Early studies of weather, seasonality, and environmental influences on COVID-19 have yielded inconsistent and confusing results. To provide policy-makers and the public with meaningful and actionable environmentally-informed COVID-19 risk estimates, the research community must meet robust methodological and communication standards.
When COVID-19 began to spread, environmental scientists recognized that the world faced a dangerous upper respiratory viral disease that might exhibit sensitivity to seasonal weather conditions. Many of these scientists have sought to aid COVID-19 response by studying the potential to monitor, forecast, or project disease transmission rates or symptom severity as a function of climate zone, season, meteorological variability, air quality, and other environmental parameters1,2,3,4. The rapid pace of COVID-19 research has meant that studies on this topic appeared on pre-print servers and then on news and social media outlets faster than the information could be cross-checked and peer-reviewed. As many such studies accumulated, it became clear that reported evidence was often contradictory, and in some cases studies were being selected subjectively in a manner that seemed intended to support political agendas. Carlson et al.5 recently provided a cogent assessment of the policy-relevant challenges associated with studies that have attempted to quantify meteorological sensitivities of the virus and the disease. We appreciate this perspective. Here we argue that the research community must act to ensure that work on this topic meets its potential to contribute to pandemic understanding and response, and that fears of inappropriate data analysis or miscommunication do not dampen innovation or the effective use of research results.
Environmentally-informed disease risk monitoring and prediction has proven to be useful for numerous infectious diseases6, including viral upper respiratory infections7 like COVID-19. These disease risk forecasts have been applied to vaccination strategies8 and have demonstrated value for informing deployment of non-pharmaceutical preventative measures and treatments9,10. In the case of COVID-19, environmentally-informed analysis has already revealed associations between chronic air pollution exposure and the health impacts of the disease11. The veracity of forecasts of COVID-19 incidence based on seasonality or other meteorological factors, however, continues to be in dispute, and the creation of robust disease risk forecast systems has been limited by data challenges12 and the dominance of or interplay with other drivers and pressures in the early phases of a respiratory disease epidemic13. If and when more consistent and meaningful climatic and environmental sensitivities are identified, such disease forecasts have the potential to help policy makers and public health officials target interventions in a way that optimizes effectiveness while minimizing their social and economic burden. Seasonally-informed physical distancing, other personal protection policies, and climate-informed vaccination strategies, for example, could make meaningful contributions to COVID-19 control, if the evidence that underlies science-based recommendations is robust and credible.
To realize this potential, however, pitfalls of miscommunication, use of unsuitable data and methods, and misrepresentation of results must be carefully guarded against. The interdisciplinary research and operational forecasting communities can do this by adopting a set of good practices for publishing, publicizing, and operationalizing their work. Recognizing this need, the World Meteorological Organization (WMO) convened an international virtual symposium on Climatological, Meteorological and Environmental factors in the COVID-19 pandemic, held 4–6 August 2020. The symposium engaged over 400 participants from 72 countries to assess and review current understanding, forecasting, and communication challenges related to climatic, meteorological and environmental influences on SARS-CoV-2 and COVID-19. The outcomes statement of this symposium14 offers pragmatic recommendations to the research and practitioner communities when pursuing their research and preparing it for scientific review or public consumption. These recommendations complement those directed at policy makers5. To build on the symposium, the WMO Research Board has established a Task Team on COVID-19 and Climatic, Meteorological, and Environmental Factors that is tasked with producing regular scientific assessments of the literature and formalizing recommendations on good practice for studies and creation of operational disease risk forecasting products that address these issues. This internationally coordinated effort is intended to promote constructive interdisciplinary collaboration and communication among researchers and decision makers.
A particularly strong message emerged from the symposium is that “studies should attempt to meet a minimum standard of good practice in data use and methods for integrated models, including: the need to account for relevant non-environmental predictors; to justify the data quality and relevance of the selected response variable; to be clear about the epidemic phase being tested (including time lags); to spatially and temporally align epidemiological and climate, meteorological and environmental data; and to distinguish between analyses that are suited to describe observed relationships and those that have been confirmed to provide skillful prediction and forecast”14. Symposium participants also emphasized that predictive studies must address the strength of mechanistic and dynamical understanding that underpins their empirical results. Ensuring that published studies have met these good practices will help to prevent many of the more egregious cases of overinterpretation or misinterpretation like those seen in the early stages of the pandemic, and will enhance the research community’s progress towards reliable and actionable results.
Robust research design and execution must, however, be accompanied by a culture of responsible publication and communication of results (Fig. 1). The very energy and civic-mindedness that has led so many from disparate disciplines to engage in the challenge of environmentally-informed COVID-19 disease risk prediction, has, at times, led to premature sharing of preliminary and sometimes unjustified results. The current scientific culture of releasing time-sensitive results on journal pre-print servers prior to peer review has resulted in a relaxation of the traditional self-regulation that research communities place on dissemination of results. The appearance of these unvetted studies online is often interpreted by journalists and the lay public, which is eager for certainty, as implying that they bear verified results. This presents a challenge to the COVID-19 research community, where a tension exists between the urgency to produce and publicize conclusive knowledge with the time and care needed for its authentication. While rapid communication of results, facilitated by journal pre-print publication, can accelerate the acquisition of knowledge and reduce redundancy, therefore allowing for faster progress on a critical research topic, pre-review release of studies can also mislead the public in the short term and threaten scientific credibility with decision makers in the medium and long term.
To balance opportunity with risk, journal and community pre-print servers should require a public synopsis, additional to the paper’s abstract, that states the study’s context in the literature—i.e., key contribution and agreement or disagreement with other studies, data sources, methodological approach and limitations, and proposed policy implications, if any. This would allow authors to clarify several common points of misinterpretation, such as whether a study is designed for prediction, how potentially confounding variables have been considered in the analysis, whether a model’s output is intended to be a specific forecast or a scenario-based projection, or if a statistically significant result (e.g., COVID-19 transmission sensitivity to temperature) is large or small relative to other risk factors.
In addition, researchers should embrace their role as representatives of the broader research community when communicating or operationalizing research results. This includes informing media outlets or policy makers of dissenting views and encouraging the presence of multiple voices in coverage of their work. It also includes clear presentation of uncertainties and alternative hypotheses in any publicly disseminated risk assessment or forecast—a practice that is well-established in climate and environmental change research. Such measures are good practice under any conditions, but researchers often leave the effort to others in the information chain, rather than viewing it as their own responsibility. In the rapidly evolving, multi-disciplinary, and potentially high stakes arena of COVID-19 forecasts, this is an avoided responsibility that the research community cannot afford. Through nimble but careful research and communication, it is possible to strike a balance between the rapid response research that the COVID-19 crisis demands and the need for careful review and communication of results likely to inform policy.
Smit, A. J. et al. Winter is coming: a southern hemisphere perspective of the environmental drivers of SARS-CoV-2 and the potential seasonality of COVID-19. Int. J. Environ. Res. Public Health 17, 5634 (2020).
Briz-Redón, Á. & Serrano-Aroca, Á. The effect of climate on the spread of the COVID-19 pandemic: a review of findings, and statistical and modelling techniques. Prog. Phys. Geogr. https://doi.org/10.1177/0309133320946302 (2020).
Pun, M., Turner, R., Strapazzon, G., Brugger, H. & Swenson, E. R. Lower incidence of Covid-19 at high altitude: facts and confounders. High Altitude Med. Biol. 21, 217–222 (2020).
Zhu, Y., Xie, J., Huang, F. & Cao, L. The mediating effect of air quality on the association between human mobility and COVID-19 infection in China. Environ. Res. 189, 109911 (2020).
Carlson, C. J., Gomez, A. C., Bansal, S. & Ryan, S. J. Misconceptions about weather and seasonality must not misguide COVID-19 response. Nat. Commun. 11, 4312 (2020).
Thomson, M. C., Muñoz, Á. G., Cousin, R. & Shumake-Guillemot, J. Climate drivers of vector-borne diseases in Africa and their relevance to control programmes. Infect. Dis. Poverty 7, 81 (2018).
Reich, N. G. et al. A collaborative multiyear, multimodel assessment of seasonal influenza forecasting in the United States. Proc. Natl Acad. Sci. USA 116, 3146–3154 (2019).
Thomson, M. C. et al. A climate and health partnership to inform the prevention and control of meningoccocal meningitis in sub-Saharan Africa: the MERIT initiative. In Climate Science for Serving Society (eds Asrar, G. & Hurrell, J.) (Springer, 2013).
Lowe, R. et al. Evaluating probabilistic dengue risk forecasts from a prototype early warning system for Brazil. Elife 5, e11285 (2020).
Reyburn, R. et al. Climate variability and the outbreaks of cholera in Zanzibar, East Africa: a time series analysis. Am. J. Tropical Med. Hygiene 84, 862–869 (2011).
Fattorini, D. & Regoli, F. Role of the chronic air pollution levels in the Covid-19 outbreak risk in Italy. Environ. Pollut. 264, 114732 (2020).
Gardner, L., Ratcliff, J., Dong, E. & Katz, A. A need for open public data standards and sharing in light of COVID-19. Lancet Infect. Dis. https://doi.org/10.1016/S1473-3099(20)30635-6 (2020).
Baker, R. E., Yang, W., Vecchi, G. A., Metcalf, C. J. E. & Grenfell, B. T. Susceptible supply limits the role of climate in the early SARS-CoV-2 pandemic. Science 369, 315–319, https://doi.org/10.1126/science.abc2535 (2020).
Outcome Statement. Virtual Symposium on Climatological, Meteorological and Environmental (CME) Factors in the COVID-19 Pandemic. 4–6 August 2020. https://public.wmo.int/en/events/meetings/covid-19-symposium/outcomes (2020).
The authors acknowledge the World Meteorological Organization for convening the symposium referenced in this comment, the American Geophysical Union for providing logistical support for the symposium, and the U.S. National Oceanic and Atmospheric Administration for funding the symposium meeting platform.
The authors declare no competing interests.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Zaitchik, B.F., Sweijd, N., Shumake-Guillemot, J. et al. A framework for research linking weather, climate and COVID-19. Nat Commun 11, 5730 (2020). https://doi.org/10.1038/s41467-020-19546-7
This article is cited by
Understanding the COVID-19 pandemic prevalence in Africa through optimal feature selection and clustering: evidence from a statistical perspective
Environment, Development and Sustainability (2023)
Indirect Response of the Temperature, Humidity, and Rainfall on the Spread of COVID-19 over the Indian Monsoon Region
Pure and Applied Geophysics (2023)
Lagged meteorological impacts on COVID-19 incidence among high-risk counties in the United States—a spatiotemporal analysis
Journal of Exposure Science & Environmental Epidemiology (2022)
Pandemic wave trends in COVID-19 cases, mobility reduction, and climate parameters in major metropolitan areas in the United States
Environment Systems and Decisions (2022)
Cold and dry winter conditions are associated with greater SARS-CoV-2 transmission at regional level in western countries during the first epidemic wave
Scientific Reports (2021)