Vetnuus | July 2025 17 Article >>>18 the landscape, so too will the pathogens dependent on these species for survival. Although research has shown that a decrease in biodiversity often results in increased disease risk (Civitello et al., 2015; Keesing et al., 2010; Orrock et al., 2011; Johnson et al., 2009; Johnson and Thieltges, 2010; Johnson et al., 2013ab), climate change could also decrease the prevalence and geographic extent of some diseases. Historically, disease in free-ranging animals was considered a natural process inherent to the functioning of a park ecosystem, and the NPS did not routinely intervene or attempt to manage disease impacts unless overt public health impacts existed (Sellars, 1997). Disease can be a natural process and is indeed at some level a component of a healthy ecosystem. Traditionally, native diseasecausing organisms warranted the same protection as other flora and fauna. However, the re-examination of disease origins, in part aided by rapid advances in genetic and other classification techniques, led to the realization that observed diseases were in many cases a result of exotic pathogens or anthropogenic impacts (Meager and Meyer, 1994; NPS, 2002a, b; Wobeser, 2002). This recognition of the nonnative origin and anthropogenic drivers of some major diseases required broadened disease management approaches in free-ranging wildlife. Today, most if not all ecosystems are impacted by significant external stressors, most notably land-use changes, loss of habitat connectivity, introduced species, changes in species abundance and density, and climate change. These external stressors have already significantly impacted both disease occurrence and wildlife populations such that current disease processes are rarely a completely natural process. Disease is a highly complex process influenced by both infectious and non-infectious factors. Changes in any of the three components of the disease triad – host, agent, or environment – can influence disease outcomes significantly, even if the underlying pathogen itself remains unchanged (Daszak et al., 2001). Diseases are more likely to have significant impacts in a system that has experienced disturbance, whereas non-disturbed systems are more ecologically resilient to disease impacts or introductions (Wobeser, 2002). Active management of diseases should therefore no longer be a last resort but considered a critical tool to ‘mitigate unacceptable impacts from external stressors’ through a harm reduction approach (Colwell et al., 2012; Fisichelli et al., 2016; Stephen et al., 2018). In a wildlife health context, ‘‘rather than focusing on obstacles and deficits, [harm reduction] deals with securing critical resources to stay well’’ (Stephen et al., 2018). Critical harmreduction strategies for wildlife have included enhancement of wildlife corridors, facilitating genetic exchange across populations, enhancing forage and habitat resources, and reducing impacts of human-wildlife interactions, among others, whether the threats are direct (i.e., vehicular collisions, hunting, or resource competition) or indirect (i.e., reduced reproduction, foraging, and movements due to human presence aversion) (Stephen & Wade 2018; Sleeman et al., 2019; Gallagher, 2020). Under climate change, ‘natural conditions may be both increasingly difficult to characterize and ineffective as a guide for desired future conditions’ (NPS, 2012). This is particularly true for pathogens and associated diseases. The difficulty and expense in detecting pathogens in free-ranging systems, their rapidly evolving nature, and the lack of historical information on diseases prevent the classification of native versus exotic for many pathogens. As a result, despite NPS policy striving ‘to maintain all the components and processes of naturally evolving park ecosystems, including the natural abundance, diversity, and genetic and ecological integrity of the plant and animal species native to those ecosystems’, a maturation in NPS policy interpretation was required. The decision of how and when to manage infectious disease in practice is currently based on disease impacts and processes as opposed to disease characteristics (native vs non-native) or drivers (i.e., evolutionary rate, community structure, climate change) (Aguirre et al., 1994, 1995; NPS, 2000, 2006). Whether the pathogen is native or non-native, management is often necessary under anthropogenic change to reduce or prevent local extirpation, genetic compromise, or other impacts on an affected population, as in the case of native epizootic hemorrhagic disease in endangered Florida Key deer. On the other hand, management may be unnecessary when impacts do not compromise population viability, as in the case of climate-driven range expansion of epizootic hemorrhagic disease in white-tailed deer (NPS, 2002a, b; Stallknecht et al., 2015; Zuliani et al., 2015). Management response to zoonotic diseases creates an additional need for contemporary interpretation. Management Policies (NPS, 2006) directs action in situations where 1) human health and safety are at risk, a disease can be controlled, and human behaviour modification, resource use modification, or closures are not effective in protecting human health and safety as determined by public health; 2) disease may pose a threat to adjacent lands, or 3) exotic pathogens that can be managed are threatening native resources. Although this guidance might be interpreted to encourage interventions for diseases that threaten human health even when natural resource impacts result from these interventions, NPS Management Policies section 1.4.3 states: Congress, recognizing that the enjoyment by future generations of the national parks can be ensured only if the superb quality of park resources and values is left unimpaired, has provided that when there is a conflict between conserving resources and values and providing for the enjoyment of them, conservation is to be predominant. In this context, visitor use of a park may be unacceptable if visitor health can only be preserved through actions that could impair future use or appreciation of native species. In this era of rapid change, more work is needed to proactively identify unacceptable impacts from management actions, as well as visitation itself, to prevent these decisions from being made during a crisis. Climate change is one of many human influences on natural systems. The real risk comes in the rapid and understudied direct impacts, the yet unknown ways in which this and other anthropogenic stressors synergize to impact natural resources, and the limited time that we have to act to prevent irreversible change that threatens natural resources and human civilization alike (IPCC, 2014). Although existing policy can be re-interpreted to accommodate a harm reduction approach, we argue that new or updated Management Policies, Executive Orders, or Congressional Mandates should prioritize and standardize a harm reduction approach and mobilize new and existing resources to better characterize ecosystem ‘health’ and factors that can promote ecological resilience. Managers of national parks and other protected areas are encouraged to take a holistic, preventative approach to infectious disease and evaluate management options from the disease-impact perspective rather than the categorization of a specific organism or pathogen. Broader understanding, and therefore data, on the health of our natural resources and pre-
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