#19,011
Long-time readers are aware of my limited grasp of statistics, and probably suspect I'll drown someday trying to ford a stream that is - on average - 2 feet deep. Which is why I won't even try to dissect the advanced methods used in today's study from Columbia University's Mailman School of Public Health.
But their findings; that early cryptic spread of pandemic viruses are hard to predict - even when viewed in retrospect - is worthy of deeper discussion.
First, in broad strokes, a brief summary from the press release.
News Release 5-Jan-2026
Study examines how the last two respiratory pandemics rapidly spread through cities
Peer-Reviewed Publication
Columbia University's Mailman School of Public Health
The researchers set out understand the geographic spread of the two pandemics to inform strategies to prevent future pandemics. They applied detailed data on the dynamics of the two infectious diseases to a computer model to simulate their spread using known patterns of air travel and commuting, as well as potential superspreading events. They focused on over three hundred metropolitan areas in the U.S.
In the simulations, both pandemics were widely circulating in most of the metro areas within weeks, before government interventions or early case detection. While the specific transmission pathways across locations were different for the last two pandemics, the spatial expansion was driven by several shared transmission hubs such as the New York and Atlanta metropolitan areas. Their spread was largely driven by air travel rather than commuting, though random dynamics introduced substantial uncertainty in transmission routes, which makes it hard to predict where the outbreaks will happen in real time.
(SNIP)
Beyond reconstructing the historical spread of the last two pandemics, the study also provides a generalizable framework to infer early epidemic dynamics that may be applied to other pathogens. While mobility, particularly air travel, is a key driver of pandemic spread, the researchers caution that other factors also play a role, including community demographics, school schedules, winter holidays, and weather conditions.
A link, and some excerpts from the full study, after which we'll look at some of the real-life implications.
Reconstructing the early spatial spread of pandemic respiratory viruses in the United States
Renquan Zhang, Rui Deng, Sitong Liu , +4 , and Sen Pei
January 6, 2026
https://doi.org/10.1073/pnas.2518051123
Vol. 123 | No. 2
Abstract
Understanding the geographic spread of emerging respiratory viruses is critical for pandemic preparedness, yet the early spatiotemporal dynamics of the 2009 H1N1 pandemic influenza and severe acute respiratory syndrome coronavirus 2 in the United States remain unclear.
While mobility and genomic data have revealed important aspects of pandemic spatial spread, several key questions remain: Did the two pandemics follow similar spatial transmission routes? How rapidly did they spread across the United States? What role did stochastic processes play in early spatial transmission?
To address these questions, we integrated high-resolution disease data with a robust, data-efficient inference framework combining air travel, commuting flows, and pathogen superspreading potentials to reconstruct their spatial spread across US metropolitan areas.
The two pandemics exhibited distinct transmission pathways across locations; however, both pandemics established local circulation in most metropolitan areas within weeks, driven by several shared transmission hubs. Early spatial spread was more strongly associated with air travel than with commuting, though stochastic dynamics introduced substantial uncertainty in transmission routes, creating challenges for timely detection and control.Simulations indicate that broad wastewater surveillance coverage beyond top transmission hubs coupled with effective infection control may slow initial spatial expansion. Our findings highlight the rapid, stochastic spread of pandemic respiratory pathogens and the difficulties of early outbreak containment.
For those who are as statistically challenged as am I; `stochastic' is just a fancy word for "random" or "probabilistic". We often talk about the R0 (r-naught) of a virus - how many people one person is likely to infect - but that's just an average.
Some people may get sick, wisely stay home, and infect no one else. Others may mask their symptoms with OTC cold/flu meds and fly to a convention; becoming a superspreader that infects dozens.
Individual choices - both good and bad - can affect how quickly a pandemic spreads. As can many external factors, like the weather, holidays, community demographics, and school closures.
And of course, not all viral threats are created equal.
The SARS-COV virus of 2022-2023 famously did not spread asymptomatically, which made quarantine of symptomatic individuals effective (see SARS and Remembrance), making containment possible.
H1N1 and COVID, however, could be spread asymptomatically and via aerosols, and that made them virtually unstoppable.
The reality is, it doesn't take a super virus to spread uncontrollably. Even a (relatively) mild H1N1 virus swept the world in 2009, and supplanted the old H1N1 virus, all in a matter of weeks.
While many countries implemented border closings, passenger screenings, and airport thermal scanners to try stop H1N1 and COVID; at best they only delayed entry by a matter of days or weeks.
Most viruses take days - up to a week or longer - to incubate. And with 7 million airline passengers each day, any attempts to identify and isolate infected passengers are probably doomed from the start.
Today's study is a reminder that once a respiratory pandemic virus is transmitting efficiently in the community, our ability to stop it is laughably small.
The authors of today's study do suggest airport wastewater surveillance at key transmission hubs (testing sewage from aircraft, airport terminals, and related infrastructure) would be a cost effective early warning system.
This would not only pick up asymptomatic carriers, or tell us where to deploy medical assets, it might even alert us to emerging threats before they become fully transmissible.
As much merit as that idea has - given our current level of pandemic denial, and unwillingness to test and share data - I'm not particularly hopeful.
