Disaster preparedness to exotic and emerging infections
David J HeslopSchool of Public Health and Community Medicine, UNSW Sydney, NSW, Australia. Email: d.heslop@unsw.edu.au
Microbiology Australia 41(3) 123-127 https://doi.org/10.1071/MA20032
Published: 19 August 2020
Abstract
Exotic and emerging infectious diseases are emerging more frequently, and impacting more profoundly, all of humanity. Disasters risk reduction efforts over the preceding decades, culminating in the Hyogo and Sendai frameworks, have provided a roadmap for all countries to address emerging disaster related risks. Sudden onset or surprise epidemics of exotic or emerging diseases have the potential to exceed the adaptive capacity of countries and international efforts and lead to widespread unmitigated pandemics with severe flow on impacts. In this article pandemic preparedness is viewed through the lens of international disaster risk reduction and preparedness efforts. Preparing for the unknown or unexpected infectious disease crisis requires different approaches than the traditional approaches to disaster related epidemic events. Countries must be able to position themselves optimally through deliberate planning and preparation to a position where future exotic or emerging infections can be managed without overwhelming public health, and other societal resources.
Introduction
Disaster preparedness has been a key focus of national and international efforts to reduce risks to vulnerable populations and improve resilience. International frameworks such as the Hyogo and now Sendai frameworks for disaster risk reduction provide all nations with a roadmap to protect development gains from disaster risks. The all-encompassing breadth of the Sendai Framework, covering all types of disasters at the strategic policy level, on its own is insufficient to provide the detailed information required to specifically address risks and improve capacity to manage emerging or exotic pathogens. Challenging even for the most advantaged, many countries are unable to properly evaluate or respond to these requirements in a way that guarantees an effective response to a major epidemic crisis1,2.
Since the late 1990s the world has been subjected to repeated epidemics of significance caused by exotic and emerging pathogens3–6, and with increasing frequency even when accounting for increased surveillance and better detection technologies. It is proposed this is being driven by overpopulation, urbanisation, globalisation of trade and travel, climate change, resource depletion, and new habitat encroachment and exploitation4,5,7–9. Equally, and interlinked, are increased vulnerabilities to emerging and exotic pathogens due to overcrowding, aging related immune senescence, immunosuppression, antimicrobial resistance, poor nutrition and rising levels of chronic disease3,10,11.
Understanding how to achieve disaster risk reduction and disaster preparedness for exotic and emerging pathogens requires a detailed understanding of not only the traditional approaches to disaster preparedness, but also a detailed understanding of how population vulnerabilities, behaviour, resilience and patterns or life interact to influence disease dynamics7. By their very nature as emerging and exotic infections, such diseases are characterised by limited data, disease dynamics uncertainties, and assumptions regarding the most effective public health interventions. In this article the disaster preparedness frameworks relevant to exotic and emerging infections are outlined, and the challenges in achieving optimal pandemic preparedness in the face of uncertainty due to novelty and limited understanding of the pathogen are discussed.
Epidemics caused by disasters
Numerous examples are available that outline the causal relationship between simple and complex disasters, and the emergence of epidemics in the post-disaster phase. A prominent example of this was the emergence of cholera in Haiti following the major earthquake of 2010. The epidemic of cholera disease in Haiti occurred at a time where the population was least prepared, with a highly compromised health system12,13 and widespread population vulnerabilities. A more recent example is the emergence of diphtheria in the Rohingya refugee camp on the border of Bangladesh14, and other many others. The frequent linkage of disasters with outbreaks of infectious disease is fundamentally important to disaster and humanitarian response planners15,16. In humanitarian response it is assumed at least one major epidemic will occur in a major event, thus significant resources are allocated to prepare and prevent it. Estimations of the most likely types of outbreaks that could occur following particular disasters are based on historical data and experience contextualised into the crisis at hand during the operational planning process. The standard medical and logistic planning tools available in the World Health Organization (WHO) and UN Disaster Aid Coordination (UNDAC) approaches support post-disaster epidemic preparedness and planning in this way.
Epidemics as disasters
Epidemics do not always occur secondarily to disasters. Such events, possibly due to a zoonotic cross-over event, an accident involving the mishandling a pathogen, or a deliberate release of one, occur at an unpredictable time and location. Significant uncertainties about pathogen specific virulence factors, transmissibility, behaviour within human and zoonotic populations, and the impact on populations and societies are usually present. There is also a paucity of evidence during the early phases of an epidemic about what therapeutic, social, and non-pharmaceutical interventions might be effective3,17. It is well recognised that the quality and quantity of available information to support decision-making increases over time. In humanitarian responses the Multi-sector Initial Rapid Assessment (MIRA) framework is designed to rapidly and systematically address this information gap, but the novel aspect of the epidemic makes this gap all the more impactful and dangerous.
Two of the three most recent major coronavirus epidemics (SARS-1 and MERS-CoV) emerged outside of the context of disasters, all believed to have emerged as a consequence of cross-over events from a zoonotic reservoir3. The emergence of H1N1 pandemic influenza equally occurred in the absence of a deliberate triggering event but as the result of a cross-over event18. In each of these examples, initial uncertainties and unknowns were gradually replaced with greater and greater information allowing for more effective epidemic control. Modest morbidity and mortality, the nature of the infectious diseases themselves, and appropriate initial epidemic response, provided decision-makers time to collect sufficient information and bring systems to bear. In contrast, uncertainties associated with SARS-CoV-2 (COVID-19) coupled with the unexpected rapidity of spread within communities and various modes of transmission have possibly contributed to the relative ineffectiveness of public health authorities and governments to prevent COVID-19 becoming a pandemic2,19.
The critical difference between epidemic disasters and other forms of disasters is the transmissible and spreading nature of the hazard within the vulnerable population. Epidemics of emerging or exotic pathogens occurring de novo in a population are unlikely to be well aligned with even the most carefully devised pandemic preparedness activities and plans, in contrast with opportunistic epidemics triggered by disasters that are more likely to correlate well with existing preparedness activities17.
Preparedness frameworks
Pandemic influenza, particularly a novel avian influenza, has historically been identified as the most likely emerging pathogen with pandemic potential19. The WHO has therefore utilised Influenza as the exemplar pathogen around which pandemic preparedness is framed. This has led to a number of key preparedness activities that are outlined in Table 120. However, it is equally recognised that influenza may not be the pathogen responsible for the next major pandemic. While influenza preparedness is a focus, a key assumption within each plan is the ability to readily and rapidly adapt existing influenza preparedness plans to suit any other respiratory pathogen. A key issue with this approach is the assumption that preparedness plans for all respiratory pathogens of pandemic potential conform to the model influenza framework, and that adaptation is possible within the timeframes available in the early part of an emergent pandemic when preparedness efforts are likely to have most effect.
Equally, at the country level significantly more detail is needed in order to translate what is broad intent, agreement and strategic guidance at the international level into concrete preparedness and planning actions. This is often a very difficult problem for individual countries, particularly low- and middle-income countries. In this case regional collaborations to share resources and jointly build capacity have been recommended as a possible solution8,16. Some of the key pitfalls associated with the current exemplar system of pandemic preparedness and response, as embodied in the plans for pandemic influenza, are:
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A failure to follow through on strategic commitment with the necessary resources and changes required to deliver a cohesive and effective epidemic response
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Disconnection between senior political and health leadership, and middle level health system professionals and managers, leading to inaccurate understanding of health system flexibility and adaptability to pandemic challenges.
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Inaccurate self-reporting of national capacity through various evaluation mechanisms
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Barriers to ensuring that gaps and identified problems in national response capacity are addressed or improved.
How to improve preparedness for future exotic or emerging pandemics
Improving preparedness for future exotic or emerging pandemics at both the country and international level requires strong political and health leadership at all levels19,20. Without a commitment to improving preparedness the necessary resources will not be made available and efforts cannot be coordinated and supported.
Beyond strong leadership, a flexible and agile health care system able to respond to the unexpected demands and realities of an outbreak of an emerging or exotic pathogen is important, allowing adaptation during any epidemic crisis from a baseline that allows the system to flex to a posture of sufficient and effective response. This is shown diagrammatically in Figure 1.
A recent report commissioned by the WHO identified 10 points that are necessary to best prepare for future exotic or emerging infectious disease epidemics20. They are:
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Improving core public health capacities
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Improving national and global surveillance capacities
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Developing systems for sharing resources and information relevant to disease preparedness and response
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Improving operational readiness to respond to infectious disease emergencies
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Using social science and community engagement to optimise pandemic response
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Individual countries and global organisations developing and exercising plans for risk communication
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Research effort directed towards rapid vaccine development and surge manufacturing capacity
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The evidence and role of non-pharmaceutical interventions clearly articulated to decision-makers
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Improving biosafety around high impact pathogens
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Accepting the possibility of surprise and the need to prepare for it.
While all of these areas have already been the focus of intense efforts over many years to improve pandemic preparedness, concerns such as increased activities in Dual Use Research of Concern (DURC) areas, reductions in barriers to accessing technologies enabling the development of emerging biological pathogens of pandemic potential, increasing opportunities for zoonotic cross-over, and many other factors are continually undermining these efforts. Addressing both the positive and negative influences on preparedness is important to optimising flexibility, resilience and reducing system vulnerability.
Conclusion
Preparedness for exotic and emerging pathogens is a challenging area of public and health policy. Traditionally preparedness for infectious disease disasters has been driven by historical data and examples – an approach that is the mainstay of the health and humanitarian response to disasters. Exotic and emerging pathogens introduce uncertainties and unknown factors that require a modified approach to preparedness. This is most commonly managed through the development of agile preparedness systems that are able to support system wide adaptation to the emergence of an exotic or emerging pathogen in a population. Recently numerous factors, particularly those associated with the risk of deliberate or accidental release of a novel pathogen, work against achieving an adequate level of agility and responsiveness to a novel infectious disease event. Addressing factors that improve preparedness to respond, while simultaneously addressing factors that threaten to undermine preparedness in general, are equally important to the overall pandemic preparedness effort.
Conflicts of interest
The author declares no conflicts of interest.
Acknowledgements
This research did not receive any specific funding.
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Biography
Dr David Heslop is an Associate Professor at the School of Public Health and Community Medicine at UNSW Sydney. He retains military responsibilities as SO1 Public Health and Occupational Medicine at Army Headquarters. He is a clinically active vocationally registered General Practitioner, registered Occupational and Environmental Medicine Physician with the Royal Australasian College of Physicians, and a fellowship candidate for the Academy of Wilderness Medicine. During a military career of over 15 years he has deployed into a variety of complex and austere combat environments, and has advanced training in Chemical, Biological, Radiological, Nuclear and Explosive (CBRNE) Medicine. His research interests lie in health and medical systems innovation and research. He is a chief investigator on the NHMRC Centre for Research Excellence Integrated Systems for Epidemic Response (ISER), and undertakes collaborative research exploring evaluation of the medical aspects of high risk and high consequence environments through a novel computational modelling and simulation effort with DST Group, and various emergency response and CBRNE related teaching and research activities with Industry and Government organisations. Throughout the COVID-19 crisis he has been providing specialist Public Health and Occ and Env Medicine advice to a range of government and private organisations, the most notable as the biosecurity operational and policy adviser to the NRL Project Apollo initiative.