Human trials will begin imminently – but even if they go well, there are many hurdles before global im
Human trials will begin imminently – but even if they go well, there are many hurdles before global immunisation is feasible
When will a coronavirus vaccine be ready? Illustration by James Melaugh.
Illustration: James Melaugh/The Observer
Even
at their most effective – and draconian – containment strategies have
only slowed the spread of the respiratory disease Covid-19. With the
World Health
Organization finally declaring a pandemic, all eyes have turned to the
prospect of a vaccine, because only a vaccine can prevent people from
getting sick.
About 35 companies and academic institutions are racing to create
such a vaccine, at least four of which already have candidates they have
been testing in animals. The first of these – produced by Boston-based
biotech firm Moderna – will enter human trials imminently.
This unprecedented speed is thanks in large part to early Chinese
efforts to sequence the genetic material of Sars-CoV-2, the virus that
causes Covid-19. China shared that sequence in early January, allowing
research groups around the world to grow the live virus and study how it
invades human cells and makes people sick.
Advertisement
But
there is another reason for the head start. Though nobody could have
predicted that the next infectious disease to threaten the globe would
be caused by a coronavirus – flu is generally considered to pose the
greatest pandemic risk – vaccinologists had hedged their bets by working
on “prototype” pathogens. “The speed with which we have [produced these
candidates] builds very much on the investment in understanding how to
develop vaccines for other coronaviruses,” says Richard Hatchett, CEO of
the Oslo-based nonprofit the Coalition for Epidemic Preparedness Innovations (Cepi), which is leading efforts to finance and coordinate Covid-19 vaccine development.
Coronaviruses have caused two other recent epidemics – severe acute
respiratory syndrome (Sars) in China in 2002-04, and Middle East
respiratory syndrome (Mers), which started in Saudi Arabia in 2012. In
both cases, work began on vaccines that were later shelved when the
outbreaks were contained. One company, Maryland-based Novavax, has now
repurposed those vaccines for Sars-CoV-2, and says it has several
candidates ready to enter human trials this spring. Moderna, meanwhile,
built on earlier work on the Mers virus conducted at the US National
Institute of Allergy and Infectious Diseases in Bethesda, Maryland.
A researcher works in a lab at the Duke-NUS Medical School in Singapore. Photograph: Joseph Campbell/Reuters
Advertisement
Sars-CoV-2
shares between 80% and 90% of its genetic material with the virus that
caused Sars – hence its name. Both consist of a strip of ribonucleic
acid (RNA) inside a spherical protein capsule that is covered in spikes.
The spikes lock on to receptors on the surface of cells lining the
human lung – the same type of receptor in both cases – allowing the
virus to break into the cell. Once inside, it hijacks the cell’s
reproductive machinery to produce more copies of itself, before breaking
out of the cell again and killing it in the process.
All vaccines work according to the same basic principle. They
present part or all of the pathogen to the human immune system, usually
in the form of an injection and at a low dose, to prompt the system to
produce antibodies to the pathogen. Antibodies are a kind of immune
memory which, having been elicited once, can be quickly mobilised again
if the person is exposed to the virus in its natural form.
Traditionally, immunisation has been achieved using live, weakened
forms of the virus, or part or whole of the virus once it has been
inactivated by heat or chemicals. These methods have drawbacks. The live
form can continue to evolve in the host, for example, potentially
recapturing some of its virulence and making the recipient sick, while
higher or repeat doses of the inactivated virus are required to achieve
the necessary degree of protection. Some of the Covid-19 vaccine
projects are using these tried-and-tested approaches, but others are
using newer technology. One more recent strategy – the one that Novavax
is using, for example – constructs a “recombinant” vaccine. This
involves extracting the genetic code for the protein spike on the
surface of Sars-CoV-2, which is the part of the virus most likely to
provoke an immune reaction in humans, and pasting it into the genome of a
bacterium or yeast – forcing these microorganisms to churn out large
quantities of the protein. Other approaches, even newer, bypass the
protein and build vaccines from the genetic instruction itself. This is
the case for Moderna and another Boston company, CureVac, both of which
are building Covid-19 vaccines out of messenger RNA.
Cepi’s original portfolio of four funded Covid-19 vaccine projects
was heavily skewed towards these more innovative technologies, and last
week it announced $4.4m (£3.4m) of partnership funding with Novavax and with a University of Oxford
vectored vaccine project. “Our experience with vaccine development is
that you can’t anticipate where you’re going to stumble,” says Hatchett,
meaning that diversity is key. And the stage where any approach is most
likely to stumble is clinical or human trials, which, for some of the
candidates, are about to get under way.
Clinical trials, an essential precursor to regulatory approval,
usually take place in three phases. The first, involving a few dozen
healthy volunteers, tests the vaccine for safety, monitoring for adverse
effects. The second, involving several hundred people, usually in a
part of the world affected by the disease, looks at how effective the
vaccine is, and the third does the same in several thousand people. But
there’s a high level of attrition as experimental vaccines pass through
these phases. “Not all horses that leave the starting gate will finish
the race,” says Bruce Gellin, who runs the global immunisation programme
for the Washington DC-based nonprofit, the Sabin Vaccine Institute.
Advertisement
There
are good reasons for that. Either the candidates are unsafe, or they’re
ineffective, or both. Screening out duds is essential, which is why
clinical trials can’t be skipped or hurried. Approval can be accelerated
if regulators have approved similar products before. The annual flu
vaccine, for example, is the product of a well-honed assembly line in
which only one or a few modules have to be updated each year. In
contrast, Sars-CoV-2 is a novel pathogen in humans, and many of the
technologies being used to build vaccines are relatively untested too.
No vaccine made from genetic material – RNA or DNA – has been approved
to date, for example. So the Covid-19 vaccine candidates have to be
treated as brand new vaccines, and as Gellin says: “While there is a
push to do things as fast as possible, it’s really important not to take
shortcuts.”
An illustration of that is a vaccine that was produced in the 1960s
against respiratory syncytial virus, a common virus that causes
cold-like symptoms in children. In clinical trials, this vaccine was
found to aggravate those symptoms in infants who went on to catch the
virus. A similar effect was observed in animals given an early
experimental Sars vaccine. It was later modified to eliminate that
problem but, now that it has been repurposed for Sars-CoV-2, it will
need to be put through especially stringent safety testing to rule out
the risk of enhanced disease.
It’s for these reasons that taking a vaccine candidate all the way to
regulatory approval typically takes a decade or more, and why President Trump sowed confusion
when, at a meeting at the White House on 2 March, he pressed for a
vaccine to be ready by the US elections in November – an impossible
deadline. “Like most vaccinologists, I don’t think this vaccine will be
ready before 18 months,” says Annelies Wilder-Smith, professor of
emerging infectious diseases at the London School of Hygiene and
Tropical Medicine. That’s already extremely fast, and it assumes there
will be no hitches.
Dr Fauci speaks to US President Donald Trump during a
tour of the National Institutes of Health. Photograph: Leah
Millis/Reuters
Advertisement
In
the meantime, there is another potential problem. As soon as a vaccine
is approved, it’s going to be needed in vast quantities – and many of
the organisations in the Covid-19 vaccine race simply don’t have the
necessary production capacity. Vaccine development is already a risky
affair, in business terms, because so few candidates get anywhere near
the clinic. Production facilities tend to be tailored to specific
vaccines, and scaling these up when you don’t yet know if your product
will succeed is not commercially feasible. Cepi and similar
organisations exist to shoulder some of the risk, keeping companies
incentivised to develop much-needed vaccines. Cepi plans to invest in
developing a Covid-19 vaccine and boosting manufacturing capacity in
parallel, and earlier this month it put out a call for $2bn to allow it
to do so.
Once a Covid-19 vaccine has been approved, a further set of
challenges will present itself. “Getting a vaccine that’s proven to be
safe and effective in humans takes one at best about a third of the way
to what’s needed for a global immunisation programme,” says global
health expert Jonathan Quick of Duke University in North Carolina, author of The End of Epidemics
(2018). “Virus biology and vaccines technology could be the limiting
factors, but politics and economics are far more likely to be the
barrier to immunisation.”
The problem is making sure the vaccine gets to all those who need it.
This is a challenge even within countries, and some have worked out
guidelines. In the scenario of a flu pandemic, for example, the UK would
prioritise vaccinating healthcare and social care workers, along with
those considered at highest medical risk – including children and
pregnant women – with the overall goal of keeping sickness and death
rates as low as possible. But in a pandemic, countries also have to
compete with each other for medicines.
Because pandemics tend to hit hardest those countries that have the
most fragile and underfunded healthcare systems, there is an inherent
imbalance between need and purchasing power when it comes to vaccines.
During the 2009 H1N1 flu pandemic, for example, vaccine supplies were
snapped up by nations that could afford them, leaving poorer ones short.
But you could also imagine a scenario where, say, India – a major
supplier of vaccines to the developing world – not unreasonably decides
to use its vaccine production to protect its own 1.3 billion-strong
population first, before exporting any.
2:10
How do I know if I have coronavirus and what happens next? – video explainer
Advertisement
Outside
of pandemics, the WHO brings governments, charitable foundations and
vaccine-makers together to agree an equitable global distribution
strategy, and organisations like Gavi, the vaccine alliance, have come
up with innovative funding mechanisms to raise money on the markets for
ensuring supply to poorer countries. But each pandemic is different, and
no country is bound by any arrangement the WHO proposes – leaving many
unknowns. As Seth Berkley, CEO of Gavi, points out: “The question is,
what will happen in a situation where you’ve got national emergencies
going on?”
This is being debated, but it will be a while before we see how it
plays out. The pandemic, says Wilder-Smith, “will probably have peaked
and declined before a vaccine is available”. A vaccine could still save
many lives, especially if the virus becomes endemic or perennially
circulating – like flu – and there are further, possibly seasonal,
outbreaks. But until then, our best hope is to contain the disease as
far as possible. To repeat the sage advice: wash your hands. • This article was amended on 19 March
2020. An earlier version incorrectly stated that the Sabin Vaccine
Institute was collaborating with the Coalition for Epidemic Preparedness
Innovations (Cepi) on a Covid-19 vaccine.
Since you’re here...
… we’re asking readers like you to make a
contribution in support of our open, independent journalism. In these
frightening and uncertain times, the expertise, scientific knowledge and
careful judgment in our reporting has never been so vital. No matter
how unpredictable the future feels, we will remain with you, delivering
high quality news so we can all make critical decisions about our lives,
health and security. Together we can find a way through this.
You’ve
read 5 articles in the last four months. We believe every one of us
deserves equal access to accurate news and calm explanation. So, unlike
many others, we made a different choice: to keep Guardian journalism
open for all, regardless of where they live or what they can afford to
pay. This would not be possible without the generosity of readers, who
now support our work from 180 countries around the world.
We
have upheld our editorial independence in the face of the
disintegration of traditional media – with social platforms giving rise
to misinformation, the seemingly unstoppable rise of big tech and
independent voices being squashed by commercial ownership. The
Guardian’s independence means we can set our own agenda and voice our
own opinions. Our journalism is free from commercial and political bias –
never influenced by billionaire owners or shareholders. This makes us
different. It means we can challenge the powerful without fear and give a
voice to those less heard.
Your financial support has
meant we can keep investigating, disentangling and interrogating. It has
protected our independence, which has never been so critical. We are so
grateful.
We need your support so we can keep delivering
quality journalism that’s open and independent. And that is here for the
long term. Every reader contribution, however big or small, is so
valuable. Support the Guardian from as little as $1 – and it only takes a minute. Thank you.
When will a coronavirus vaccine be ready? Illustration by James Melaugh.
Illustration: James Melaugh/The Observer
Even
at their most effective – and draconian – containment strategies have
only slowed the spread of the respiratory disease Covid-19. With the
World Health
Organization finally declaring a pandemic, all eyes have turned to the
prospect of a vaccine, because only a vaccine can prevent people from
getting sick.
About 35 companies and academic institutions are racing to create
such a vaccine, at least four of which already have candidates they have
been testing in animals. The first of these – produced by Boston-based
biotech firm Moderna – will enter human trials imminently.
This unprecedented speed is thanks in large part to early Chinese
efforts to sequence the genetic material of Sars-CoV-2, the virus that
causes Covid-19. China shared that sequence in early January, allowing
research groups around the world to grow the live virus and study how it
invades human cells and makes people sick.
Advertisement
But
there is another reason for the head start. Though nobody could have
predicted that the next infectious disease to threaten the globe would
be caused by a coronavirus – flu is generally considered to pose the
greatest pandemic risk – vaccinologists had hedged their bets by working
on “prototype” pathogens. “The speed with which we have [produced these
candidates] builds very much on the investment in understanding how to
develop vaccines for other coronaviruses,” says Richard Hatchett, CEO of
the Oslo-based nonprofit the Coalition for Epidemic Preparedness Innovations (Cepi), which is leading efforts to finance and coordinate Covid-19 vaccine development.
Coronaviruses have caused two other recent epidemics – severe acute
respiratory syndrome (Sars) in China in 2002-04, and Middle East
respiratory syndrome (Mers), which started in Saudi Arabia in 2012. In
both cases, work began on vaccines that were later shelved when the
outbreaks were contained. One company, Maryland-based Novavax, has now
repurposed those vaccines for Sars-CoV-2, and says it has several
candidates ready to enter human trials this spring. Moderna, meanwhile,
built on earlier work on the Mers virus conducted at the US National
Institute of Allergy and Infectious Diseases in Bethesda, Maryland.
A researcher works in a lab at the Duke-NUS Medical School in Singapore. Photograph: Joseph Campbell/Reuters
Advertisement
Sars-CoV-2
shares between 80% and 90% of its genetic material with the virus that
caused Sars – hence its name. Both consist of a strip of ribonucleic
acid (RNA) inside a spherical protein capsule that is covered in spikes.
The spikes lock on to receptors on the surface of cells lining the
human lung – the same type of receptor in both cases – allowing the
virus to break into the cell. Once inside, it hijacks the cell’s
reproductive machinery to produce more copies of itself, before breaking
out of the cell again and killing it in the process.
All vaccines work according to the same basic principle. They
present part or all of the pathogen to the human immune system, usually
in the form of an injection and at a low dose, to prompt the system to
produce antibodies to the pathogen. Antibodies are a kind of immune
memory which, having been elicited once, can be quickly mobilised again
if the person is exposed to the virus in its natural form.
Traditionally, immunisation has been achieved using live, weakened
forms of the virus, or part or whole of the virus once it has been
inactivated by heat or chemicals. These methods have drawbacks. The live
form can continue to evolve in the host, for example, potentially
recapturing some of its virulence and making the recipient sick, while
higher or repeat doses of the inactivated virus are required to achieve
the necessary degree of protection. Some of the Covid-19 vaccine
projects are using these tried-and-tested approaches, but others are
using newer technology. One more recent strategy – the one that Novavax
is using, for example – constructs a “recombinant” vaccine. This
involves extracting the genetic code for the protein spike on the
surface of Sars-CoV-2, which is the part of the virus most likely to
provoke an immune reaction in humans, and pasting it into the genome of a
bacterium or yeast – forcing these microorganisms to churn out large
quantities of the protein. Other approaches, even newer, bypass the
protein and build vaccines from the genetic instruction itself. This is
the case for Moderna and another Boston company, CureVac, both of which
are building Covid-19 vaccines out of messenger RNA.
Cepi’s original portfolio of four funded Covid-19 vaccine projects
was heavily skewed towards these more innovative technologies, and last
week it announced $4.4m (£3.4m) of partnership funding with Novavax and with a University of Oxford
vectored vaccine project. “Our experience with vaccine development is
that you can’t anticipate where you’re going to stumble,” says Hatchett,
meaning that diversity is key. And the stage where any approach is most
likely to stumble is clinical or human trials, which, for some of the
candidates, are about to get under way.
Clinical trials, an essential precursor to regulatory approval,
usually take place in three phases. The first, involving a few dozen
healthy volunteers, tests the vaccine for safety, monitoring for adverse
effects. The second, involving several hundred people, usually in a
part of the world affected by the disease, looks at how effective the
vaccine is, and the third does the same in several thousand people. But
there’s a high level of attrition as experimental vaccines pass through
these phases. “Not all horses that leave the starting gate will finish
the race,” says Bruce Gellin, who runs the global immunisation programme
for the Washington DC-based nonprofit, the Sabin Vaccine Institute.
Advertisement
There
are good reasons for that. Either the candidates are unsafe, or they’re
ineffective, or both. Screening out duds is essential, which is why
clinical trials can’t be skipped or hurried. Approval can be accelerated
if regulators have approved similar products before. The annual flu
vaccine, for example, is the product of a well-honed assembly line in
which only one or a few modules have to be updated each year. In
contrast, Sars-CoV-2 is a novel pathogen in humans, and many of the
technologies being used to build vaccines are relatively untested too.
No vaccine made from genetic material – RNA or DNA – has been approved
to date, for example. So the Covid-19 vaccine candidates have to be
treated as brand new vaccines, and as Gellin says: “While there is a
push to do things as fast as possible, it’s really important not to take
shortcuts.”
An illustration of that is a vaccine that was produced in the 1960s
against respiratory syncytial virus, a common virus that causes
cold-like symptoms in children. In clinical trials, this vaccine was
found to aggravate those symptoms in infants who went on to catch the
virus. A similar effect was observed in animals given an early
experimental Sars vaccine. It was later modified to eliminate that
problem but, now that it has been repurposed for Sars-CoV-2, it will
need to be put through especially stringent safety testing to rule out
the risk of enhanced disease.
It’s for these reasons that taking a vaccine candidate all the way to
regulatory approval typically takes a decade or more, and why President Trump sowed confusion
when, at a meeting at the White House on 2 March, he pressed for a
vaccine to be ready by the US elections in November – an impossible
deadline. “Like most vaccinologists, I don’t think this vaccine will be
ready before 18 months,” says Annelies Wilder-Smith, professor of
emerging infectious diseases at the London School of Hygiene and
Tropical Medicine. That’s already extremely fast, and it assumes there
will be no hitches.
Dr Fauci speaks to US President Donald Trump during a
tour of the National Institutes of Health. Photograph: Leah
Millis/Reuters
Advertisement
In
the meantime, there is another potential problem. As soon as a vaccine
is approved, it’s going to be needed in vast quantities – and many of
the organisations in the Covid-19 vaccine race simply don’t have the
necessary production capacity. Vaccine development is already a risky
affair, in business terms, because so few candidates get anywhere near
the clinic. Production facilities tend to be tailored to specific
vaccines, and scaling these up when you don’t yet know if your product
will succeed is not commercially feasible. Cepi and similar
organisations exist to shoulder some of the risk, keeping companies
incentivised to develop much-needed vaccines. Cepi plans to invest in
developing a Covid-19 vaccine and boosting manufacturing capacity in
parallel, and earlier this month it put out a call for $2bn to allow it
to do so.
Once a Covid-19 vaccine has been approved, a further set of
challenges will present itself. “Getting a vaccine that’s proven to be
safe and effective in humans takes one at best about a third of the way
to what’s needed for a global immunisation programme,” says global
health expert Jonathan Quick of Duke University in North Carolina, author of The End of Epidemics
(2018). “Virus biology and vaccines technology could be the limiting
factors, but politics and economics are far more likely to be the
barrier to immunisation.”
The problem is making sure the vaccine gets to all those who need it.
This is a challenge even within countries, and some have worked out
guidelines. In the scenario of a flu pandemic, for example, the UK would
prioritise vaccinating healthcare and social care workers, along with
those considered at highest medical risk – including children and
pregnant women – with the overall goal of keeping sickness and death
rates as low as possible. But in a pandemic, countries also have to
compete with each other for medicines.
Because pandemics tend to hit hardest those countries that have the
most fragile and underfunded healthcare systems, there is an inherent
imbalance between need and purchasing power when it comes to vaccines.
During the 2009 H1N1 flu pandemic, for example, vaccine supplies were
snapped up by nations that could afford them, leaving poorer ones short.
But you could also imagine a scenario where, say, India – a major
supplier of vaccines to the developing world – not unreasonably decides
to use its vaccine production to protect its own 1.3 billion-strong
population first, before exporting any.
2:10
How do I know if I have coronavirus and what happens next? – video explainer
Advertisement
Outside
of pandemics, the WHO brings governments, charitable foundations and
vaccine-makers together to agree an equitable global distribution
strategy, and organisations like Gavi, the vaccine alliance, have come
up with innovative funding mechanisms to raise money on the markets for
ensuring supply to poorer countries. But each pandemic is different, and
no country is bound by any arrangement the WHO proposes – leaving many
unknowns. As Seth Berkley, CEO of Gavi, points out: “The question is,
what will happen in a situation where you’ve got national emergencies
going on?”
This is being debated, but it will be a while before we see how it
plays out. The pandemic, says Wilder-Smith, “will probably have peaked
and declined before a vaccine is available”. A vaccine could still save
many lives, especially if the virus becomes endemic or perennially
circulating – like flu – and there are further, possibly seasonal,
outbreaks. But until then, our best hope is to contain the disease as
far as possible. To repeat the sage advice: wash your hands. • This article was amended on 19 March
2020. An earlier version incorrectly stated that the Sabin Vaccine
Institute was collaborating with the Coalition for Epidemic Preparedness
Innovations (Cepi) on a Covid-19 vaccine.
Since you’re here...
… we’re asking readers like you to make a
contribution in support of our open, independent journalism. In these
frightening and uncertain times, the expertise, scientific knowledge and
careful judgment in our reporting has never been so vital. No matter
how unpredictable the future feels, we will remain with you, delivering
high quality news so we can all make critical decisions about our lives,
health and security. Together we can find a way through this.
You’ve
read 5 articles in the last four months. We believe every one of us
deserves equal access to accurate news and calm explanation. So, unlike
many others, we made a different choice: to keep Guardian journalism
open for all, regardless of where they live or what they can afford to
pay. This would not be possible without the generosity of readers, who
now support our work from 180 countries around the world.
We
have upheld our editorial independence in the face of the
disintegration of traditional media – with social platforms giving rise
to misinformation, the seemingly unstoppable rise of big tech and
independent voices being squashed by commercial ownership. The
Guardian’s independence means we can set our own agenda and voice our
own opinions. Our journalism is free from commercial and political bias –
never influenced by billionaire owners or shareholders. This makes us
different. It means we can challenge the powerful without fear and give a
voice to those less heard.
Your financial support has
meant we can keep investigating, disentangling and interrogating. It has
protected our independence, which has never been so critical. We are so
grateful.
We need your support so we can keep delivering
quality journalism that’s open and independent. And that is here for the
long term. Every reader contribution, however big or small, is so
valuable. Support the Guardian from as little as $1 – and it only takes a minute. Thank you.
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