes before taking the patient to the cardiac cath lab in order to reduce unnecessary virus exposure to the operators.
- ACEI/ARB should be continued in most cases in COVID patients based on cardiology societies’ recommendations.
- With the widespread use of antimalarial drugs like chloroquine or hydroxychloroquine, frequent ECG and continuous telemetry monitoring is reasonable to rule out ventricular arrhythmias like torsades.
- There is no specific treatment to date for acute cardiac injuries. Since there are no specific guidelines and information about the virus is rapidly changing, it will be prudent to follow common-sense approaches outlined by institutions like the Brigham and Women’s Hospital COVID-19 Critical Care clinical guidelines, which incorporate new clinical information on a daily basis ().
References
1. Rothan HA and Byrareddy SN. The epidemiology and pathogenesis of coronavirus disease (COVID-19) outbreak. J Autoimmun. 2020 May;109:102433. doi: 10.1016/j.jaut.2020.102433.
2. Kolata G. A heart attack? No, it was the coronavirus. New York Times 2020 Mar 27.
3. Guo T et al. Cardiovascular implications of fatal outcomes of patients with coronavirus disease 2019 (COVID-19). JAMA Cardiol. 2020 Mar 27. doi: 10.1001/jamacardio.2020.1017.
4. Zhao X et al. Incidence, clinical characteristics and prognostic factor of patients with COVID-19: a systematic review and meta-analysis. MedRxIV. 2020 Mar 20. doi: 10.1101/2020.03.17.20037572.
5. Ruan Q et al. Clinical predictors of mortality due to COVID-19 based on an analysis of data of 150 patients from Wuhan, China. Intensive Care Med. 2020 Mar 3. doi: 10.1007/s00134-020-05991-x.
6. Wu Z and McGoogan JM. Characteristics of and important lessons from the coronavirus disease 2019 (COVID-19) outbreak in China: Summary of a report of 72,314 cases from the Chinese Center for Disease Control and Prevention. JAMA. 2020 Feb 24. doi: 10.1001/jama.2020.2648.
7. Thygesen K et al. Fourth universal definition of myocardial infarction (2018). J Am Coll Cardiol. 2018 Oct;72:2231-64.
8. Zhou F et al. Clinical course and risk factors for mortality of adult inpatients with COVID-19 in Wuhan, China: a retrospective cohort study. Lancet. 2020 Mar 28;395(10229):1054-62.
9. Wang D et al. Clinical characteristics of 138 hospitalized patients with 2019 novel coronavirus-infected pneumonia in Wuhan, China. JAMA. 2020 Feb 7. doi: 10.1001/jama.2020.1585.
10. CDC: Therapeutic options for patients with COVID-19. Updated April 13, 2020.
11. Inciardi RM et al. Cardiac involvement in a patient with coronavirus disease 2019 (COVID-19). JAMA Cardiol. 2020 Mar 27. doi: 10.1001/jamacardio.2020.1096.
12. Brigham and Women’s Hospital COVID-19 Critical Care Clinical Guidelines.
13. American Society of Echocardiography Statement on COVID-19. 2020 Apr 1.
14. A cardiologist in Brooklyn infected with COVID-19. @jigneshpatelMD. 2020 Mar 20.
15. Paules CI et al. Coronavirus infections – more than just the common cold. JAMA. 2020 Jan 23. doi: 10.1001/jama.2020.0757.
16. Zheng YY et al. COVID-19 and the cardiovascular system. Nat Rev Cardiol. 2020 May;17(5):259-60.
17. Gurwitz D. Angiotensin receptor blockers as tentative SARS-CoV-2 therapeutics. Drug Dev Res. 2020 Mar 4. doi: 10.1002/ddr.21656.
18. Henry C et al. Impact of angiotensin-converting enzyme inhibitors and statins on viral pneumonia. Proc (Bayl Univ Med Cent). 2018 Oct 26;31(4):419-23.
19. HFSA/ACC/AHA statement addresses concerns re: Using RAAS antagonists in COVID-19. 2020 Mar 17.
20. Touret F and de Lamballerie X. Of chloroquine and COVID-19. Antiviral Res. 2020 May;177:104762. doi: 10.1016/j.antiviral.2020.104762.
21. Expert consensus on chloroquine phosphate for the treatment of novel coronavirus pneumonia. Chinese journal of tuberculosis and respiratory diseases. 2020 Mar 12;43(3):185-8.
22. Yao X et al. In vitro antiviral activity and projection of optimized dosing design of hydroxychloroquine for the treatment of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Clin Infect Dis. 2020 Mar 9. doi: 10.1093/cid/ciaa237.
23. Devaux CA et al. New insights on the antiviral effects of chloroquine against coronavirus: What to expect for COVID-19? Int J Antimicrob Agents. 2020 Mar 12:105938. doi: 10.1016/j.ijantimicag.2020.105938.