Jonathan Pugh, University of Oxford and Julian Savulescu, University of Oxford
Regulators in Europe are at odds over whether the Oxford/AstraZeneca vaccine should be given to the elderly. In the UK, the vaccine has been approved for use in adults aged 18 and up, but France, Germany, Sweden and Austria say the vaccine should be prioritised for those under the age of 65. Poland only recommends it for those younger than 60. Italy goes one step further and only recommends it for those 55 and younger.
It is only ethical to approve a vaccine if it is safe and effective. Crucially, the reluctance to approve the AstraZeneca vaccine in the elderly is grounded only in concerns about its efficacy.
The concern is not that there is data showing the vaccine to be ineffective in the elderly, it’s that there is not enough evidence to show that it is effective in this age group. The challenge is in how we manage the degree of uncertainty in the efficacy of the vaccine, given the available evidence.
So how much data is there? The interim results from the AstraZeneca vaccine study pooled data from over 11,000 participants who received two doses of either the AstraZeneca vaccine or a placebo. A further report shows that only 660 participants were aged over 65, and there were only two cases of COVID in this group. Because of the low numbers, the authors of the study conclude that the efficacy of the vaccine in the elderly could not be determined. In comparison, the published Pfizer vaccine study included nearly 38,000 participants; around 16,000 of them were aged over 55.
There is also data about the extent to which the AstraZeneca vaccine generates an immune response. A study analysed whether the vaccine provoked an immune response in 560 participants, including 400 participants over the age of 55. Early phase human trials found that the vaccine elicited a similar immune response across all age groups after the second dose. Although this isn’t proof that the vaccine prevents symptomatic disease, it suggests that the vaccine has an important effect in the elderly.
An ethical rather than scientific disagreement
The disagreement about whether to recommend the vaccine for the elderly concerns an ethical rather than a scientific question, namely, what standard of evidence do we need to establish the efficacy of a vaccine before approving it for use in a pandemic?
The more evidence available, the greater the certainty that regulators can have that a vaccine works, and about which distribution strategies will maximise its public health benefit. But gathering evidence takes time. The higher the standard, the greater the delay before people can access the intervention. In the pandemic, this trade-off is particularly acute. Time here is lives.
Consider the following rough calculations based on publicly available statistics. According to data from the Office for National Statistics, from November 28 2020 to January 1 2021, there were 14,633 COVID-related deaths in the UK. Only 1,351 of those deaths were in the 20-64 age group; 13,280 were in people over 65.
Imagine that the UK had been able to fully vaccinate all of those between the ages of 20-64 before November 28 2020 with a vaccine that was 95% effective. Assume that preventing infection with coronavirus would have been enough to avoid all of the above deaths. On this assumption, the vaccine could have been expected to prevent 1,283 of the deaths that occurred in the 20-64 age band.
Suppose now that we could also have vaccinated all of those over the age of 65 with this vaccine, but that there was limited data about how effective it would be in the elderly. Here is the crucial point: for it to save a same number of lives (1,283) in those over 65, the vaccine would need to be just shy of 10% effective, given the far higher mortality in the elderly.
This is generously assuming that the vaccine is very effective below the age of 65. If the vaccine was 70% effective in the 20-64 age band, then it would need to be only 7.1% effective in the elderly to be expected to save an equivalent number of lives (946 in this case).
Here’s another example. A recent study suggests the average risk of death for 60- to 64-year-olds infected with coronavirus is 0.46%. For a person aged 80 or older, the risk is 8.3%. Again, assume generously that a vaccine is 95% effective in 60- to 64-year-olds. That means for every 1,000 people vaccinated in this group who would have become infected, the vaccine would save 4.3 lives. How effective would a vaccine need to be in those aged 80 and older to still save the same number of lives? 5.2%.
We are not suggesting that the effectiveness of the AstraZeneca vaccine in the elderly is this low, nor that regulators should approve a vaccine as ineffective as this imaginary one. The World Health Organization has stipulated a minimum efficacy of 50% for COVID-19 vaccines. But these examples show how important it is to consider the limitations of efficacy (or its evidence) with the actual mortality risk faced by people in the absence of a vaccine.
A vaccine with limited effectiveness is problematic if it stops people accessing other effective available interventions. However, other vaccine supplies are currently scarce, and their evaluation in the elderly is also ongoing. Meanwhile, those over the age of 65 face an exponentially increasing risk of death. In the absence of other effective prophylactic interventions, a vaccine can have far lower efficacy in older groups and still be expected to save many lives.
Jonathan Pugh, Research Fellow, University of Oxford and Julian Savulescu, Visiting Professor in Biomedical Ethics, Murdoch Children’s Research Institute; Distinguished Visiting Professor in Law, University of Melbourne; Uehiro Chair in Practical Ethics, University of Oxford
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Does anyone consider it a co-incidence that the two mutant strains came from the OxfordAZ test sites in South Africa and Brasil?
You mean that because South Africa and Brazil were chosen for their high populations and high infection rates – factors that made them perfect areas for variant strains to develop that this means that the Astrazeneca vaccine definitively caused them? Ooh not sure on that one – wait while I put my tinfoil hat on then I’ll have a think about it.
Deletions are the key to covid19 mutations. This Science Daily article reports research from Pittsburg University by Paul Duprex and colleagues which shows why deletions are the most likely sort of covid19 mutation to occur. That’s because even a coronavirus has a gene “proof-reader” that corrects mutations during replication. However a deletion can’t be repaired, there’s nothing to replace.
https://www.sciencedaily.com/releases/2021/02/210203144533.htm
Of course, randomly snipping off a part of the covid19 genome most of the time will render the virus dysfunctional and it will fail to replicate and spread. A dead end. But here and there in the genome there are short bits of RNA whose removal does not impair the virus’ vitality. Some may even enhance it. Such survivable deletions include ones that change the virus’ spike proteins, evading the immune response and – in some cases – the effectiveness of vaccines.
There are a limited number of such survivable and advantageous deletions in the viral genome and this is why the mutant strains emerging, from southern England, Brazil and South Africa for instance, are similar to each other sometimes involving the same deletion.
Finally another factor driving evolution of resistant covid19 strains is the severity of the infection in many patients and the length of time the person is sick with the virus. For weeks or even months. This gives time for the “cat and mouse” game between immune system and virus out of which successful mutant strains can arise. That could be bad news if severity of the infection carries survival advantage for the virus.
A poor analysis that assumes one life lost at age 90 is the same as one lost at age 30. Years of expected life lost would be the better measure, and that would alter the balance significantly.
There is talk here in Aus that a COVID vaccination certificate, digital (HA HA HA HA HA) or otherwise, will be required for travel within the country and internationally. Does not apply if you play sports.
Papieren bitte!
With the emergency “heath guidelines” being activated here, police (Aus and the UK) seem to think they are above the law.
And still, most health authorities do not recommend vitamin D supplements. The scientific proof is obviously not good enough!
I am having a problem with the efficiacy mathemathics…
Say (Moderna, was it?) 15000 guinea pigs each “vaccine” and placebo yielding 5 and 95 cases of Covid-19.
With a test number of 100, that would yield 5 and 95% efficiacy and relative efficiacy of (1-5/95)*100=94,7%.
With a test number of 10.000 and 5/95 cases of Covid-19, that would yield 99.95 and 99.05% for a relative efficiacy of (1-5/95)*100%=94.7%.
With a test number of 10.000 and 500/9500 cases of Covid-19, that would yield 5 and 95% efficiacy and a relative efficiacy of 94.7%.
With 5/95 cases out of 100 cases or 500/9500 cases out of 10.000 guinea pigs, vaccine looks like a nobrainer. With 5/95 cases out of 15.000 guinea pigs…
The effect of vaccine and placebo is approximate identical (14995/15000*100%=99.97, 14905/15000*100%=99.37) )and the difference in efficiacy is 14995/15000*100%-14905/15000*100%=0.6%
Meaning “vaccine” is as effective as placebo (or vice versa). Leading to the conclusion it is a nobrainer to NOT vaccinate.
Someone smarter than me do me a favor and qualify the mathematics and logic, please.
Oddgeir