COVID-19 risks may shift from older adults to younger children as the SARS-CoV-2 virus becomes endemic, according to new modeling results.
Within the next few years, as the SARS-CoV-2 virus becomes endemic in the global population, COVID-19 may behave like other common-cold coronaviruses, affecting mostly young children who have not yet been vaccinated or exposed to the virus, according to new modeling results. Because COVID-19 severity is generally lower among children, the overall burden from this disease is expected to decline.
“Following infection by SARS-CoV-2, there has been a clear signature of increasingly severe outcomes and fatality with age,” said Ottar Bjornstad. “Yet, our modeling results suggest that the risk of infection will likely shift to younger children as the adult community becomes immune either through vaccination or exposure to the virus.”
Bjornstad explained that such shifts have been observed in other coronaviruses and influenza viruses as they have emerged and then become endemic.
Historical Lessons from Past Pandemics
“Historical records of respiratory diseases indicate that age-incidence patterns during virgin epidemics can be very different from endemic circulation,” he said. “For example, ongoing genomic work suggests that the 1889-1890 pandemic, sometimes known as the Asiatic or Russian flu — which killed one million people, primarily adults over age 70 — may have been caused by the emergence of HCoV-OC43 virus, which is now an endemic, mild, repeat-infecting cold virus affecting mostly children ages 7-12 months old.”
Bjornstad cautioned, however, that if immunity to reinfection by SARS-CoV-2 wanes among adults, disease burden could remain high in that group, although previous exposure to the virus would lessen the severity of disease.
“Empirical evidence from seasonal coronaviruses indicates that prior exposure may only confer short-term immunity to reinfection, allowing recurrent outbreaks, this prior exposure may prime the immune system to provide some protection against severe disease,” said Bjornstad. “However, research on COVID-19 shows that vaccination provides stronger protection than exposure to the SARS-CoV-2 virus, so we encourage everyone to get vaccinated as soon as possible.”
The U.S.-Norwegian team developed what is known as a “realistic age-structured (RAS) mathematical model” that integrates demography, degree of social mixing, and duration of infection-blocking and disease-reducing immunity to examine potential future scenarios for age-incidence and burden of mortality for COVID-19.
Specifically, the researchers examined disease burden over immediate, medium and long terms — 1, 10 and 20 years, respectively. They also examined disease burden for 11 different countries — including China, Japan, South Korea, Europe, Spain, United Kingdom, France, Germany, Italy, United States, Brazil and South Africa — that differed widely in their demographics. They used data from the United Nations for each of these countries to parameterize the model.
“Regardless of immunity and mixing, the population-level burden of mortality may differ among countries because of varying demographics,” said Ruiyun Li, postdoctoral fellow, University of Oslo. “Our general model framework allows for robust predictions of age-dependent risk in the face of either short or long-term protective immunity, reduction of severity of disease given previous exposure, and consideration of the range of countries with their different demographics and social mixing patterns.”
According to Li, social distancing is well documented to affect transmissibility, and many countries implemented interventions, such as “shelter in place,” during the build-up of the virgin COVID-19 epidemic. Therefore, the team’s model assumes that the reproduction number (R0) — or the level of transmissibility — on any given day is linked to the amount of mobility on that day. The model also incorporates a variety of scenarios for immunity, including both independence and dependence of disease severity on prior exposure, as well as short- (either three months or one year) and long-term (either 10 years or permanent) immunity.
The team’s results were published on August 11, 2021, in the journal Science Advances.
Predictions of Long-Term Endemic Patterns
“For many infectious respiratory diseases, prevalence in the population surges during a virgin epidemic but then recedes in a diminishing wave pattern as the spread of the infection unfolds over time toward an endemic equilibrium,” said Li. “Depending on immunity and demography, our RAS model supports this observed trajectory; it predicts a strikingly different age-structure at the start of the COVID-19 epidemic compared to the eventual endemic situation. In a scenario of long-lasting immunity, either permanent or at least 10 years, the young are predicted to have the highest rates of infection as older individuals are protected from new infections by prior infection.”
Jessica Metcalf, associate professor of ecology, evolutionary biology, and public affairs, Princeton University, noted that this prediction is likely to hold only if reinfections produce only mild disease. However, she said, the burden of mortality over time may remain unchanged if primary infections do not prevent reinfections or mitigate severe disease among the elderly.
“In this bleakest scenario, excess deaths due to continual severe reinfections that result from waning immunity will continue until more effective pharmaceutical tools are available,” she said.
Interestingly, due to variations in demographics, the model predicts different outcomes for different countries.
“Given the marked increase of the infection-fatality ratio with age, countries with older population structures would be expected to have a larger fraction of deaths than those with relatively younger population structures,” said Nils Chr. Stenseth, professor of ecology and evolution, University of Oslo. “Consistent with this, for example, South Africa — likely due, in part, to its younger population structure — has a lower number of deaths compared to older populations such as Italy. We found that such ‘death disparities’ are heavily influenced by demographics. However, regardless of demographics, we predict a consistent shift of the risk to the young.”
The researchers said that they designed their model so that health authorities will have a powerful and flexible tool to examine future age-circulation of COVID-19 for use in strengthening preparedness and deployment of interventions.
Bjornstad said, “The mathematical framework we built is flexible and can help in tailoring mitigation strategies for countries worldwide with varying demographics and social mixing patterns, thus providing a critical tool for policy decision making.”
Reference: “A general model for the demographic signatures of the transition from pandemic emergence to endemicity” by Ruiyun Li, C. Jessica E. Metcalf, Nils Chr. Stenseth and Ottar N. Bjørnstad, 11 August 2021, Science Advances.
DOI: 10.1126/sciadv.abf9040
The Huck Institute of the Life Sciences at Penn State and the Research Council of Norway supported this research.
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3 Comments
It sounds to me that what really happens is the longer the virus circulates through the population, the higher the proportion of people who were exposed to it at really young ages where their immune systems are the strongest, and then through repeated exposures they continue to have at least some protection from the virus.
In other words, even the common cold virus probably killed a lot of adults when it first started infecting humans because the adult immune systems had never experienced the virus. Over time more people experience mild illnesses as children and it becomes a “regular” common virus.
This article takes a very optimistic view, putting all the SARS-CoV-2 varieties together. But we’ve seen how more infectious the Delta variant is, infecting everyone.
All the variants have different spike proteins, with Delta having one that’s more efficient at getting around the vaccines. But the real problem is in the virus and why two of the most dangerous, MERS and Covid-19, are so infectious. My independent research has found multiple one-in-a-million nucleotide sequence matches between all the coronaviruses and the human genome. Those sequences are the same as some of the DHU loops of human tRNA. Using those loops and their anticodon matches, viruses may be able to fool the nucleus membrane in cells to allow the virus to enter and associate with the human DNA, creating more opportunities for further infection. Our immune system may be compromised and may no longer be able to stop the virus and other diseases from attacking organs throughout the body. Vaccines that attack the virus protein shells while ignoring their contents are doomed to failure from the Darwin effect, but recognizing these DHU loops suggests a possible approach to successful coronavirus vaccines. For MERS, eliminating the nucleotide sequence CAGTGGTAG from the virus may make it less infectious and stimulate the body to create antibodies to attack the entire virus. And eliminating the nucleotide sequence TAGTGGTGAG from Covid-19 may do the same thing. Only the infection process is considered in my work, not the innate virulence of the virus. For more info, check out this YouTube, Coronavirus – Using Your DNA Against You. https://www.youtube.com/watch?v=pd4OD4GpsJI
It seems obvious that evolutionary pressure on any virus is to maximize transmissibility and minimize overall morbidity and mortality of the host.
Eventually, the host and the virus both adapt to each other to maxmimize the overall number of both hosts and virus particles.
Although the delta variant is more contagious it causes less serious disease, statistically. The trend is apparent.