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Emerging zoonoses: tackling the challenges

Published online by Cambridge University Press:  11 May 2015

K. D. C. STÄRK  and
D. MORGAN
K. D. C. STÄRK
Affiliation:
Royal Veterinary College, London, UK
D. MORGAN
Affiliation:
Public Health England, London, UK London School of Hygiene and Tropical Medicine, London, UK (Email: kstaerk@rvc.ac.uk)
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Abstract

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Type
Editorial
Information
Epidemiology & Infection , Volume 143 , Special Issue 10: Emerging zoonoses , July 2015 , pp. 2015 - 2017
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Copyright
Copyright © Cambridge University Press 2015 

It is widely accepted that most emerging diseases are zoonotic, i.e. naturally transmitted between vertebrate animals and humans, often involving complex transmission pathways that may also include arthropods [Reference Cleaveland, Laurenson and Taylor1, Reference Cutler, Fooks and van der Poel2]. In recent years, emerging zoonoses have received increasing attention due to major outbreaks such as SARS and Ebola.

According to the European Food Safety Agency (EFSA), an emerging risk is defined as ‘a risk resulting from a newly identified hazard to which significant exposure may occur or from an unexpected new or increased significant exposure and/or susceptibility to a known hazard’. Thus, emerging zoonoses may be caused by previously unknown agents (i.e. ‘true’ emergence) or by changes in the exposure or susceptibility of hosts leading to an increased number of cases. Some authors also distinguish between global emergence – outbreaks due to agents observed for the first time worldwide, or local emergence – occurrence of a known agent in geographical areas previously free of disease. There may also be apparent disease emergence caused by increased disease awareness or improved or new diagnostic tools. The latter should be distinguished from true emergence [Reference D'Alessandro3].

Numerous factors have been identified as drivers of disease emergence [Reference Morse4Reference Weaver and Reisen7]. These include both characteristics of the pathogen itself such as high mutation rate in RNA viruses, as well as characteristics of the host such as human demographics and behaviour. The latter can include, for example, changes in dietary habits or behaviour which can increase the relevance of previously rare exposure pathways. More frequent travelling to exotic places or consumption of exotic foods such as bush meat are examples of such changed behaviour. Moreover, through an increase in air passenger numbers, pathogen incursions via human movement can become a real risk [Reference Van Den Bossche8]. Finally, ecological and environmental changes can also lead to changes in the distribution of agents or their vectors [Reference Weaver and Reisen7]. Although inextricably linked to the factors above, climate change is a major driver for disease emergence. There are already several examples where changes in temperature and/or rainfall have led to the spread of zoonotic diseases. In Europe, this is true for West Nile virus, dengue virus and chikungunya virus. Flooding can be an additional risk factor. Finally, changes in agricultural practices and particularly global trade can lead to an increased probability of spread of agents [Reference Wallace and Wallace9]. The understanding of these driving factors is therefore central to preparedness. A key lesson learnt on emerging diseases is that we need to understand and – if possible – anticipate the convergence of factors related to the characteristics of the microbe and host, as well as their complex interaction simultaneously or in sequence [Reference Smolinski, Hamburg and Lederberg10].

Despite ongoing research, the epidemiology of many zoonoses remains obscure. Even for pathogens that have been known for a long time in humans, the animal reservoir can remain vaguely defined or unknown. This involves not only diseases causing minor disease burden such as tularaemia where pathogenic strains are rare [Reference D'Alessandro3, Reference Hestvik11], but also major public health threats such as Ebola. Certain animals are mentioned in the context of several emerging diseases, most notably a number of bats (Chiroptera) which have been associated with disease outbreaks caused by both Hendra and Nipah viruses. Epidemiological and genomic analyses suggest a single zoonotic transmission event from a bat to a 2-year old boy was the initiating factor for the recent Ebola outbreak in West Africa [Reference Baize12, Reference Alexander13]. Human behaviour then became the key driver for the subsequent human-to-human transmission which led to a major outbreak.

In order to be able to more effectively manage outbreaks of emerging zoonoses, early warning systems are being developed. Such systems are widely used and a range of methods are available [Reference Rodríguez-Prieto14]. Nevertheless, to achieve mitigation of emerging zoonoses, it is important to integrate surveillance into a wider context of general preparedness and rapid response. This should be achieved at a time when resources for both veterinary and public health services are being reduced. Prioritization is thus essential to use limited resources in an effective way. A range of approaches to priority setting is in use [Reference Brookes15], but a better integration and strategic use is warranted.

Methods such as risk assessment or simulation modelling can also be applied to estimate the probability of pathogen emergence, incursions into previously free areas and subsequent spread [Reference Alexander13, Reference Brookes15]. However, as we are dealing with novel risks, there will be major uncertainties and paucity of data underpinning these models. In such situations, expert opinion may be the only option. Limitations of this approach are well understood and measures to assure use of good practice should be taken. To include more experts is not always a solution as they may have diverging views the combination of which can cause further challenge [Reference Roche16].

Emerging zoonoses are often complex in their biology and epidemiology. Their effective control therefore requires a combination of knowledge and skills across disciplines. The need for collaboration involving public health specialists and veterinarians, and also environmental scientists, economists, sociologists and anthropologists has been repeatedly emphasized [Reference Hestvik11, Reference Alexander13, Reference Brookes15]. Such an approach would follow the so-called One Health paradigm. There are many definitions of One Health, and they generally cover efforts to provide more effective, evidence and systems-based health interventions. Examples of implementations of the One Health concept are unfortunately still rare. A recent international round-table discussion called for more inter-related training of medical, veterinary and environmental science students to create conditions in which One Health would offer the obvious approach [Reference Stärk17]. This would be particularly useful for the control of zoonoses and essential for the early detection and effective management of disease emergence. The outbreak of Ebola that occurred across several countries in West Africa provides a stark example of the consequences of delayed and inefficient response. It also creates an opportunity to investigate influential factors for successful and rapid management of disease emergence. Priorities for capacity-building for the control of emerging zoonotic diseases have recently been identified [Reference Gebreyes18]. Efforts should include the development of risk management policies, human and diagnostic capacity building as well as cost-benefit considerations for setting priorities when resources are limited.

References

REFERENCES

1. Cleaveland, S, Laurenson, MK, Taylor, LH. Diseases of humans and their domestic mammals: pathogen characteristics, host range and the risk of emergence. Philosophical Transactions of the Royal Society of London, Series B: Biological Sciences 2001; 356: 991999.Google Scholar
2. Cutler, SJ, Fooks, AR, van der Poel, WHM. Public health threat of new, reemerging, and neglected zoonoses in the industrialized world. Emerging Infectious Diseases 2010; 16: 17.Google Scholar
3. D'Alessandro, D, et al. Human tularemia in Italy. Is it a re-emerging disease? Epidemiology and Infection. Published online: 22 October 2014. doi:10.1017/S0950268814002799.Google ScholarPubMed
4. Morse, SS. Factors in the emergence of infectious diseases. Emerging Infectious Diseases 1995; 1: 715.CrossRefGoogle ScholarPubMed
5. Anderson, PK, et al. Emerging infectious diseases of plants: pathogen pollution, climate change and agrotechnology drivers. Trends in Ecology and Evolution 2004; 19: 535544.CrossRefGoogle ScholarPubMed
6. Jones, KE, et al. Global trends in emerging infectious diseases. Nature 2008; 451: 990993.CrossRefGoogle ScholarPubMed
7. Weaver, SC, Reisen, WK. Present and future arboviral threats. Antiviral Research 2010; 85: 328345.Google Scholar
8. Van Den Bossche, D, et al. Chikungunya virus and West Nile virus infections imported into Belgium, 2007–2012. Epidemiology and Infection. Published online: 2 April 2014. doi:10.1017/S0950268814000685.Google ScholarPubMed
9. Wallace, R, Wallace, RG. Blowback: new formal perspectives on agriculturally driven pathogen evolution and spread. Epidemiology and Infection. Published online: 4 February 2014. doi.org/10.1017/S0950268814000077.Google Scholar
10. Smolinski, MS, Hamburg, MA, Lederberg, J (eds). Microbial threats to health: emergence, detection, and response. Institute of Medicine (US) Committee on Emerging Microbial Threats to Health in the 21st Century. Washington, DC, The National Academies Press, 2003, pp. 397.Google Scholar
11. Hestvik, G, et al. The status of tularemia in Europe in a one-health context: a review. Epidemiology and Infection. Published online: 30 September 2014. doi.org/10.1017/S0950268814002398.Google Scholar
12. Baize, S, et al. Emergence of Zaire Ebola virus disease in Guinea – preliminary report. New England Journal of Medicine 2014; 371: 14181425.Google Scholar
13. Alexander, KA, et al. What factors might have led to the emergence of Ebola in West Africa? PLOS Neglected Tropical Diseases (in press). [preliminary version available online: http://blogs.plos.org/speakingofmedicine/2014/11/11/factors-might-led-emergence-ebola-west-africa/].Google Scholar
14. Rodríguez-Prieto, V, et al. Systematic review of surveillance systems and methods for early detection of exotic, new and re-emerging diseases in animal populations. Epidemiology and Infection. Published online: 12 September 2014. doi.org/10.1017/S095026881400212X.Google Scholar
15. Brookes, VJ, et al. Preparedness for emerging infectious diseases: pathways from anticipation to action. Epidemiology and Infection. Published online: 12 December 2014. doi.org/10.1017/S095026881400315X.Google ScholarPubMed
16. Roche, SE, et al. Assessing the risk of Nipah virus establishment in Australian flying-foxes. Epidemiology and Infection. Published online: 4 February 2014. doi.org/10.1017/S0950268813003336.Google Scholar
17. Stärk, KDC, et al. One health surveillance – more than a buzz word? Preventive Veterinary Medicine. Published online: 11 February 2015. doi:10.1016/j.prevetmed.2015.01.019.CrossRefGoogle ScholarPubMed
18. Gebreyes, WA, et al. The global one health paradigm: challenges and opportunities for tackling infectious diseases at the human, animal, and environment interface in low-resource settings. PLoS Neglected Tropical Diseases 2014; 8: e3257.Google Scholar