The pandemic of coronavirus disease 2019 (COVID-19) caused by the novel severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) presents a challenge to all doctors worldwide for detection of disease, differentiating it from those with similar presenting symptoms.
The initial evaluation of the patient with suspected Covid-19 disease is usually performed by general practitioners; who, unfortunately; as their knowledge about the on growing changing faces of this pandemic disease presenting symptoms and evolving new information are not continually updated, miss the diagnosis of some cases, with fatal consequences to these cases.
This simplified review is intended to provide those doctors basic, quick but essential information that will enable them to better at detecting and diagnosing cases. The current medical literature that is applicable to this simplified review was identified by a computerized search in WHO and the CDC, websites and in most of the reputed English language printed medical journals and was evaluated using standardized methods till the time of publication.
COVID-19, SARS-CoV-2, Coronavirus, pandemic, PCR, CT, Vaccine
SARS-CoV-2, a single-stranded RNA-enveloped virus having structural spike (S) protein that binds to the viral proteins angiotensin-converting enzyme 2 (ACE2) receptor present on cells. Following receptor binding, the virus these enter cells. Once inside the cell, viral polyproteins are synthesized [1].
• Incubation period: 2-14 days [2,3].
• Symptoms and signs vary: [2,3].
*General: Fever, fatigue, muscle or body aches, headache, chills.
*Respiratory: Cough, sputum production, shortness of breath, sore throat, congestion or runny nose, rarely hemoptysis.
*Gastrointestinal: Anorexia, nausea, vomiting, new loss of taste or smell (anosmia or ageusia), diarrhea, abdominal pain.
*Ocular: Conjunctival hyperemia, chemosis, epiphora or increased secretions.
*Asymptomatic.
Some patients with COVID-19 described as exhibiting oxygen levels incompatible with life without dyspnea. The pairing-dubbed happy hypoxia, but more precisely termed silent hypoxemia [4].
Some proposed explanations:
• The ventilatory response to hypoxia is decreased by 50% in people older than 65 years and in diabetics. Given that dyspnea response to hypoxia parallels the ventilatory response, it is likely that older or diabetic COVID-19 patients are more prone to silent hypoxemia [5-7].
• Chemical drive to breathe (in response to hypercapnia and hypoxia) exhibits as much as 300% to 600% variation between one subject and the next [8].
• Pulse oximetry is less reliable in critically ill patients than in healthy volunteers [9].
• Fever, prominent with COVID-19, causes the curve to shift to the right; any given PaO2 will be associated with a lower SaO2. These shifts produce substantial desaturations without change in chemoreceptor stimulation (because carotid bodies respond only to PaO2, and not SaO2)-another factor contributing to silent hypoxemia [10-12].
Gattinoni, et al. [13], have mentioned that the COVID-19 pneumonia are two types, L and H.
The Type L is characterized by [13]:
*Low elastance with normal compliance. Combination not seen in other acute respiratory distress syndrome (ARDS).
*Low ventilation to perfusion ratio.
*Low lung weight detected by computerized tomography of chest (CT chest).
*Low lung recruit ability with very low non-aerated lung tissue.
The Type H is characterized by [13]:
*High elastance due to increase oedema.
*High right to left shunt.
*High lung weight detected by computerized tomography of chest (CT chest).
*High lung recruit ability with increased amount of non-aerated lung tissue.
N.B: Those patients have severer ARDS criteria [13].
Secondary haemophagocytic lymphohistiocytosis (sHLH) is an underecognised, hyperinflammatory syndrome characterized by a fulminant and fatal hypercytokinaemia with multiorgan failure [14].
• In adults, sHLH is most commonly triggered by viral infections [14].
• Cardinal features of sHLH include [15].
*unremitting fever,
*cytopenias,
*hyperferritinaemia,
*pulmonary involvement (including ARDS)
The chest film is insensitive early in the disease; however, it can be useful in the follow-up of the disease [16].
Initially: Bilateral, multilobar, ground glass opacities (GGO), with a peripheral or posterior distribution, mainly in lower lobes less commonly in middle lobe [17].
Box 1: GGO: Is a radiological finding in computed tomography (CT) consisting of a hazy opacity that does not obscure the underlying bronchial structures or pulmonary vessels [18].
• Other CT findings: Consolidation, crazy paving, vascular dilation, traction bronchiectasis, pleural thickening, subpleural bands and architectural distortion [17,19].
• Uncommon findings include: Pleural effusion, pericardial effusion, lymphadenopathy, cavitation, reversed CT halo sign and pneumothorax [17].
Box 2: Crazy paving: Is a radiological finding in computed tomography (CT) consisting of a thickened inter and intralobular lines with GGO [20].
Box 3: Reversed CT halo sign: Is a radiological finding in computed tomography (CT) of a rounded area of GGO surrounded by a complete or almost complete ring of consolidation [18].
• The severity of lung involvement on CT correlated with the disease severity [19].
• The severity of CT is evaluated by visual assessment and this is the easiest method [19].
• Another method is by scoring percentage involvement of each of the five lobes with a total score calculated by the sum of individual lobar score divided by the number of lobes [19].
Serial chest CT scans could be used as a monitoring modality to help clinician better understanding the course of the disease. There are few reports about post discharge follow- up chest CT findings. However, one study evidenced peak of pulmonary involvement 3-4 weeks after onset of disease with predominant GGO and consolidation. Pulmonary lesions still existed on discharge and the pulmonary lesions continued decreasing. Around 2 months after symptom onset, subpleural parenchymal bands were the predominant feature, and complete radiological resolution started in this period [21].
Author's comment: As the GGO increases during the first 3-4 weeks it might be misinterpreted as deterioration of the case , thus if clinically the patient is improving the radiological findings should not affect decision making of discharge or stoppage of medications.
There are two types of tests:
• Diagnostic: To show active infection, it is either molecular test (RT-PCR) that detects the virus's genetic material [22], or antigen tests that detect specific proteins on the surface of the virus [23].
• Antibody test: Detect antibodies made by immune system in response to the virus [24].
If patient has strong symptoms of COVID-19, it is safest to self-isolate, even if the swab test is negative [25].
A positive result of PCR or IgM assay in patients who displayed no clinical manifestation should not be considered indicative of being infectious [26].
Currently there is neither established treatment regimen for COVID-19 nor established prevention for SARS-CoV-2 [27].
Azithromycin given alone early in the course of COVID-19 infection showed encouraging effects [28].
The use of such medication in treating COVID-19 cases appeared in international guidelines alone or in combination with azithromycin. However, although it is a well tolerated medication it can cause corrected QT interval and cardiac arrhythmias which is greater if combined with azithromycin. Thus close monitoring by clinicians is recommended [29].
Dexamethasone 6 mg per day for up to 10 days reduces 28-day mortality in COVID-19 patients receiving invasive mechanical ventilation by one third, and by one fifth in patients receiving oxygen without invasive mechanical ventilation. Similarly, benefit was clearer in patients treated more than 7 days after treatment onset, when inflammatory lung damage is likely to have been more common [30].
• An intravenous drug that is metabolized intracellularly inhibiting the virus RNA polymerase thus inhibits virus replication [31].
• To be used in hospitalized patients with COVID-19 who require supplemental oxygen but who are not on high-flow oxygen, non-invasive ventilation, mechanical ventilation, or extracorporeal membrane oxygenation (ECMO) [31,32].
• The current dose under investigation is a single 200-mg loading dose, followed by 100-mg daily infusion for 9 days [31,32].
• This intravenous drug that is metabolized intracellularly inhibiting the virus RNA polymerase thus inhibit virus replication [33].
• A loading dose is recommended (2400 mg to 3000 mg every 12 hours for 2 doses) followed by a maintenance dose (1200 mg to 1800 mg every 12 hours). Limited clinical experience has been reported supporting the use of favipiravir for COVID-19 [34].
• Lopinavir/Ritonavir (Kaletra), an oral combination agent for treating HIV [35], that inhibits the "3-chymotrypsin like protease" which is responsible for breaking the synthesized viral polypeptides to non-structural proteins in host cell [32].
• The most commonly used and studied lopinavir/ritonavir dosing regimen for COVID-19 treatment is 400 mg/100 mg twice daily for up to 14 days [36]. They can be used in pregnancy [37].
• Tocilizumab, a monoclonal antibody IL-6 receptor antagonist, is used to treat RA [38]. A report in Covid-19 cases at a dose of 400 mg IV or 8 mg/kg for 1-2 doses., and a second dose 8-12 hours after first dose if inadequate response, was associated with clinical improvement [39].
• Zinc has the ability to enhance innate and adaptive immunity in the course of viral infection [40].
• Reported to inhibit SARS-CoV-2 RNA-dependent RNA polymerase (RdRp) thus stopping the virus replication in infected cells [40].
• Chloroquine enhances zinc uptake by lysosomes [40].
• Daily dosage: 15-30 mg [40].
• Vitamin D has a protective effect against respiratory tract infection [41].
• Some studies showed correlation between vitamin D level and COVID-19 cases and outcome; however, other studies lacked this conclusion [41].
• Lactoferin is a common nutritional support with laboratory evidence as an antiviral and immune-modulator [42].
• Studies showed possible reduced severity and duration of infection with preventive effect in contacts [42].
• Plasma collected from recovered asymptomatic proved COVID-19 cases, whose test turned negative and their blood contains antibodies and is compatible with the recipient and is negative for HIV [43].
• Used in deteriorating cases. Proved to improve clinical symptoms, increase survival rate, decrease hospital stay, reduce lung lesions in CT chest, and ameliorate routine laboratory criteria and pulmonary function and increase neutralizing antibody titers and cause disappearance of SARS-Cov-2 RNA [44].
• In the absence of effective targeted therapies for COVID-19, optimization of supportive care is essential [45].
• Awake prone positioning appears to be safe and may slow the respiratory deterioration in select patients with COVID-19, who require oxygen supplementation or NIV/CPAP. This in turn may reduce demand for invasive mechanical ventilation [45].
• However, further studies are required to assess the degree to which awake prone positioning may be beneficial [45].
• HFNO is a commonly used therapy for patients with acute hypoxaemic respiratory failure [46].
• For patients considered unsuitable for tracheal intubation but who are deteriorating despite standard nasal oxygen or facemask oxygen, HFNO and CPAP are the only remaining options in active management and should be considered [46].
• Unfortunately, as the potential for aerosolisation of virus particles with increased risk that healthcare workers could become infected with coronavirus, this had limited the use of HFNO in many guidelines [46].
• As several therapeutic strategies in managing COVD-19 have proven to be partially ineffective, even show many side effects. Thus the idea of adopting any adjuvant therapies that may contribute to a better outcome has pushed some physicians to recommend ECMO for those with severe ARDS from COVID-19 infection. ECMO therapy and COVID-19 itself are associated with synergistic changes in hematological and inflammatory status of the patients, thus the efficacy of ECMO is largely dependent on centers' experience with such therapies [47].
There is no vaccine against COVID-19 at this time. Over 100 candidate vaccines are in clinical trials or preclinical evaluation [48].
Not applicable.
Not applicable.
The author declares no competing interest.