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Herd Immunity illustration: in a line of 10 people, we see how members of a society immunised or protected from a disease or infection (in blue) can act as a buffer between unprotected members (in red) and those vulnerable to infection (in green).

Herd immunity

When studying rates of infections, notably with measles, researchers have seen that in cases where a sufficiently large proportion of a population has been immunised or developed protection against a disease then infection rates also reduce in unprotected members of the population. In other words, the unprotected members appear to receive some indirect protection from the protected members of the population. This effect is known as herd immunity and is a tantalising goal for reducing the prevalence of epidemics.

While appealing in theory this article in Nature provides Five reasons why COVID herd immunity is probably impossible. These include:

Uncertainty around whether vaccinations prevent transmission. For example, herd immunity works when diseases can't be passed between protected members of a population to the unprotected. With COVID-19, vaccines seem to reduce symptoms but may still allow transmission.

It's also challenging to get vaccines evenly to all areas. These combined with complications brought by new variants, immunity fading before widespread vaccination is achieved, and people changing their behaviour — say, mixing more widely — once they've received some protection, means COVID-19 may be more likely to be something we live alongside rather than eradicate.

Also see: the Swiss cheese model

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