Global hotspots and correlates of emerging zoonotic diseases

Allen, Talli; Murray, Kris A.; Zambrana‐Torrelio, Carlos; Morse, Stephen S.; Rondinini, Carlo; Marco, Moreno Di; Breit, Nathan; Olival, Kevin J.

doi:10.1038/s41467-017-00923-8

Cited by 826 publications

(832 citation statements)

References 62 publications

Supporting

Mentioning

784

Contrasting

Unclassified

Order By: Relevance

“…The use of outbreak data to model disease distributions raises methodological issues. Disease data are generally aggregated at coarse politicoadministrative levels (e.g., province, country), losing crucial information on the local natural history of the disease [1,33]. Additionally, the geographic site of infection and the associated uncertainty are generally not reported and may instead refer to the health-care facility where it is diagnosed [1], potentially misleading the identification of ecological conditions favoring disease occurrence.…”

Section: Traditional Enm Framework Limitations For Disease Systemsmentioning

confidence: 99%

“…Approximately 60% of emerging human diseases are caused by pathogenic parasites of animal origin (zoonoses), particularly wildlife [6]. As human activities intensify, contact with wildlife and exposure to novel parasites increase, potentially driving zoonotic disease emergence [1,7]. Given the threat that EIDs pose to human populations, understanding the underlying drivers of parasite geographic distribution and their spillover to humans is particularly relevant for epidemiologists, public-health practitioners, and policy makers [9].Ecological niche modeling (ENM) has proven useful to forecast the distribution of a vast number of organisms [10-13] and is increasingly employed to predict parasite distributions locally and globally [14][15][16][17].…”

mentioning

confidence: 99%

See 1 more Smart Citation

An Ecological Framework for Modeling the Geography of Disease Transmission

Johnson

Escobar

Zambrana‐Torrelio

2019

Trends in Ecology & Evolution

Self Cite

110

View full text Add to dashboard Cite

Ecological niche modeling (ENM) is widely employed in ecology to predict species' potential geographic distributions in relation to their environmental constraints and is rapidly becoming the gold-standard method for disease risk mapping. However, given the biological complexity of disease systems, the traditional ENM framework requires reevaluation. We provide an overview of the application of ENM to disease systems and propose a theoretical framework based on the biological properties of both hosts and parasites to produce reliable outputs resembling disease system distributions. Additionally, we discuss the differences between biological considerations when implementing ENM for distributional ecology and epidemiology. This new framework will help the field of disease ecology and applications of biogeography in the epidemiology of infectious diseases. Challenges and Opportunities to Map Disease RiskThe recent rise of emerging infectious diseases (EIDs) (see Glossary) [1] has increased the burden of infectious diseases and negatively impacted the global economy [2][3][4][5]. Approximately 60% of emerging human diseases are caused by pathogenic parasites of animal origin (zoonoses), particularly wildlife [6]. As human activities intensify, contact with wildlife and exposure to novel parasites increase, potentially driving zoonotic disease emergence [1,7]. Given the threat that EIDs pose to human populations, understanding the underlying drivers of parasite geographic distribution and their spillover to humans is particularly relevant for epidemiologists, public-health practitioners, and policy makers [9].Ecological niche modeling (ENM) has proven useful to forecast the distribution of a vast number of organisms [10-13] and is increasingly employed to predict parasite distributions locally and globally [14][15][16][17]. Despite great strides made in the implementation of ENM to forecast complex biological phenomena such as disease systems [18], traditional frameworks may render biologically unrealistic predictions and thus must be revised, as we show in this review. We provide an overview of the current state of disease ENM and propose a framework based on the biological properties of both parasites and hosts to produce reliable outputs resembling disease systems distributions. Specifically, our theoretical framework: (i) addresses the selection of an appropriate modeling approach and highlights the importance of including biologically sound predictor variables; (ii) proposes the concept of a microscale parasitic niche defined by host traits to identify relevant parasite-host associations; and (iii) integrates traditional parasite ENM with the proposed microscale niche to better understand geographic distributions and improve fine-scale predictions of disease transmission risk. ENM and Biotic InteractionsENM estimates the distributions of species by linking their geographic occurrence with their environmental constraints, often utilizing correlative approaches (detailed explanations in [18]). Highlights

show abstract

Section: Traditional Enm Framework Limitations For Disease Systemsmentioning

confidence: 99%

mentioning

confidence: 99%

An Ecological Framework for Modeling the Geography of Disease Transmission

Johnson

Escobar

Zambrana‐Torrelio

2019

Trends in Ecology & Evolution

Self Cite

110

View full text Add to dashboard Cite

show abstract

“…This may be due to a variety of factors, including low veterinary and human public health standards, climate change, migration, growing incomes and meat consumption in emerging economies, encroachment of people and their livestock on wildlife habitats, and animal-human proximity in poor households and in many cities in low income countries 10. The emergence and spread of antimicrobial resistance is a related threat that could have similar effects to those of a severe influenza pandemic or climate change 7.…”

Section: Identifying and Communicating Risksmentioning

confidence: 99%

“…Communications about zoonotic diseases can be harmful when health officials (or the media) mislead the public about the source of the risk and also influence behaviour 10. Research on risk perception, behavioural reactions, and media incentives can improve containment strategies.…”

Section: Identifying and Communicating Risksmentioning

confidence: 99%

Call for independent monitoring of disease outbreak preparedness

Jonas

Katz

Yansen

et al. 2018

BMJ

View full text Add to dashboard Cite

show abstract

“…Zoonotic diseases represent a significant threat to human and animal health (Allen et al, ), and their prevention, detection and control constitute a public health priority in endemic regions. One of these regions is the South Caucasus.…”

Section: Introductionmentioning

confidence: 99%

Multivariate relationships between epidemiologic risk factors and zoonotic infections among military personnel in the country of Georgia: A non‐linear canonical correlation analysis

Akhvlediani¹,

Chitadze

Chlikadze

et al. 2019

Zoonoses and Public Health

View full text Add to dashboard Cite

Zoonotic diseases are endemic in the country of Georgia. Using the non‐linear canonical correlation (NCC) method, the aim of this study was to examine the relationship between thirteen epidemiological risk factors and seropositivity to five zoonotic infections (anthrax, Q fever, tularemia, leptospirosis, and Crimean‐Congo hemorrhagic fever [CCHF]) among Georgian military recruits during 2014–2016. According to this multivariate statistical technique, which is suitable for the analysis of two or more sets of qualitative variables simultaneously, two canonical variables were identified. These variables accounted for 68% of the variation between the two sets of categorical variables (“risk factors” and “zoonotic infections”). For the first canonical variable, there was a relationship among CCHF (canonical loading, which is interpreted in the same way as the Pearson's correlation coefficient, [cl] = 0.715), tick bites (cl = 0.418) and slaughter of animals (cl = 0.351). As for the second canonical variable, Q fever (cl = −0.604) and leptospirosis (cl = −0.486) were related to rodents inside and outside home (cl = −0.346) and sweeping in or around home (cl = −0.317). The NCC method allows researchers to obtain additional insights into the complex relationship between epidemiological risk factors and multiple zoonotic infections.

show abstract

Global hotspots and correlates of emerging zoonotic diseases

Cited by 826 publications

References 62 publications

An Ecological Framework for Modeling the Geography of Disease Transmission

An Ecological Framework for Modeling the Geography of Disease Transmission

Call for independent monitoring of disease outbreak preparedness

Multivariate relationships between epidemiologic risk factors and zoonotic infections among military personnel in the country of Georgia: A non‐linear canonical correlation analysis

Contact Info

Product

Resources

About