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Published VersionCC BY V4.0, Open Access
Journal article
Future-proofing cities against negative city mobility and public health impacts of impending natural hazards: a system dynamics modelling study
The Lancet. Planetary health, Vol.9(3), pp.e207-e218
2025
PMID: 40120627
Abstract
Background
The world faces increasing risk from more frequent and larger scale natural hazards, including infectious disease outbreaks (IDOs) and climate change-related extreme weather events (EWEs). These natural hazards are expected to have adverse mobility and public health impacts, with people living in cities especially vulnerable. Little is known about how transport systems can be optimally designed to make cities more resilient to these hazards. Our aim was to investigate how cities’ transport systems, and their resulting mobility patterns, affect their capabilities to mitigate mobility and health impacts of future large-scale IDOs and EWEs.
Methods
System dynamics modelling was used to investigate how different city mobility scenarios can affect the health and mobility impacts of four plausible future IDO and EWE (flooding) shocks in three cities: Belfast, UK; Belo Horizonte, Brazil; and Delhi, India. Three city mobility scenarios with incremental degrees of modal shift towards active travel (private motor vehicle volume reduced to 50% and 20% of total road trip volume in vision 1 and 2, and motor vehicle volume [including buses] reduced to 20% of total road trip volume in vision 3) were tested. For each city and each IDO and EWE shock, we estimated the percentage of deaths prevented in visions 1, 2, and 3, relative to the reference scenario, as well as changes in mode share over time.
Findings
In all scenarios, all cities showed reduced susceptibility to flooding, with 4–50% of deaths potentially prevented, depending on case city, city mobility, and EWE scenario. The more ambitious the transition towards healthier city mobility patterns, the greater the resilience against flooding. Only vision 3 (the most ambitious transition) showed reduced vulnerability to IDOs, with 6–19% of deaths potentially prevented. Evolution of mode shares varied greatly across cities and mobility scenarios under the IDO shocks.
Interpretation
Our results emphasise the importance of well designed, forward-thinking urban transport systems that make cities more resilient and reduce the impact of future public health-related and climate-related threats.
Details
- Title
- Future-proofing cities against negative city mobility and public health impacts of impending natural hazards: a system dynamics modelling study
- Authors
- Leandro Garcia (Corresponding Author) - Queens UniversityMehdi Hafezi - Cranfield UniversityLarissa Lima - Queens UniversityChristopher Millett - Imperial College LondonJason Thompson - The University of MelbourneRuoyu Wang - Queen's University BelfastSelin Akaraci - Queen's University BelfastRahul Goel - Indian Institute of Technology DelhiRodrigo Reis - Washington University in St. LouisKerry A. Nice - The University of MelbourneBelen Zapata-Diomedi - RMIT UniversityPedro C. Hallal - University of Illinois Urbana-ChampaignEsteban Moro - Universidad Carlos III de MadridClifford Amoako - Kwame Nkrumah University of Science and TechnologyRuth F. Hunter - Queen's University Belfast
- Publication details
- The Lancet. Planetary health, Vol.9(3), pp.e207-e218
- Publisher
- The Lancet Publishing Group
- Date published
- 2025
- DOI
- 10.1016/S2542-5196(25)00026-9
- ISSN
- 2542-5196
- PMID
- 40120627
- Copyright note
- © 2025 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY 4.0 license.
- Grants
- Grant note
- UK Prevention Research Partnership, UK Economic and Social Research Council, UK Medical Research Council, UK National Institute for Health and Care Research, and Health and Social Care Research and Development Office Northern Ireland.
- Organisation Unit
- Centre for Human Factors and Systems Science
- Language
- English
- Record Identifier
- 991184299502621
- Output Type
- Journal article
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