This article contains information about Novel Coronavirus (COVID-19) – which in March 2020 was declared a pandemic by the WHO. Information and public health advice about the virus (SARS CoV-2) and the illness it causes (COVID-19) is changing rapidly. It is recommended that you seek the advice of your local government health authority for the latest information.
This article will be updated as the pandemic progresses. Last updated on 14th July 2020.
Coronaviruses are a family of viruses that cause respiratory infections in humans. Most coronaviruses cause a mild illness – for example – coronaviruses are responsible for about 1/4 of cases of the common cold.
Significant outbreaks of deadly coronaviruses include:
- Middle East Respiratory Syndrome (MERS-CoV) – which caused various outbreaks in the 2010s. MERS had a mortality rate of about 35%
- Severe Acute Respiratory Syndrome (SARS-CoV) – which caused an outbreak in China and Hong Kong in 2002-03. SARS had a mortality rate of about 10%
- Novel coronavirus (SARS-CoV-2) which causes the illness known as COVID-19. Current estimates put the mortality rate at around 1-2%
- The virus itself is officially called SARS CoV-2
- The illness it causes is known as COVID-19
- COrona VIrus Disease 2019
- The term COVID-19 is often used interchangeably for both purposes
- The term “novel” refers to the fact that it is a new strain – not previously identified in humans. Novel viruses often carry a worse prognosis, because the immune system has very little defence against these viruses because it has never encountered similar viruses
Novel coronavirus was first identified in the city of Wuhan in Hubei, China, around the end of 2019. It is believed to have originated in the live animal market in Wuhan – probably in bats (not as first suggested the pangolin). It was discovered after there were a cluster of unusual pneumonia cases within the city.
It mainly causes a respiratory disease.
By January 2020 it was confirmed to be spreading from person to person.
In March 2020 it was declared a pandemic by the WHO. Around the world in March and April 2020, countries imposed tight restrictions on movement of people, commonly referred to as “social distancing” in an attempt to reduce the spread of the disease.
There is currently no vaccine available for the virus, and no specifically recommended medications to treat the infection. Treatment is supportive. Mulitple agents are currently undergoing testing as part of trials to assess their efficacy for the treatment of coronavirus, but as of 14th July 2020, official Australian guidelines do not suggest use of any agents outside of clinical trials.
Stringent hygiene such as regular hand-washing and avoiding touching your face, and use of face masks can reduce the risk of infection. Public health measures to limit person to person contact may help to reduce the rate of spread amongst the population.
The virus seems to disproportionally affect older patients and those with pre-existing health conditions. There are very few cases identified in children.
The current outbreak is expected to last at least several months.
There are over 100 vaccines in development, with, in the best case scenario, the earliest available vaccine likely to be by October 2020. The efficacy and duration of protection afforded by a future vaccine is yet unknown.
Early studies suggest that antibody levels to SARS-CoV-2 decline significantly over a period of months after infection. It is unclear if this also means that immunity declines over time.
- Can be very variable
- An unknown proportion (estimates vary from 1 – 30%) are asymptomatic
- The illness peaks between days 9-13
- Most patients who become sick enough to require hospital admission have presented by day 5
- Typical presentations involve flu-like symptoms such as:
- Fever – 88%
- Cough – 67%
- Fatigue – 38%
- Shortness of breath – 18%
- Muscle aches – 15%
- Headache – 14%
- Sore throat – 14%
- Coryza – 5%
- Nausea / vomiting – 5%
- Diarrhoea – 4%
- Rarely there may also be:
- Encephalitis – including agitation, confusion, altered consciousness
- 80% of cases are mild and can be treated at home
- 20% of cases require hospital admission – typically for treatment of shortness of breath secondary to pneumonia or ARDS
- 5% of cases require ICU admission – typically for ARDS, respiratory failure, sepsis and multi-organ failure
- The median time from onset to ICU admission is 10 days
- Average time from symptom onset to death is 2-8 weeks
Some Emergency Medicine and ICU specialists in hard-hit countries (particularly the USA) are starting to talk in-terms of three types of presentation:
- Mild flu-like illness
- These patients do not have respiratory distress, and typically present with mild flu-like symptoms
- These patients can be safely managed at home
- “Happy hypoxic”
- These patients present with low O2 sats (typically in the 70-80% range), but otherwise appear well
- They typically do NOT have tachycardia or increased respiratory rate or increased work of breathing. Their blood-pressure is usually normal
- The patients should be admitted to hospital for basic oxygen therapy
- Advising these patients to sit up (out of bed in a chair, or in bed) or to lie ‘prone’ (lie on their front) can help to improve the hypoxia
- Despite the very low O2 saturations, it doesn’t appear to be beneficial to intubate or ventilate these patients
- More severe patients may be considered for NIV (CPAP)
- Severely unwell patient
- These patients often have extremely low oxygen saturations – numbers that may initially seem incompatible with life – such as 25-40%
- Their other vital signs may also suggest a severely unwell patient – such as tachycardia and hypotension
- They will require intubation and ventilation and ICU admission
- CPAP may be used as a temporary measure to assist with pre-oxygenation before intubation
The Ro number refers to on average how many people and affected person will infect.
- A disease with an Ro on <1 will typically slowly decline in number of cases, and eventually disappear
- A disease with an Ro number of >1 can propagate widely throughout a population
- The Ro of coronavirus is estimated to be 1.5 – 3.4
- Ro of influenza is about 1.3
For a really interesting interactive simulation on infectivity, and how it can be altered using social isolation methods, try this simulation from The Washington Post.
- The average incubation period is 5 days
- The typical range is between 2-14 days
- There is a single confirmed case after 27 days incubation
- 75% show symptoms before 7 days
- <1% show symptoms after 14 days
- It is believed that the virus can be shed during the asymptomatic incubation period, or in individuals who are completely asymptomatic
- Transmission occurs from person to person by droplet transmission, mucous membranes, faecal-oral route and via fomites (contaminated inanimate objects – such as door handles and other surfaces)
- It is possible that airborne transmission can also occurr but this is not yet proven
- The virus can survive for up to 4 days on surfaces (duration of survival depends on the surface – plastic and wood surfaces have longer duration of survival than metal)
- Respiratory droplets (>5um) are the major form of transmission
- These are produces by coughing, sneezing and breathing
- Respiratory droplets typically stay in the air for <17 minutes, and only travel about 1m. Sneezing and aerosolising procedures can transmit droplets further than 1m.
- Respiratory droplets land on inanimate objects – such as surfaces, clothes etc. These are known as fomites.
- Spread occurs when an uninfected individual touches a “fomite” and then subsequently transfers the droplets to a mucous membrane – e.g. the eye, mouth or nose.
- “Aerosolising” procedures are medical procedures thought to increase the spread of smaller aerosol droplets (<5um). These include the use of nebulizers, bag-valve-mask ventilation, and non-invasive ventilation (e.g. CPAP).
- It is not yet proven that this can lead to transmission of SARS-CoV2
- Coronaviruses have transmembrane glycoproteins – known as “spike proteins” on their surface, that attach to the target cells
- It appears that SARS-CoV2 attaches to Angiotensin converting enzyme 2 (ACE2) receptors
- ACE2 is expressed in the lungs and upper respiratory tract cells, and to a lesser extent, in the small intestine
- Once inside the cell, viral RNA replication occurs
- In patients who develop severe life-threatening illness it is believed that an extreme immune response (Sometimes referred to as a “cytokine storm“) may be responsible for many of the effects, rather than a direct effect of the virus itself
There has been some speculation as to the role of ACE-inhibitors and angiotensin receptor blockers in the treatment of COVID-19. At the moment it remains just that – speculation. Initially there were some fears that these medications were associated with a worse prognosis, but more recently, there are suggestions that they may improve prognosis. Know one really knows at present, but there is no official advice to cease these medications in patients suffering from or at high risk of COVID-19.
Diagnosis is typically confirmed by a PCR swab of the nasopharynx and oropharynx. Some jurisdictions recommend using the same swab in both locations. Depending on the lab, PCR testing can take anywhere from 6 hours to several days. Check your local testing guidelines. Initial restrictions to testing due to lack of capacity have mostly now been relaxed and in most countries and jurisdictions testing is available to anybody with URTI symptoms.
- Between 60-85% senstivie
- i.e. between 15-40% of truly infected patients will be false negatives
Other testing methods
- Viral culture is not recommended for safety of lab technicians
- A serology (blood / serum) test is being developed
- This can detect the presence of antibodies (Ig) to coronavirus
- This test typically becomes positive within several weeks of contracting the infection and likely remains positive for months or even years after the infection
- In theory, these test can give a result in 15 minutes
- Initial test kits have proved unreliable, and as of July 2020, this testing is not yet widely available
- When this test does become widely available it may have a role in population screening
- It will be able to help us determine how many cases have truly occurred
- It may allow those whom have had the virus to be allowed to move more freely
Consider COVID-19 in any patient with:
- Cough, OR
- Recent to a high risk area (either overseas or to a location known to have a high number of cases) within 14 days on onset of symptoms, OR
- Contact with a confirmed case of COVID-19
- In many jurisdictions the contact requirement is no longer required and those wit any respiratory symptoms are being tested
Contact is defined as:
- Living in the same household as a person with confirmed infection
- Direct contact with someone who has a confirmed infection, or their bodily fluids
- Face-to-face contact with a person with a confirmed infection for any length of time
- Being within 2 metres of a person with a confirmed infection for more than 15 minutes
If the above conditions are met, then consider nasopharyngeal PCR swab:
- Nasophayrngeal swab for coronavirus PCR testing
- Highly sensitive and specific
- Typically takes 6-72 hours for a result depending on test centre
- Latest advise is to take x2 samples with a single swab – nasopharyngeal (via nose) and throat
Healthcare workers: recommendations may be different for healthcare workers. In Australia it is recommended all healthcare workers with fever and respiratory symptoms are screened, even if they don’t meet the contact requirements.
- FBC – lymphocytopaenia
- About 45% of patients
- 85% of critically ill patients
- WCC can be normal, high or low
- Coagulation studies
- Usually normal except in DIC (a life-threatening complication of SIRS)
- U+Es – usually normal
- ALT / AST / bilirubin – may be increased
- 40-75% of cases
- >90% of ICU cases
- Might be useful as a marker of severity
- Inflammatory markers
- CRP – increased
- ESR – increased
- Albumin – decreased
- Ferritin – increased
- Lumbar puncture – consider if signs of meningitis
- Troponin and D-dimer are often increased
The findings in COVID-19 are no different to other causes of a viral pneumonia – there are no specific COVID-19 imaging changes. The typical finding is bilateral opacities. These may start as unilateral and later progress to bilateral. The changes typically evolve over 1-3 weeks and usually peak at around 10-12 days.
X-ray and CT changes may also be visible in asymptomatic individuals.
The amount of lung involved is proportional to the severity of the disease.
- Bilateral opacities
- Rarely – pleural effusions
- Bilateral ground glass infiltrates
- Seen in >80% of cases
- Not specific, but can be considered diagnostic in the context of clinical symptoms consistent with coronavirus
- May be useful as a bedside test in the emergency setting
- Again – changes are the same as those seen in all viral pneumonias – and not specific to COVID-19
- Irregular pleural line
- Guillain-Barre Syndrome
- Acute kidney injury
- Acute liver injury
- Co-infection with other pathogens
- Multi-organ failure
No specific treatment is widely available as of July 2020. Care is supportive – mainly in the form of assisted oxygenation and ventilation in those with severe disease.
- Multiple trials are underway to assess the efficacy of several proposed treatments, including:
- The use of blood products (serum) containing antibodies from previously infected patients whom have now recovered
- Many other anti-virals
- Some reports in popular media suggest that dexamethasone may be effective, but as of July 2020, I have not found any guidelines that recommend its use or dose
Mild cases can be managed safely at home. Advise should be similar to that of other common upper respiratory tract infections, such as:
- Simple analgesia – e.g. paracetamol 1g QID
- Oral fluids – titrate to urine output – aim for straw coloured urine, passing urine at least x3 per day
- Safety-net instructions – such as – advise to seek medical review if increasing shortness of breath, light-headed or dizzy (pre-syncope), or syncopal symptoms, or generally unwell
Self isolation is an important public health measure for anybody with confirmed or suspected COVID-19.
- Self isolation should last until symptoms have resolved, OR
- Should last for 14 days in asymptomatic individuals advised to self isolate (see prevention below)
- Self-isolation should involve:
- Staying at home, or your hotel or place of residence
- Going outside to private gardens is OK
- NOT allowing visitors
- DO NOT visit public places, including schools, work, childcare, university, other public gatherings
- DO NOT use public transport
- Ask friends or relatives who are not in isolation to fetch food and any other items you many need. Online shopping may also be an option
- Infected patient should wear a face mask in any communal areas of the home to reduce the risk of droplet transmission
- Wearing a mask for non-infected patients is unlikely to reduce their risk of catching the infection
- Other people in the house:
- Will also be required to self-isolate if they have been in close contact with a confirmed infection (see close contact rules, above)
- Coping with self isolation
- Keep a regular routine – e.g. eating regular meals
- Work from home if possible
- Take regular exercise
- Arrange activities for children – and try to keep up with any school-work via email or other electronic means
- Staying at home, or your hotel or place of residence
- Cleaning around the house to minimise transmission – regular household detergent is suitable. Advise patients to regular wash any surfaces that are frequently touched in the home, such as:
- Door handles
- Light switches
- Kitchen and bathroom areas
Indicators of mild infection include:
- No shortness of breath
- O2 sats >92% on room air
- Speaking in full sentences
- Respiratory rate not raised
- No signs of increased work of breathing
- Not hypotensive
- No symptoms of pre-syncope or syncope, or signs of postural hypotension
- Normal heart rate – not tachycardic (HR <100)
- About 20% of cases are expected to require hospital admission
- The mainstay of treatment is supportive respiratory care – such as:
- Oxygen to maintain O2 sats >= 93%
- Intubation and ventilation in the most severe cases
- Other organ support in multi-organ failure
- The role of antiviral medication is as yet unclear
- Typical time from onset of illness to development of ARDS is 8-9 days
- 10% of patients develop secondary infections
Aim for the usual oxygenation targets:
- Sats >92% for most patients
- Sats 88-92% for patients with known COPD with CO2 retention
Types of oxygen supply device that can be safely used with standard droplet precautions:
- Nasal prongs / cannulae
- Hudson mask
- Non-rebreather mask
- Venturi mask
In patients who still do not maintain adequate oxygenation, despite these measures then forms of assisted ventilation – such as non-invasive ventilation (NIV) and intubation should be considered.
NIV devices are somewhat contentious. In theory they can produce aerosolised particles, and some studies of the SARS outbreak showed an increased risk of healthcare worker transmission when they were used. NIV devices included high-flow nasal cannulae (HFNC) and CPAP / BiPAP type devices with face masks (of various types).
Current recommendations generally suggest that:
- HFNC are recommended for use in acutely hypoxic patients
- Consider airborne and contact precautions
- Other types of NIV should be used with caution in COVID-19, and with airborne precautions
- A suggested approach is to use other forms of NIV only as a pre-oxygenation device when preparing for intubation
- Early experience in China led to a high rate of intubations – mainly based on the typical parameters used for intubation based on oxygenation
- However, subsequent experience in Europe and the USA has suggested that many patients with low oxygenation who are otherwise not distressed (the “happy hypoxics” described above) may have a better outcome by avoiding intubation
- As such, it may now be advisable for those even with poor oxygenation, if they are alert, do NOT have tachycardia or hypotension, and are able to “prone” themselves (lie on their front) – that they should not be intubated, and instead can tolerate low O2 sats whilst ever they still meet the parameters above
- The intubation procedure itself presents a very high level of risk to the staff involved
- High levels of PPE are recommended
- Avoid bag-valve-mask ventilation (BVM)
- Use video laryngoscope
- Avoid auscultating the chest after intubation
- Use viral filters on ventilators
- Consider taping all connections in the ventilator tubing – disconnections could be spraying the virus around the room
- Advice for ventilation
- Similar to ARDS management
- Tidal volume of 4-6 mL/Kg
- Plateau pressures <30 cmH20
- Allow hypercapnia as long as pH maintained >7.15
- Consider prone positioning if oxygenation is insufficient
- The long term effects are still unclear
- Reports include:
You can keep track of the various coronavirus vaccines in development via a vaccine tracker such as this one by The Guardian.
Basic hygiene measures may help to reduce the spread of the virus. Face mask wearing is now thought to be particularly important in reducing the spread of the virus.
Governments around the world, as of 15th March 2020, are being to enact restrictions on the movement and meeting of people and crowds. The aim of this is to slow the spread of the disease.
Minimising social contact is the main way to slow down the spread of the virus.
In addition to population measures to prevent spread, certain populations (such as those recently returning from high risk areas) are being advised to self-isolate, regardless of whether or not they have symptoms.
- 80% of patients have mild symptoms – similar to a common cold or the flu
- 20% of patients require hospital admission
- 5% require ICU admission
- Novel coronavirus has about a 2% mortality
- This is not evenly distributed, and disproportionally affects older and co-morbid populations
- The exact mortality rate cannot be accurately calculated until after the outbreak is over – through retrospective testing of the population for coronavirus antibodies to calculate the true incidence of the disease
Mortality by age
Most sources suggest that men are more likely to die than women, but this is not yet proven.
Mortality by pre-existing condition
|Chronic Respiratory disease||6%|
Public health implications
- Peak incidence in any given country or region is expected to occur about 2 months after the first cases
- 20-80% of the population is likely to be infected
- Duration of the pandemic is likely to be 6-12 months
- After this, the future of the virus is uncertain. It may become endemic – circulating amongst the population indefinitely.
- This could be either as a seasonal illness and rapidly mutating illness – like influenza – or as a non-seasonal disease – like chicken-pox
- A vaccine is under development but will probably not be available until late 2020 at the earliest
- Previous infection is likely to provide immunity for at least several years – but this is not known for sure
- The aim of public health measures is to slow the rate of spread
- It is believed it is no longer possible to contain the virus
- By slowing the spread of the virus, the peak of cases can be widened, reducing the peak load on health services
- There are concerns that in a brief and large outbreak, there will not be sufficient hospital and ICU beds to treat all those that will require hospital admission
- This has been succinctly described by Tim Stellar on twitter:
- Coronavirus disease 2019 (covid-19): a guide for UK GPs
- WHO – Coronavirus disease (COVID-19) outbreak
- Clinical care – Coronavirus Disease 2019 (COVID-19) – CDC
- Coronavirus cases – Worldometer
- COVID-19 Data pack – information is beautiful
- Coronavirus disease (COVID-19) – Isolation guidance – health.gov.au
- Coronavirus disease 2019 (COVID-19) – LIFTL
- A practical COVID-19 resource for Emergency Medicine – Emergency Medicine Cases