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Cornavirus Predictions, Models, Analysis, Stats, Projects | All Talk here

There are many in world providing reliable models, predictions and some are just giving inaccurate data and predictions, solutions, All statisticians, Mathematics of Covid-19 Disease here.

 
The veil begins to lift on coronavirus | Analysis

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PARIS: Just three months ago, few people even knew the word “coronavirus”. But as the disease continues to spread across the globe, infecting and killing thousands, and causing millions to live in self-isolation, it has become a watchword for the daily life of billions.

Here are some of the questions that have been raised since coronavirus became headline news around the world:

WHO IS MOST AT RISK?

The severity of COVID-19, the disease caused by the new coronavirus, increases with age, as various studies have shown.

Published on March 31, the latest edition of the British medical journal “The Lancet” shows that the disease is on average much more dangerous for those over 60, with a mortality rate of 6.4 percent (among confirmed cases).

The mortality rate climbs to 13.4 percent for the over 80s against just 0.32 percent of deaths for the under 60s, according to studies made mainly on several hundred Chinese cases observed in February.

Similarly, the study shows that the proportion of patients requiring hospitalisation increases sharply with age: 0.04 percent for 10 to 19-year-olds, 4.3 percent for 40 to 49-year-olds, 11.8 percent for 60 to 69, and 18.4 percent for those over 80.

The last of these figures means that about one in five octogenarians develops a form serious enough to require hospitalisation.

Besides age, having a chronic illness — for example, respiratory failure, heart disease, history of stroke, cancer — is also a risk factor.

In a recent report on 10,000 deaths, the Italian Higher Institute of Health (ISS) identified common existing illnesses in the deceased.

The most common are hypertension (73.5 percent of cases), diabetes (31 percent) and coronary heart disease (27 percent).

Finally, according to an extensive analysis published on February 24 by Chinese researchers in the American medical journal “Jama”, the disease is mild in 80.9 percent of cases, “serious” in 13.8 percent of cases and “critical” in 4.7 percent of cases.

HOW MANY DEATHS CAN WE EXPECT?

The statistical correlation between the number of deaths in the world and the total number of officially registered cases, suggests COVID-19 kills approximately five percent of diagnosed patients, with disparities according to different countries.

But that fatality rate has to be treated with caution as it is unclear how many people have actually been infected.

Since many patients seem to develop few or no symptoms, their number is likely to be greater than the cases detected, which would therefore lower this rate.

In addition, countries have very different testing policies and some do not systematically test all suspected cases.

A few weeks ago Anthony Fauci, director of the National Institute of Infectious Diseases in the US, told Congress that the fatality rate was much lower than five percent.

“If you count all the cases of minimally symptomatic or asymptomatic infections, that probably brings the mortality rates down to somewhere around one percent,” he said, adding that this still makes coronavirus “10 times more lethal than the seasonal flu”.

The study published in “The Lancet” on March 31 estimated the proportion of deaths among the confirmed cases at 1.38 percent.

However, the danger of a disease does not only depend on the overall death rate but also on its ability to spread.

Even if only one percent of patients die, “it can make significant figures if 30 percent or 60 percent of a population is infected,” said Simon Cauchemez, of the Pasteur Institute in Paris.

The other factor that is affecting the fatality rate of this new disease is the congestion of hospitals, caused by a sudden and a massive influx of cases.

This complicates matters not only for those patients with severe forms of COVID-19 but for everyone else as well.

WHAT ARE THE SYMPTOMS?

According to the World Health Organization (WHO), the most common symptoms “include respiratory problems, fever, cough, shortness of breath and difficulty breathing”.

Each of these symptoms may be present to a greater or lesser extent depending on the case, and the development of symptoms fluctuates.

Another common symptom is loss of smell and taste.

According to a recent Belgian study carried out on 417 patients who were “non-severely” infected, 86 percent had problems with smell — most of them no longer sensing anything — and 88 percent had taste disorders.

Symptoms usually last two weeks or more, sometimes less. For some people it will get worse.

“In the most severe cases, the infection can lead to pneumonia, severe acute respiratory syndrome, kidney failure, and even death,” says the WHO.

There is no vaccine or medication, and managing the virus involves treating the symptoms. However, some patients are administered antiviral drugs or other experimental treatments, the effectiveness of which is still being evaluated.

HOW IS IT TRANSMITTED?

The virus is mainly transmitted by a respiratory route and by physical contact.

Transmission occurs in the droplets of saliva expelled by a patient, for example when he coughs. Scientists estimate that this requires a close contact distance, of about one metre (3.3 feet).

To avoid contagion, health authorities emphasise the need to take precautions. These include washing hands frequently, coughing or sneezing in the crook of one’s elbow or in a disposable handkerchief, and avoiding shaking hands and kissing.

They recommend wearing a mask if you are sick and point out that you can become infected by touching a contaminated object and then putting your hand to your face — eyes, nose or mouth.

A study published in mid-March in the American journal “NEJM” showed that coronavirus is detectable for up to two to three days on plastic or stainless steel surfaces, and up to 24 hours on cardboard.

However, these maximum durations are only theoretical, since they are recorded under experimental conditions.

“It only takes a little bit of the virus to remain on a surface to infect someone who touches it,” warned French health authorities on their official website.

“Indeed, after a few hours, the vast majority of the virus dies and is probably no longer contagious.”

Another unknown is whether coronavirus can be transmitted simply through breath rather than coughing or sneezing. This has been the subject of much speculation in recent weeks but nothing has yet been scientifically proven.

– Can a person be infected twice? –

Is it possible to be contaminated by the coronavirus, to recover and test negative, only to contract the virus a second time? Several cases in Asia have raised this question.

To the extent that these cases were isolated, scientists believe that these patients were probably never fully recovered in the first place.

The negative test can either come from the fact that it was not done properly or because at that point the presence of the virus in the body was very weak.

However, there is still no certainty about the level of immunity we can acquire against the coronavirus. Based on the example of other viral diseases, specialists believe that once cured, a person is temporarily immune, even if this is not yet proven.

Crucially however, it is not known how long this supposed immunity lasts.

“If theoretically, a person can maintain immunity for a prolonged period (for instance 12-24 months) post-recovery, they could conceivably safely return to public spaces even as the virus continues to circulate,” says the Center for Strategic and International Studies (CSIS) in Washington.

“Inversely, if immunity is very short-lived, a person who has been infected could soon become reinfected.”

https://www.pakistantoday.com.pk/2020/04/07/veil-begins-lift-coronavirus/
 

Scientific research have narrowed down to horseshoe bats being carriers of coronaviruses and infecting humans upon contact and/or close encounters, and coronaviruses have recombinogenic properties which are not apparent in other types of viruses:

Evolutionary origins of the SARS‐CoV‐2 sarbecovirus lineage responsible for the COVID-19 pandemic

Abstract

There are outstanding evolutionary questions on the recent emergence of coronavirus SARS-CoV-2/hCoV-19 in Hubei province that caused the COVID-19 pandemic, including (1) the relationship of the new virus to the SARS-related coronaviruses, (2) the role of bats as a reservoir species, (3) the potential role of other mammals in the emergence event, and (4) the role of recombination in viral emergence. Here, we address these questions and find that the sarbecoviruses – the viral subgenus responsible for the emergence of SARS-CoV and SARS-CoV-2 – exhibit frequent recombination, but the SARS-CoV-2 lineage itself is not a recombinant of any viruses detected to date. In order to employ phylogenetic methods to date the divergence events between SARS-CoV-2 and the bat sarbecovirus reservoir, recombinant regions of a 68-genome sarbecovirus alignment were removed with three independent methods. Bayesian evolutionary rate and divergence date estimates were consistent for all three recombination-free alignments and robust to two different prior specifications based on HCoV-OC43 and MERS-CoV evolutionary rates. Divergence dates between SARS-CoV-2 and the bat sarbecovirus reservoir were estimated as 1948 (95% HPD: 1879-1999), 1969 (95% HPD: 1930-2000), and 1982 (95% HPD: 1948-2009). Despite intensified characterization of sarbecoviruses since SARS, the lineage giving rise to SARS-CoV-2 has been circulating unnoticed for decades in bats and been transmitted to other hosts such as pangolins. The occurrence of a third significant coronavirus emergence in 17 years together with the high prevalence and virus diversity in bats implies that these viruses are likely to cross species boundaries again.

Full read: https://www.biorxiv.org/content/biorxiv/early/2020/03/31/2020.03.30.015008.full.pdf (PDF format)

The aforementioned findings motivate a look at the global distribution of horseshoe bats:

Geographical-distribution-of-different-horseshoe-bats-which-were-discovered-to-carry.jpg
(1)

(1) Taken from following study:

Global Epidemiology of Bat Coronaviruses

Abstract

Bats are a unique group of mammals of the order Chiroptera. They are highly diversified and are the group of mammals with the second largest number of species. Such highly diversified cell types and receptors facilitate them to be potential hosts of a large variety of viruses. Bats are the only group of mammals capable of sustained flight, which enables them to disseminate the viruses they harbor and enhance the chance of interspecies transmission. This article aims at reviewing the various aspects of the global epidemiology of bat coronaviruses (CoVs). Before the SARS epidemic, bats were not known to be hosts for CoVs. In the last 15 years, bats have been found to be hosts of >30 CoVs with complete genomes sequenced, and many more if those without genome sequences are included. Among the four CoV genera, only alphaCoVs and betaCoVs have been found in bats. As a whole, both alphaCoVs and betaCoVs have been detected from bats in Asia, Europe, Africa, North and South America and Australasia; but alphaCoVs seem to be more widespread than betaCoVs, and their detection rate is also higher. For betaCoVs, only those from subgenera Sarbecovirus, Merbecovirus, Nobecovirus and Hibecovirus have been detected in bats. Most notably, horseshoe bats are the reservoir of SARS-CoV, and several betaCoVs from subgenus Merbecovirus are closely related to MERS-CoV. In addition to the interactions among various bat species themselves, bat–animal and bat–human interactions, such as the presence of live bats in wildlife wet markets and restaurants in Southern China, are important for interspecies transmission of CoVs and may lead to devastating global outbreaks.

Full read: https://www.mdpi.com/1999-4915/11/2/174

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In light of the above, it make sense to retrace PATIENT ZERO in every country: https://www.weforum.org/agenda/2020/03/coronavirus-covid-19-patient-zero/

This information is useful to those who are looking forward to help combating COVID-19 outbreak and/or already involved in any capacity, and will also help quell affiliated conspiracy theories floating around in this forum and elsewhere. At minimum, this information will contribute to knowledge of people.

Regards and take care.
 
Why it’s so hard to see into the future of Covid-19
The hardest thing for a epidemiological model to predict: human behavior.

By Brian Resnick@B_resnickbrian@vox.com Apr 10, 2020, 11:42am EDTShare this on Facebook (opens in new window)
One of the greatest challenges of the coronavirus pandemic is that all levels of policy makers need to make decisions with imperfect information. Scientists still don’t know everything about how this virus is transmitted, and due to the lack of widespread testing, they also don’t know, exactly, how prevalent it is. They don’t know if the virus will show a strong seasonal effect, and decreased during the summer. They don’t know how this will all end.

One way they are trying to answer these questions is through modeling. Specifically, infectious disease models are tools — based on mathematical formulations — that try to game out what’s possible in the future. These models are varied, often confusing to interpret, and are not crystal balls, especially because the ideal data isn’t yet available. But they are a large part of what government leaders use to make decisions, influencing how resources are allocated to health care facilities and how social distancing orders are issued to the public.

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Deborah Birx holds notes on coronavirus cases during a briefing in Washington, DC, on April 2.
Win McNamee/Getty Images
In this piece, I’m going to try to explain the utility of coronavirus models and how to think about them when you see them reported in the news. I’ll also explain a big idea to make these models work better in the future.

But before that, I think it’s key to stress what we don’t need them for. We don’t need them to know that we’re in a very, very dangerous situation.

“What’s very important is not the details of the model, it’s that this is a virus that can crush health care,” says Bill Hanage, an epidemiologist who studies infectious diseases at Harvard. “That’s not a model result, that’s an observation. We know it because of Wuhan, we know it because of Italy, because of Spain, we know it because, now, of New York.“

In New York state, thousands have died, and hospitals are at, or exceeding capacity and struggling with equipment shortages. Covid-19 is “a freight train,” as Hanage calls it, and it has rammed into not just New York but several other parts of the US.

Why do some young, healthy people die from Covid-19?[/paste:font]
But the models also show that the country is nearing the peak in daily deaths. And people should continue to listen to their mayors and governors and stay at home. Modeling plays a very important role for public decision-making, and it can help the public know that they, are, in fact, doing the right thing by staying home.

Modeling an outbreak is an immense challenge
Leaders have tough choices to make in the weeks and months ahead, as the outbreak plays out differently in states. Models can help predict rates of new infections, and estimate when the strain on the hospital system could peak. In early April, Washington, DC, Mayor Muriel Bowser said that modeling projects a surge in DC area hospitals during the summer. “Like all models, we hope this one will be proved wrong,” she told MSNBC. But she’s preparing for it anyway. “We are preparing for many people to come through our hospitals.”

Forecasting disease outbreaks is an immense challenge. Models incorporate many different types of data into their projections. There are a head-spinning number of potential inputs. (And some models don’t use these inputs at all, but just rely on projecting data from earlier in the outbreak.)

A model can input the biology of the virus: How does it spread, how quickly does it infect, how quickly does it lead to symptoms, how quickly does it replicate to a level where it can jump from person to person? (Note: A lot of these variables are still not completely known.)

isn’t perfectly understood either.)

It also should, ideally, reflect how human society works: How many people do we come into contact with each day, and how does this vary in different communities, rural and urban? Models need to account for that; in a big country like the United States, outbreaks are going to be regional, with varying intensities and responses.

It needs to be realistic about the capacities of health care systems: How many beds are available for Covid-19 patients, how quickly will they fill up, how many doctors and nurses are there to serve them, how many ventilators are there, and how many patients will need them, and when?

Then, there’s chaos: How do people react to the news that tens of thousands are dying from a virus that probably started with a bat, and how might that influence the model?

The question of “how will an outbreak progress” is clearly immense. In a common modeling approach called SIR (SIR stands for susceptible, infected, recovered) scientists are trying to figure how many people are susceptible to a disease, how many of them will become infected, and at what rate and where. But then, as more people recover from the disease, and become immune, that decreases the number of those who are susceptible.

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A group of medical workers help a patient in Brooklyn, New York, on April 7.
Pablo Monsalve/VIEWpress via Getty Images
To sum up: This stuff is complicated! That we can get any insight into the future, considering the variables, is a miracle. Yet scientists are trying, and their efforts are valuable.

Hanage explains there are basically two main types of models being used to try to plot out the course of this pandemic: statistical models and mechanistic models.

Let’s start by explaining statistical models.

Statistical models try to predict the future by projecting current trends
The Institute for Health Metrics and Evaluation (IHME) has the most commonly cited models — and it includes separate projections for every state. Dr. Deborah Birx, the White House coronavirus response coordinator, has referenced it. Hanage explains this model is what’s known as a statistical model.

The IHME, based out of the University of Washington, looks at data of how Covid-19 outbreaks have progressed around the world. It takes that data and then tries to project what the epidemic curve will look like as new outbreaks form in new areas based on what social distancing actions are being taken. The goal is to predict the time of peak hospital strain in an area, and the number of deaths.

To use Hanage’s metaphor: It’s looking at how fast and hard the freight train has hit on other stops of its journey, and predicting it will hit that fast and hard when it gets to new stops.

This model makes some assumptions, namely, that the conditions for the previous freight train collisions will be similar in the future.

Earlier in the outbreak, the model was mainly fed from data in China, which imposed extreme social distancing measures. And so it assumes some high level of social distancing will continue into the future. “That makes this a best-case scenario model,” Carl Bergstrom, a computational biologist at the University of Washington, assessed on Twitter. It’s now also drawing from current social distancing actions in the US.

The IHME model assumes this behavior will continue. And its creators are transparent about this limitation. The projection, the IHME explains on its FAQ page, “only covers the next four months and does not predict how many deaths there may be if there is a resurgence at a later point or if social distancing is not fully implemented and maintained.” The hardest thing to model in all of this, is not the virus, but human behavior.

The IHME model projections have changed over the course of the outbreak, as its creators have input new data from new outbreaks, new social distancing measures, and new resources (like ventilators) that have become available. (The model is regularly updated with new data).

This has actually led the models to decrease their death toll projection for the US a few times, most recently from 81,766 to 60,415, or about 25 percent. This doesn’t mean the model has been wrong or shortsighted. It means collective actions have been working.


Ali H. Mokdad@AliHMokdad

https://twitter.com/AliHMokdad/status/1247978436930318336

Our estimates for total COVID-19 deaths have dropped from 81,766 to 60,415 in today’s update. Why? Because social distancing measures in the US are working. Some Americans stayed at home before the orders came. Encouraging news #COVID19 #socialdistancing »http://covid19.healthdata.org/projections


IHME | COVID-19 Projections
Explore hospital bed use, need for intensive care beds, and ventilator use due to COVID-19 based on projected deaths

covid19.healthdata.org


145

1:03 AM - Apr 9, 2020
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Also keep in mind: The IHME death toll projections come with a huge range of error. In the model, deaths per day are expected to peak soon in the US. As of April 10, it’s two days away, and the error — the shaded area, spans roughly 4,000 deaths per day.

Screen_Shot_2020_04_10_at_10.07.57_AM.png
IHME
“I think it’s key not to get fixated on the exact numbers,” Dominique Heinke, an epidemiologist in Massachusetts, says. “You can look at a range of models and say, we can expect it to be at least this bad.” Again, we know this: The freight train is coming, and in many places, is already here.

What’s the good use of a forecast model if it changes all the time? Well, it reflects the complexity of the problem these models are trying to solve. For example, weather forecasters use atmospheric models to predict the weather, and as they gather more data on temperature, humidity, and barometric pressure, their forecasts become more accurate and, thus, often change.

“Unlike the weather, which we’re all accustomed to understanding and incorporating forecast into whatever decision you make, unlike the weather [here] we actually influence the outcome,” says Caitlin Rivers, a professor at the Johns Hopkins Center for Health Security. “So people see the numbers, and they are motivated then to be more aware, stay home, and using good hygiene and doing all the things that really change that outcome.”

The models change, because our actions change. The models could change for the worse if local governments declare premature victories and decrease social distancing measures too early.

“By keeping an eye on the model, we can tell how the virus is circulating in our own communities: in some places, cases and deaths are still going up, in some places they are starting to come down,” says Ali Mokdad, a professor at IHME and chief strategy officer for population health at the University of Washington. “We can also use the model to ask what businesses we should open first as we recover: The key issue as we go into recovery mode is to do it in stages so we don’t have a second wave of infections that will hurt us even more in terms of mortality and the economy.”

Unless testing can be scaled up, some social distancing measures may have to be kept in place until there is a vaccine available, which can take a year or more. What happens in the scenario when social distancing measures are relaxed, but then put in place again if cases spike again? “I’m not sure we can model that,” Hanage says.

Mechanistic models try to game out how the outbreak looks under different scenarios
The other type of model decision makers are using is a mechanistic model. These models are designed to help policy makers understand the impacts specific policies and actions may have on a disease’s course. These models also make a lot of assumptions, and often present very wide ranging scenarios.

A good example of a mechanistic model comes from the Imperial College of London.

In the middle of March, it provided a scary wake-up call to the UK government to take more action. Their model looked at what would happen in Great Britain and in the United States if the countries did nothing. It took what it knew about the transmissibility of the virus and put it into a model designed for the flu — a caveat right off the bat, as Covid-19 is not the flu.

(Transmissibility here is often called the R0, or R-naught, it’s the average number of new cases expected to be spawned by each case of an illness. Note: The value of the R0 is still just an estimation).

Predictions are hard, especially about the coronavirus[/paste:font]
In the scenario where nothing is done, the model’s authors found, there could be 510,000 deaths in Great Britain, and 2.2 million in the US. And that was “not accounting for the potential negative effects of health systems being overwhelmed on mortality,” the authors report.

That made headlines. But their model didn’t just report the worst-case scenario. It tried to game out the impact of various social distancing policies, and tried to make estimates for many different R0 figures. The estimates ranged, for Great Britain, from just 5,600 deaths assuming a low R0 of 2, and the most aggressive social distancing, and 550,000 deaths assuming an R0 of 2.6 and no social distancing measures.

If you’re a leader of a country, looking at that spread, you know what you need to do: implement social distancing measures. That’s what the UK did. Later, when one of the model’s authors told the UK government in testimony that the deaths in Great Britain would probably number around 20,000, he was not revising the model, as some critics complained. Instead, he was reflecting that range of possibilities presented in the model.

Again, the point of these models is not to precisely predict the future, it’s to influence the future, and choose a good course of action.

That’s helpful. But again, as with the statistical model, these mechanistic models can’t game out every possible future.

GettyImages_1205517449.jpg

This Johns Hopkins outbreak map dashboard is being used to track the novel coronavirus by officials worldwide.
Samuel Corum/Getty Images
Recently, Columbia University put out a model (with a handy interactive map) that tries to predict which US counties will have their health care systems overwhelmed, under different social distancing scenarios, and when.

The model also attempts to help hospitals by gaming out how different coping strategies in hospitals (i.e. converting operating room beds to Covid-19 care beds, for one example, and modifying ventilators for use in multiple patients for another) could mitigate the problem, and help save lives.

The prediction is grim for the crush on hospital systems, which is expected to soon move from the northeast United States, to southern counties, as the outbreak starts to impact more and more rural areas. (Keep in mind: As outbreaks in some cities taper off, outbreaks in other areas may just be getting started.)

It’s a complicated model. It’s trying to predict hospital bed demand, ICU bed demand, ventilator demand, Jeff Shaman, an infectious disease modeler at Columbia explains. “It’s a mathematical description of transmission at county scale, where the counties are linked by movement between them based on ... travel patterns, and understanding that those have waned over time because of this ongoing Covid crisis.”

Experts predict American hospital staffing will “spiral” as doctors fall ill to coronavirus[/paste:font]
It tries to account for a lot, but it can’t account for everything. Something it can’t account for: the possibility that health care workers get sick and have to leave work, leaving these hospital systems more strained. “We’re in the process right now on establishing a national database on staffing levels,” Charles Branas, chair of epidemiology, at Columbia says. “It’s been challenging to build this airplane while it is flying, quite frankly.”

That doesn’t mean the model is useless. It can still help guide decision-making. You can look at the map and see which counties are still overwhelmed in their best-case scenarios. “Those could potentially be first-choice counties for supplementary resources,” Branas says.

I asked these Columbia researchers how they’d like the public to think of their model.

“These are not forecasts, they are projections, we’re dealing with a very, very uncertain environment,” Shaman stressed. “The degree to which people are social distancing ... is changing day-to-day. It is difficult to pin down what’s going on. We’re making multiple projections because we don’t know what people will do. We do it because we would like some window into the future. So we can assess: Are we on a really bad trajectory no matter what we do? Or are we on a good trajectory no matter what we do? Or is it incumbent upon us to make certain decisions so we can more certainly move to a better outcome?“

(Another mechanistic model to check out: The University of Pennsylvania has a tool for regional leaders to input their own observations, and see how an outbreak might impact their area’s hospitals.)

What we need in the future is better disease forecasting
There’s a lot that’s still unknown about the coronavirus, and the pandemic.

“There will be people writing papers 100 years from now about what actually happened, there will be people making discoveries about the relative rates of increase in San Francisco vs New York,” Hanage says.

Rivers, the Johns Hopkins epidemiologist, hopes, in the future, we’ll get better at this. Like the US has the National Weather Service — a government agency staffed to create weather models and test their predictive power — she hopes to see the creation of a National Infectious Disease Forecasting Center.

“The reason that we have accurate weather forecast today, is because there was a federal agency responsible for weather forecast,” she says.

We need to learn from the modeling approaches being used now, to make better models for the future. The weather service does this for hurricanes: You can clearly see in the weather service data how hurricane forecast tracks (i.e. forecast models) have greatly improved over time. Rivers doesn’t see that as an accident. The weather models have improved because there’s a centralized service to study and create them.

She says there needs to be some central agency collecting these models in an archive, so that researchers later on can figure out which ones worked the best, and why. It could then incorporate that understanding to better forecast future outbreaks.

“THE POINT OF THESE MODELS IS NOT TO PRECISELY PREDICT THE FUTURE, IT’S TO INFLUENCE THE FUTURE, AND CHOOSE A GOOD COURSE OF ACTION”
Right now, there are a lot of models. There are a lot of projections. We’re not sure which ones will be most accurate, or useful. “Don’t end up being obsessed with a specific number,” Hanage gives a final piece of advice. “Just end up recognizing the number is large. That’s the best way to think about it.”

Hanage offers another potentially helpful metaphor: “A very, very good physicist will be able to model what will happen if you walk out into the interstate and say exactly where your body parts might land, but the fact that another model puts the body parts in another place, doesn’t alter the central conclusion that you’re going to get run down by a car,” he says.

For now, the biggest message from all of them is that social distancing measures are indeed saving lives. The models predicted that weeks ago — and that prediction is coming true. We can all feel good about our sacrifices because of that.
 
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