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Six unknown factors in coronavirus models and how they could affect predictions

  <span class="attribution"><a class="link " href="https://www.shutterstock.com/image-vector/social-distancing-flatten-curve-coronavirus-covid19-1675978102" rel="nofollow noopener" target="_blank" data-ylk="slk:EamesBot/Shutterstock;elm:context_link;itc:0;sec:content-canvas">EamesBot/Shutterstock</a></span>

Since the global outbreak of COVID-19, researchers have scrambled to develop and share models which can predict how the virus will spread. This is inherently tricky, as we know so little about the disease, and a model is only ever as good as the information you put into it.

Researchers at Imperial College London produced a model that predicted there could be more than 510,000 deaths in the UK in the absence of preventative measures by the government, assuming that each person with the virus would give it to between 2 and 2.6 other people.

But that’s only one important consideration among many. Some of these may have a negligible effect on the predictions of these models, but others could affect the results dramatically. Here are six factors that are still not entirely known, and how they could lead to different outcomes.

1. Asymptomatic spread

People who have the virus but don’t display symptoms are known as asymptomatic patients. There’s some evidence that these people can still spread it to others, but we don’t know how infectious these people are.

This could be a real issue, as the advice for a long time was only for people showing signs of the illness to stay at home. It could be that there were plenty of infectious people going about their lives, unwittingly spreading the virus.

If there is more asymptomatic spread than modellers assume, their models will be too optimistic in situations where people without symptoms haven’t self-isolated.

2. Mode of contact

Our understanding is that after the initial spillover – when the virus first jumped from an animal to a human – the virus only travels between humans, but we don’t yet have a full picture of how the virus spreads. To what extent can it be transmitted by people touching surfaces, for example? If modellers incorporate these other modes of contact with the virus, they are likely to see faster spreads as a result.

<span class="caption">How long does the virus linger on surfaces, and how might this accelerate the spread of the virus?</span> <span class="attribution"><a class="link " href="https://www.shutterstock.com/image-photo/person-holding-onto-handrail-escalator-public-1306778179" rel="nofollow noopener" target="_blank" data-ylk="slk:ThamKC/Shutterstock;elm:context_link;itc:0;sec:content-canvas">ThamKC/Shutterstock</a></span>

3. Flouting the rules

In the UK a new set of rules have only just been introduced (stay at home except for essential shopping and exercise and travel only to work if you’re a key worker). We have no idea how many people are planning on actually following them.

A YouGov poll found 93% in favour of these lockdown rules, so we might assume they’ll follow them, whereas 2% were strongly opposed, perhaps indicating they’ll flout them.

Measures to fight the pandemic work better if more people follow the rules, and modellers should provide results for both disciplined and less disciplined cases.

4. Hotspots

We know epidemics flare up earlier and more intensively in certain places, for instance diseases such as Ebola never spread fully around the globe. But we don’t know how tackling these hotspots early affects the spread of the virus later on.

This is important, as understanding hotspots – which are greatly affected by factors such as population density and cultural factors – can be vital in understanding the speed and spread of the disease.

In China, through tracking the rise of hotspots, they could tell the virus was spreading towards Shanghai and Beijing, driven by people travelling for their seasonal holidays. This allowed authorities to target their efforts.


Read more: How to model a pandemic


5. The incubation period

How long does it take between you getting exposed to the virus and you becoming infectious to other people? We don’t know either, and the WHO mentions that “most estimates of the incubation period for COVID-19 range from one to 14 days”.

We need to know this as a key part of the advice is that people sharing a household with someone showing symptoms should self-isolate, regardless of whether they display any.

Someone could catch the virus from a family member right at the end of their illness, and then go outdoors before they start to feel ill themselves, spreading the virus as they go. A shorter incubation period also leads to a faster epidemic spread, so a good model should account for a range of possible incubation periods.

6. How the spread differs between countries

The virus doesn’t necessarily behave the same way in every country, or every area of a country. In some cultures, older people socialise a lot, whereas in others, they spend much of their time alone. A higher than average population density in cities, or on public transport, could influence how quickly the virus spreads.

Assuming the virus works the same everywhere could produce wildly inaccurate predictions. Understanding the spread at the local, regional and national level is needed to make the best models possible.

<span class="caption">Cultural differences could play a big role in how fast the virus spreads in different countries.</span> <span class="attribution"><a class="link " href="https://webgate.epa.eu/webgate" rel="nofollow noopener" target="_blank" data-ylk="slk:EPA-EFE/JEON HEON-KYUN;elm:context_link;itc:0;sec:content-canvas">EPA-EFE/JEON HEON-KYUN</a></span>

Computer power

To take all this uncertainty into account, we have to run a massive amount of simulations.

Each time we add a factor, any of which could render the results useless if calculated badly, the amount of computer power needed to run the simulation grows.

If, for instance, we had a total of ten factors we needed to consider, and we wanted to try ten variations for each factor, we’d end up having to run 10 billion simulations – much more than the standard researcher’s laptop can handle.

At Brunel, we’ve handed over a number of machines to running coronavirus simulations (including a so-called grid computer, which bundles computers from different locations together to solve one overarching problem) – and in general, large computer communities such as supercomputing and cloud computing communities are keen to help.

We’ll be hearing a lot about models and simulations over the coming months as they begin to play an ever more influential role in our lives. But it’s important we never forget to ask – what information did they use to get their answer, and can they show their results still hold if the reality turns out a little different from what they assumed?

This article is republished from The Conversation under a Creative Commons license. Read the original article.

The Conversation
The Conversation

Derek Groen receives funding from the European Union Horizon 2020 research and innovation programme under grant agreement No. 800925 (VECMA) and 824115 (HiDALGO).

Ariana Zeka has received funding from the European Commission.

Imran Mahmood receives funding from the European Union Horizon 2020 research and innovation programme under grant agreement No. 824115 (HiDALGO).