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Overcoming the limitations of wildlife disease monitoring

Published online by Cambridge University Press:  12 January 2024

A response to the following question: How do the practical and pragmatic limitations in the design or implementation of wildlife disease surveillance systems bias our understanding of the drivers, epidemiology, and impact of pathogen traffic between wildlife and people or domestic species, or within wildlife host populations?

Patricia Barroso
Affiliation:
Department of Veterinary Sciences, University of Turin, Turin, Italy
Jorge R. López-Olvera*
Affiliation:
Wildlife Ecology & Health (WE&H) research group and Servei d’Ecopatologia de Fauna Salvatge (SEFaS), Departament de Medicina i Cirurgia Animals, Universitat Autònoma de Barcelona (UAB), Bellaterra, Barcelona, Spain
Théophile Kiluba wa Kiluba
Affiliation:
Research Centre in Natural Sciences (CRSN), Lwiro, South Kivu, Democratic Republic of Congo (DRC) Department of General Biology, Natural Conservation, and Wildlife, Faculty of Veterinary Medicine, University of Lubumbashi, Lubumbashi, Haut-Katanga, Democratic Republic of Congo (DRC)
Christian Gortázar
Affiliation:
SaBio Instituto de Investigación en Recursos Cinegéticos (IREC) CSIC-UCLM-JCCM, Ciudad Real, Spain
*
Corresponding author: Jorge R. López-Olvera; Emails: [email protected], [email protected]
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Abstract

Integrated wildlife monitoring (IWM) combines infection dynamics and the ecology of wildlife populations, including aspects defining the host community network. Developing and implementing IWM is a worldwide priority that faces major constraints and biases that should be considered and addressed when implementing these systems. We identify eleven main limitations in the establishment of IWM, which could be summarized into funding constraints and lack of harmonization and information exchange. The solutions proposed to overcome these limitations and biases comprise: (i) selecting indicator host species through network analysis, (ii) identifying key pathogens to investigate and monitor, potentially including nonspecific health markers, (iii) improve and standardize harmonized methodologies that can be applied worldwide as well as communication among stakeholders across and within countries, and (iv) the integration of new noninvasive technologies (e.g., camera trapping (CT) and environmental nucleic acid detection) and new tools that are under ongoing research (e.g., artificial intelligence to speed-up CT analyses, microfluidic polymerase chain reaction to overcome sample volume constraints, or filter paper samples to facilitate sample transport). Achieving and optimizing IWM is a must that allows identifying the drivers of epidemics and predicting trends and changes in disease and population dynamics before a pathogen crosses the interspecific barriers.

Type
Impact Paper
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Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

Establishing, developing, and implementing wildlife health surveillance programs is a worldwide priority and a challenge within the One Health approach (Ryser-Degiorgis, Reference Ryser-Degiorgis2013; OIE, 2019; Lawson et al., Reference Lawson, Neimanis, Lavazza, López-Olvera, Tavernier, Billinis, Duff, Mladenov, Rijks, Savić, Wibbelt, Ryser-Degiorgis and Kuiken2021; Machalaba et al., Reference Machalaba, Uhart, Ryser-Degiorgis and Karesh2021; Giacinti et al., Reference Giacinti, Pearl, Ojkic, Campbell and Jardine2022; Mazzamuto et al., Reference Mazzamuto, Schilling and Romeo2022; Delgado et al., Reference Delgado, Ferrari, Fanelli, Muset, Thompson, Sleeman, White, Walsh, Wannous and Tizzani2023; Pruvot et al., Reference Pruvot, Denstedt, Latinne, Porco, Montecino-Latorre, Khammavong, Milavong, Phouangsouvanh, Sisavanh, Nga, Ngoc, Thanh, Chea, Sours, Phommachanh, Theppangna, Phiphakhavong, Vanna, Masphal, Sothyra, San, Chamnan, Long, Diep, Duoc, Zimmer, Brown, Olson and Fine2023). Traditionally, wildlife health surveillance is considered to encompass general surveillance (also called scanning or passive surveillance) and targeted surveillance (formerly called active surveillance) (Ryser-Degiorgis, Reference Ryser-Degiorgis2013; OIE, 2019). General surveillance is based on the detection of dead or visibly sick wildlife, while targeted surveillance relies on proactive sampling of dead or living wildlife to detect a selected disease or pathogen (Leighton, Reference Leighton1995; Artois et al., Reference Artois, Bengis, Delahay, Smith and Hutchings2009; Leighton, Reference Leighton1995). While general surveillance better suits the investigation of disease or mortality outbreaks, particularly for new or emerging diseases in an area or population, targeted surveillance allows the detection of pathogens asymptomatically infecting the animals (Ryser-Degiorgis, Reference Ryser-Degiorgis2013; OIE, 2019), monitoring prevalence trends (Barroso et al., Reference Barroso, Barasona, Acevedo, Palencia, Carro, Negro, Torres, Gortázar, Soriguer and Vicente2020a, Reference Barroso, García-Bocanegra, Acevedo, Palencia, Carro, Jiménez-Ruiz, Almería, Dubey, Cano-Terriza and Vicente2020b), and assessing the outcome of interventions (Boadella et al., Reference Boadella, Vicente, Ruiz-Fons, de la Fuente and Gortázar2012). Proposals to standardize and harmonize wildlife health surveillance at local, regional, and global scale have been and are currently being developed, with little success in achieving successful implementation up to date (Boadella et al., Reference Boadella, Gortázar, Acevedo, Carta, Martín-Hernando, de la Fuente and Vicente2011a; Hanisch et al., Reference Hanisch, Riley and Nelson2012; Stephen, Reference Stephen2018; Tomaselli et al., Reference Tomaselli, Kutz, Gerlach and Checkley2018; OIE, 2019; Lawson et al., Reference Lawson, Neimanis, Lavazza, López-Olvera, Tavernier, Billinis, Duff, Mladenov, Rijks, Savić, Wibbelt, Ryser-Degiorgis and Kuiken2021; Machalaba et al., Reference Machalaba, Uhart, Ryser-Degiorgis and Karesh2021; Giacinti et al., Reference Giacinti, Pearl, Ojkic, Campbell and Jardine2022; Mazzamuto et al., Reference Mazzamuto, Schilling and Romeo2022; Pruvot et al., Reference Pruvot, Denstedt, Latinne, Porco, Montecino-Latorre, Khammavong, Milavong, Phouangsouvanh, Sisavanh, Nga, Ngoc, Thanh, Chea, Sours, Phommachanh, Theppangna, Phiphakhavong, Vanna, Masphal, Sothyra, San, Chamnan, Long, Diep, Duoc, Zimmer, Brown, Olson and Fine2023).

Wildlife health surveillance aims at detecting, investigating, and monitoring disease in wildlife populations (Ryser-Degiorgis, Reference Ryser-Degiorgis2013; OIE, 2019). However, achieving a precise knowledge of wildlife species abundance, density, and distribution is challenging, and establishing harmonized methodologies allowing exchange of information and comprehensive epidemiological studies across geographical regions has become an issue (Sonnenburg et al., Reference Sonnenburg, Ryser-Degiorgis, Kuiken, Ferroglio, Ulrich, Conraths, Gortázar and Staubach2017; Moussy et al., Reference Moussy, Burfield, Stephenson, Newton, Butchart, Sutherland, Gregory, McRae, Bubb, Roesler, Ursino, Wu, Retief, Udin, Urazaliyev, Sánchez‐Clavijo, Lartey and Donald2022; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023). As a result of such a challenge, most current wildlife health surveillance schemes lack integration with appropriate population monitoring (Stallknecht, Reference Stallknecht2007; Lawson et al., Reference Lawson, Neimanis, Lavazza, López-Olvera, Tavernier, Billinis, Duff, Mladenov, Rijks, Savić, Wibbelt, Ryser-Degiorgis and Kuiken2021). Efforts have been carried out to overcome the methodological and technical limitations and achieve harmonized wildlife population monitoring (APHAEA 2023; Sonnenburg et al., Reference Sonnenburg, Ryser-Degiorgis, Kuiken, Ferroglio, Ulrich, Conraths, Gortázar and Staubach2017; EFSA, 2023; ENETWILD, 2023). This is even more complicated for multi-host pathogens, where the epidemiology and maintenance does not depend on a single-host species but on a host community network, which might include wildlife, domestic animals, and/or humans (Fenton and Pedersen, Reference Fenton and Pedersen2005; Godfrey, Reference Godfrey2013; Portier et al., Reference Portier, Ryser-Degiorgis, Hutchings, Monchâtre-Leroy, Richomme, Larrat, van der Poel, Domínguez, Linden, Santos, Warns-Petit, Chollet, Cavalerie, Grandmontagne, Boadella, Bonbon and Artois2019; Stephen, Reference Stephen2023). While most approaches to assess and monitor wildlife abundance focus on a single species or taxon, determining and achieving knowledge on the host community network, including abundance and interspecific contact rates, must instead be the objective, allowing to fine-tune community interspecific pathogen transmission dynamics (Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023; González-Crespo et al., 2023a, Reference González-Crespo, Martínez-López, Conejero, Castillo-Contreras, Serrano, López-Martín, Lavín and López-Olvera2023b).

Combining epidemiological and community network approaches allows the classification of disease threats according to the risk of exposure and duration (Fenton and Pedersen, Reference Fenton and Pedersen2005; Triguero-Ocaña et al., Reference Triguero-Ocaña, Martínez-López, Vicente, Barasona, Martínez-Guijosa and Acevedo2020). Nevertheless, measuring wildlife population health, including demographics and the diversity and status of infectious and noninfectious diseases (Hanisch et al., Reference Hanisch, Riley and Nelson2012; Stephen, Reference Stephen2014), faces major methodological, technical, logistical, economic, and even political constraints (Wobeser, Reference Wobeser2007; Ryser-Degiorgis, Reference Ryser-Degiorgis2013). Developing and implementing integrated wildlife monitoring (IWM), merging wildlife health monitoring (WHM) and host community monitoring (HCM), is required to achieve integrated and harmonized disease and population monitoring (Cardoso et al., Reference Cardoso, García-Bocanegra, Acevedo, Cáceres, Alves and Gortázar2022; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023). The complexity of assessing and monitoring the complete range of hosts and pathogens in the community has led to the quest for indicator species (Gortázar et al., Reference Gortázar, Barroso, Nova and Cáceres2021; Mazzotta et al., Reference Mazzotta, Bellinati, Bertasio, Boniotti, Lucchese, Ceglie, Martignago, Leopardi and Natale2023) as well as nonspecific health indicators (Ráez-Bravo et al., Reference Ráez-Bravo, Granados, Cerón, Cano-Manuel, Fandos, Pérez, Espinosa, Soriguer and López-Olvera2015; Vicente et al., Reference Vicente, Martínez-Guijosa, Tvarijonaviciute, Fernández-de Mera, Gortázar, Cerón and Martínez-Subiela2019). Indicator host species should allow to detect pathogens due to their central role in the network of a system, while nonspecific health indicators would allow detecting changes in population health status once the baseline values are established for each system (Halliday et al., Reference Halliday, Meredith, Knobel, Shaw, Bronsvoort and Cleaveland2007; Glidden et al., Reference Glidden, Beechler, Buss, Charleston, de Klerk-Lorist, Maree, Muller, Pérez-Martin, Scott, van Schalkwyk and Jolles2018; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023).

The objective of this article is describing the features, limitations, and biases of IWM and each one of their components (WHM and HCM) and how they affect the capability of IWM to understand the drivers, epidemiology, and impact of pathogen circulation.

Integrated wildlife monitoring

Figure 1 illustrates the components of IWM. It combines the study of the epidemiology of transmissible pathogens with the ecological knowledge of wildlife populations, including biodiversity and intra and interspecific contact rates and points defining the host community network. The detailed knowledge arising from such combination allows eco-epidemiologically characterizing the status of the pathogens present in a system as emerging, endemically maintained in a multi-host system, or spillover, as well as assessing whether the interaction of the host community with the pathogen(s) has a dilution effect or the multi-species host community exerts a density-dependent maintenance effect on the pathogen (Cortez and Duffy, Reference Cortez and Duffy2021). IWM also allows defining the specific role of each host taxon, species, or population as maintenance, bridge, or spillover hosts (Fenton and Pedersen, Reference Fenton and Pedersen2005; Gervasi et al., Reference Gervasi, Stephens, Hua, Searle, Xie, Urbina, Olson, Bancroft, Weis, Hammond, Relyea, Blaustein and Lötters2017; Pepin et al., Reference Pepin, Kay, Golas, Shriner, Gilbert, Miller, Graham, Riley, Cross, Samuel, Hooten, Hoeting, Lloyd‐Smith, Webb, Buhnerkempe and Aubry2017; Triguero-Ocaña et al., Reference Triguero-Ocaña, Martínez-López, Vicente, Barasona, Martínez-Guijosa and Acevedo2020; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023).

Figure 1. Components of Integrated wildlife monitoring (IWM) and main actions belonging to each component.

The additional effort and cost of developing, implementing, performing, and combining the double monitoring (health and population) required for IWM, as well as the need to standardize harmonized methodologies that can be applied transversally in countries and regions with different backgrounds and resources, call for the utilization of new noninvasive technologies, both for WHM and HCM. These new technologies should provide a wider and deeper monitoring while keeping efforts and costs within sustainable thresholds to allow long-term (ideally continuous) monitoring. Sampling and analytical methodologies such as environmental sampling (Martínez-Guijosa et al., Reference Martínez-Guijosa, Romero, Infantes-Lorenzo, Díez, Boadella, Balseiro, Veiga, Navarro, Moreno, Ferreres, Domínguez, Fernández, Domínguez, Gortázar and Serrano2020), use of filter paper (Santos et al., Reference Santos, Nunes, Fonseca, Vieira-Pinto, Almeida, Gortázar and Correia-Neves2018), microfluidic PCR (von Thaden et al., Reference von Thaden, Nowak, Tiesmeyer, Reiners, Alves, Lyons, Mattucci, Randi, Cragnolini, Galián, Hegyeli, Kitchener, Lambinet, Lucas, Mölich, Ramos, Schockert and Cocchiararo2020), and the establishment and determination of nonspecific health markers (Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023) should contribute to improve the feasibility of WHM. Furthermore, noninvasive population monitoring using remote-sensing devices such as camera trapping (CT) or sound-recording would probably reduce the effort and field personal cost required for HCM (Toenies and Rich, Reference Toenies and Rich2021; Palencia et al., Reference Palencia, Rowcliffe, Vicente and Acevedo2021a).

As aforementioned, IWM relies on WHM and wildlife HCM, each one of these components facing specific challenges, limitations, and biases. Moreover, the combination of WHM and wildlife HCM to achieve IWM creates additional challenges.

IWM limitations and biases

Section 1: WHM limitations and biases

WHM is critical given its relevance for public health, conservation, and food security. It generates benefits that range from early disease detection to the capacity to design and evaluate interventions and regulatory changes (Cano-Terriza et al., Reference Cano-Terriza, Risalde, Jiménez-Ruiz, Vicente, Isla, Paniagua, Moreno, Gortázar, Infantes-Lorenzo and García-Bocanegra2018; Gortazar et al. Reference Gortázar, Reperant, Kuiken, de la Fuente, Boadella, Martínez-López, Ruiz-Fons, Estrada-Peña, Drosten, Medley, Ostfeld, Peterson, VerCauteren, Menge, Artois, Schultsz, Delahay, Serra-Cobo, Poulin, Keck, Aguirre, Henttonen, Dobson, Kutz, Lubroth, Mysterud and Racaniello2014; Mörner et al., Reference Mörner, Obendorf, Artois and Woodford2002; Palencia et al., Reference Palencia, Blome, Brook, Ferroglio, Jo, Linden, Montoro, Penrith, Plhal, Vicente, Viltrop and Gortázar2023a). WHM schemes should combine broad and inclusive general surveillance networks with targeted sampling schemes targeting priority hosts and pathogens, but flexible enough to adapt to emerging ones (Cardoso et al., Reference Cardoso, García-Bocanegra, Acevedo, Cáceres, Alves and Gortázar2022). However, multiple limitations constrain the implementation of WHM and bias our understanding of the epidemiology of shared pathogens at the human-domestic animals–wildlife interface. Funding the capacity building, infrastructure, and budget needs of a modern and complete WHM scheme is the obvious and most relevant concern.

General surveillance

General surveillance depends on heterogeneous actors with differential specific weights of wildlife rehabilitation centers and the eventual involvement of hunter and conservation associations, roadkill monitoring networks, or citizen science initiatives (Lawson et al., Reference Lawson, Petrovan and Cunningham2015; Schwartz et al., Reference Schwartz, Shilling and Perkins2020). This generates two limitations: first, the scale and distribution of general WHM are heterogenous, non-stratified, and often do not match the distribution of the targeted sampling and monitoring networks; second, since most of these stakeholders are not directly linked to the human and animal health authorities, information is frequently lost or miscommunicated between the sources generating the data and the health authorities. Similarly, targeted WHM schemes are generally led by animal health authorities, who do not always communicate straightforward with human health authorities, environment and fish and game authorities, and the stakeholders involved in general WHM. Therefore, there is a need to improve and standardize general WHM data collection and communication bidirectionally, so the stakeholders participating in the basis of general WHM get a feedback of their involvement (Boadella et al., Reference Boadella, Gortázar, Acevedo, Carta, Martín-Hernando, de la Fuente and Vicente2011a), as well as improving information sharing among authorities across administration compartments (Gortázar et al., Reference Gortázar, Ruiz-Fons and Höfle2016).

Targeted surveillance

The first limitation of targeted surveillance (sometimes also affecting general surveillance) is the impossibility to effectively monitor all the pathogens potentially present and/or emerging in all the potential host species in a system. Consequently, targeted WHM schemes have traditionally focused on wild ungulate and bird diseases known to have an impact on human and/or livestock health, giving less relevance to diseases mostly relevant for wildlife (Gortázar et al., Reference Gortázar, Ferroglio, Höfle, Frölich and Vicente2007; Martin et al., Reference Martin, Pastoret, Brochier, Humblet and Saegerman2011; Miller et al., Reference Miller, Farnsworth and Malmberg2013; Wiethoelter et al., Reference Wiethoelter, Beltran-Alcrudo, Kock and Mor2015; Hassell et al., Reference Hassell, Begon, Ward and Fèvre2017; Wiethoelter et al., Reference Wiethoelter, Beltran-Alcrudo, Kock and Mor2015). However, this approach ignores the potentiality for pathogens to jump the taxon barrier and becoming zoonotic or eventually pandemic, as repeatedly shown by different pathogens (Dudas et al., Reference Dudas, Carvalho, Rambaut and Bedford2018; Dhama et al., Reference Dhama, Patel, Sharun, Pathak, Tiwari, Yatoo, Malik, Sah, Rabaan, Panwar, Singh, Michalak, Chaicumpa, Martínez-Pulgarín, Bonilla-Aldana and Rodríguez-Morales2020; Gortazar et al. Reference Gortázar, Reperant, Kuiken, de la Fuente, Boadella, Martínez-López, Ruiz-Fons, Estrada-Peña, Drosten, Medley, Ostfeld, Peterson, VerCauteren, Menge, Artois, Schultsz, Delahay, Serra-Cobo, Poulin, Keck, Aguirre, Henttonen, Dobson, Kutz, Lubroth, Mysterud and Racaniello2014; Riedel, Reference Riedel2006). Adaptive protocols have been suggested for early detection of diseases newly introduced in a system (Miller et al., Reference Miller, Bevins, Cook, Free, Pepin, Gidlewski and Brown2022).

By comprehensively and holistically monitoring the whole system, including pathogens, hosts, and their networks and relationships, IWM should achieve a better capability of monitoring known pathogens and detecting new ones. Once the host network has been analyzed, the most suitable indicator species and target pathogens can be identified. Ideal indicator species would be widespread, abundant, central in the host community contact network, easy to sample, and prone to get infected or develop antibodies against a broad range of relevant pathogens. While the Eurasian wild boar (Sus scrofa) matches these requirements in most of the systems where it is present (Figure 2), other hosts such as common and widespread rodents (e.g., genus Apodemus in Europe) or carnivores such as the red fox (Vulpes vulpes) can also be potentially good indicator species (Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023; Mazzotta et al., Reference Mazzotta, Bellinati, Bertasio, Boniotti, Lucchese, Ceglie, Martignago, Leopardi and Natale2023). Bats have been reported as reservoir of zoonotic diseases at the wildlife livestock–human interface, particularly in tropical regions, and are often forgotten by WMH schemes (Calisher et al., Reference Calisher, Childs, Field, Holmes and Schountz2006; Allocati et al., Reference Allocati, Petrucci, Di Giovanni, Masulli, Di Ilio and De Laurenzi2016; Serra-Cobo and López-Roig, Reference Serra-Cobo and López-Roig2016), so they probably are a worthy target host for IWM.

Figure 2. Wild boar as indicator species: main characteristics and examples of pathogens which can be monitored through wild boar serology.

As for the key shared pathogens to target through WMH for IWM, those present or endemic in the system are generally known, although focusing WHM on the zoonotic aspect, the conservation approach, or the animal health perspective will drive the prioritization of such pathogens differently (ENETWILD consortium et al. Reference Ferroglio, Avagnina, Barroso, Benatti, Cardoso, Gómez, Goncalves, Neimanis, Poncina, Ruiz Rodríguez, Vada, Vicente, Zanet and Gavier‐Widén D2022; Gortázar et al., Reference Gortázar, Ruiz-Fons and Höfle2016). However, the potential emergence of new pathogens (Miller et al., Reference Miller, Bevins, Cook, Free, Pepin, Gidlewski and Brown2022) warrants nonspecific search through nonspecific sampling and analysis for pathogen groups, allowing the early detection of different and emerging pathogens and not only those already present in the system.

Since several transmission cycles can occur simultaneously in a system, more than one indicator host species and pathogen should be targeted to achieve a complete WHM. In industrialized countries, the scope of targeted WHM is limited by funding and logistic limitations, whereas in less studied regions with more limited resources the identification of both suitable indicator species and target pathogens remains challenging (Table 1).

Table 1. The perspective (limitations and challenges) on integrated wildlife monitoring (IWM) development in industrialized countries and in low- and middle-income countries (LMICs)

Another technological and budgetary limitation of targeted WHM emerges from sampling, shipping, and storing representative numbers of biological materials such as blood, serum, lymphoid tissues, and ectoparasites. While collecting a representative sample size of the indicator species in each system can already be challenging and time- and effort-consuming, particularly for small species such as rodents, bats, or carnivores as compared to game species (Maaz et al., Reference Maaz, Gremse, Stollberg, Jäckel, Sutrave, Kästner, Korkmaz, Richter, Bandick, Steinhoff-Wagner, Lahrssen-Wiederholt and Mader2022; Mazzotta et al., Reference Mazzotta, Bellinati, Bertasio, Boniotti, Lucchese, Ceglie, Martignago, Leopardi and Natale2023), methodologies allowing the identification of shared pathogens through environmental sampling could create a whole new wide range of possibilities for IWM (Martínez-Guijosa et al., Reference Martínez-Guijosa, Romero, Infantes-Lorenzo, Díez, Boadella, Balseiro, Veiga, Navarro, Moreno, Ferreres, Domínguez, Fernández, Domínguez, Gortázar and Serrano2020).

Regarding analyses, antibody detection tests are originally designed and validated for domestic species and diagnosis in wildlife consequently faces specific challenges (Michel et al., Reference Michel, Van Heerden, Crossley, Al Dahouk, Prasse and Rutten2021). Nevertheless, reliable antibody detection tests have been well-established for most of the relevant host-pathogen combinations (e.g., Godfroid et al., Reference Godfroid, Nielsen and Saegerman2010; Boadella et al., Reference Boadella, Lyashchenko, Greenwald, Esfandiari, Jaroso, Carta, Garrido, Vicente, de la Fuente and Gortázar2011b; Elmore et al., Reference Elmore, Samelius, Al-Adhami, Huyvaert, Bailey, Alisauskas, Gajadhar and Jenkins2016; Raez-Bravo et al., Reference Ráez-Bravo, Granados, Serrano, Dellamaria, Casais, Rossi, Puigdemont, Cano-Manuel, Fandos, Pérez, Espinosa, Soriguer, Citterio and López-Olvera2016; Thomas et al., Reference Thomas, Balseiro, Gortázar and Risalde2021; Luo et al., Reference Luo, Shoemaker, Pak and Marqusee2023). Additionally, pathogen molecular detection tests are equally valid in domestic animals and wildlife and readily available, at least in industrialized countries.

National and international regulations for sample collection, transport, storage, and analyses for infection diagnosis are an additional constraint to achieve the comprehensive WHM required for IWM. For instance, only public laboratories or reference laboratories might be allowed to perform certain techniques, and some authorities might be reluctant or even prohibit taking or analyzing samples from their territory. Intranational differences in regionalized countries such as Belgium, Germany, Italy, and Spain add complexity, difficulties, and bureaucratic issues hampering the effective establishment of WHM and the adequate preventive or management measures (Uchtmann et al., Reference Uchtmann, Herrmann, Hahn and Beasley2015). At each level, racing against each other and betting on being the last one to notify a disease seems sometimes the goal rather than collaborating in establishing comprehensive, holistic, and harmonized WHM and IWM. The perspective of low- and middle-income countries (LMICs) is synthesized in Table 1.

Section 2: HCM limitations and biases

Epidemiological evidence derived from observational and experimental studies suggests that shared multi-host pathogens are rarely best described as single or two-host systems, where only certain species are regarded as maintenance (Nugent, Reference Nugent2011). Rather, most multi-host pathogens thrive in complex and dynamic “maintenance communities” where different wild and domestic species and the environment contribute to build networks facilitating pathogen transmission and survival (Gortázar et al., Reference Gortázar, de la Fuente, Perelló and Domínguez2023).

Assessing wildlife population abundance and density is challenging, and new methodologies are increasingly being proposed and contrasted against traditional methods (APHAEA Consortium, 2023; ENETWILD consortium et al. Reference Keuling, Sange, Acevedo, Podgorski, Smith, Scandura, Apollonio, Ferroglio and Vicente2018; Iijima, Reference Iijima2020). The objectives of wildlife population estimations can be (1) censusing all the animals; (2) estimating the population abundance/density without seeing all the animals; or (3) obtaining population indices (Lancia et al., Reference Lancia, Nichols, Pollock and Bookhout1994; Witmer, Reference Witmer2005). Censusing or counting all the animals is generally unfeasible and habitat-dependent, thus such methods are difficult to standardize, harmonize, transfer among different locations, and apply on wider scales (ENETWILD consortium et al. 2020). Each population monitoring method has pros and cons, but in general it should be reliable (accurate and precise to allow time trend analysis), with the potential to be used as a reference to validate and calibrate other methods, and provide density estimates rather than relative abundances (ENETWILD consortium et al. 2020; Palencia et al., Reference Palencia, Rowcliffe, Vicente and Acevedo2021a). The methods could vary for different target species, but they should also be well-established, repeatable, suitable for a broad range of settings and species, and accessible to all actors including, for example, hunters and private gamekeepers or fish and game officers (Acevedo et al., Reference Acevedo, Vicente, Höfle, Cassinello, Ruiz-Fons and Gortázar2007; Sobrino et al., Reference Sobrino, Acevedo, Escudero, Marco and Gortázar2009; Palencia et al., Reference Palencia, Vicente, Soriguer and Acevedo2021b; Ruiz-Rodriguez et al., Reference Ruiz-Rodríguez, Blanco-Aguiar, Gómez-Molina, Illanas, Fernández-López, Acevedo and Vicente2022; Sobrino et al., Reference Sobrino, Acevedo, Escudero, Marco and Gortázar2009). However, all these methods to estimate wildlife population abundance and/or density usually focus on a single species, while pathogens are usually maintained in a multi-host network community (Fenton and Pedersen, Reference Fenton and Pedersen2005; Godfrey, Reference Godfrey2013; Portier et al., Reference Portier, Ryser-Degiorgis, Hutchings, Monchâtre-Leroy, Richomme, Larrat, van der Poel, Domínguez, Linden, Santos, Warns-Petit, Chollet, Cavalerie, Grandmontagne, Boadella, Bonbon and Artois2019). This single-host approach can be useful for the selected key indicator species in the network, but it fails to capture the biodiversity and its potential effect on pathogen epidemiology dynamics (Barasona et al., Reference Barasona, Gortázar, de la Fuente and Vicente2019; Keesing and Ostfeld, Reference Keesing and Ostfeld2021; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023). Such biodiversity assessment is a key added value of IWM, and integrative methodologies capable of assessing and monitoring multi-species populations are required to capture the epidemiological complexity of multi-host systems (Robinson et al., Reference Robinson, Morrison and Baillie2014; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023).

Advanced IWM schemes such as that implemented in Spain consider two aspects of the host populations, namely (1) host community characterization and (2) host population monitoring (Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023). Host community characterization describes the host community composition and identifies through network contact analysis the key species considering the regionally relevant diseases, which can be used as indicator species. However, since all vertebrate species are potentially relevant as indicators, victims, reservoirs, or bridge hosts for either known or emerging disease agents (Gortázar et al., Reference Gortázar, Barroso, Nova and Cáceres2021), an inventory of vertebrate richness is advisable. Species richness is also an index of biodiversity and can generate information to tackle the debate on the dilution effect or an increase in the circulation of at least certain pathogens due to higher host availability (Barasona et al., Reference Barasona, Gortázar, de la Fuente and Vicente2019; Keesing and Ostfeld, Reference Keesing and Ostfeld2021; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023). The quantification of both direct and indirect contacts of relevant host species achieved through the network analysis should allow an understanding of pathogen transmission and circulation dynamics, as well as identifying the role of key host species in infection maintenance. Furthermore, the host community characterization should include identifying the main risk points for cross-species interactions, such as baiting sites or waterholes (Barasona et al., Reference Barasona, Latham, Acevedo, Armenteros, Latham, Gortázar, Carro, Soriguer and Vicente2014a; Payne et al., Reference Payne, Philipon, Hars, Dufour and Gilot-Fromont2017; González-Crespo et al., 2023a, Reference González-Crespo, Martínez-López, Conejero, Castillo-Contreras, Serrano, López-Martín, Lavín and López-Olvera2023b).

HCM should at least include monitoring the relative abundance and spatial distribution of relevant hosts through time. Ideally, densities of indicator hosts should also be monitored, although this significantly increases the associated costs and efforts (Acevedo et al., Reference Acevedo, Ruiz-Fons, Vicente, Reyes-García, Alzaga and Gortázar2008; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023; ENETWILD consortium et al. 2020). Moreover, since disease and associated mortality often affect differently host sex and age classes (López-Olvera et al., Reference López-Olvera, Fernández-de-Mera, Serrano, Vidal, Vicente, Fierro and Gortázar2013; Garrido-Amaro et al., 2015, Reference Garrido-Amaro, Jolles, Velarde, López-Olvera and Serrano2023), population estimation methodologies that permit identifying age and sex in indicator host species should allow the establishment of population structure as an early nonspecific index of morbidity and mortality, thus contributing to general WHM.

Finally, population assessment methods, effort, and hence the quality and quantity of the information generated face the same territorial, political, and bureaucratic issues as aforementioned for WHM, varying not only among countries but even within countries (Ruiz-Rodríguez et al., Reference Ruiz-Rodríguez, Blanco-Aguiar, Gómez-Molina, Illanas, Fernández-López, Acevedo and Vicentesubmitted). Relevant changes in wildlife or livestock management should also be recorded as these will influence host populations.

Advances in population monitoring methodologies

Newer techniques to estimate wildlife population abundance and/or density are traditionally validated against the formerly existing ones, considered the reference methodology. Methodology-biased indices can significantly affect wildlife population abundance and/or density estimations and consequently HCM and IWM (ENETWILD consortium et al. 2020; Norvell et al., Reference Norvell, Howe and Parrish2003; Moore and Kendall, Reference Moore and Kendall2004; Le Moullec et al., Reference Le Moullec, Pedersen, Yoccoz, Aanes, Tufto and Hansen2017; Palencia et al. Reference Palencia, Rowcliffe, Vicente and Acevedo2021a,Reference Palencia, Vicente, Soriguer and Acevedo2021b). The availability of low-cost electronic devices has led to their consideration as tools to assess and monitor wildlife populations, including unmanned aerial vehicles, CT, genetic analyses, and sound detection (Gardner et al., Reference Gardner, Reppucci, Lucherini and Royle2010; Luikart et al., Reference Luikart, Ryman, Tallmon, Schwartz and Allendorf2010; Trolliet et al., Reference Trolliet, Huynen, Vermeulen and A2014; Barasona et al., Reference Barasona, Mulero-Pázmány, Acevedo, Negro, Torres, Gortázar and Vicente2014b; Linchant et al., Reference Linchant, Lisein, Semeki, Lejeune and Vermeulen2015; Hodgson et al., Reference Hodgson, Baylis, Mott, Herrod and Clarke2016; Lyons et al., Reference Lyons, Brandis, Murray, Wilshire, McCann, Kingsford, Callaghan and Shepard2019; Beaver et al., Reference Beaver, Baldwin, Messinger, Newbolt, Ditchkoff and Silman2020; Yip et al., Reference Yip, Knight, Haave‐Audet, Wilson, Charchuk, Scott, Sólymos and Bayne2020; Palencia et al., Reference Palencia, Rowcliffe, Vicente and Acevedo2021a; Mason et al., Reference Mason, Hill, Whittingham, Cokill, Smith and Stephens2022). However, when considered for HCM as a part of IWM, the methodologies used for population estimation must not only be reliable and validated, but also accomplish the requirements, particularly regarding capability of use in different habitats, multi-species detection, and reasonable cost (Acevedo et al., Reference Acevedo, Ruiz-Fons, Vicente, Reyes-García, Alzaga and Gortázar2008; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023; ENETWILD consortium et al. 2020; Hofmeester et al., Reference Hofmeester, Cromsigt, Odden, Andrén, Kindberg and Linnell2019). Genetic assessment of wildlife population is far too costly and restricted in species scope, while unmanned aerial vehicles, even if coupled with infrared sensors, cannot be used in all kinds of habitats (e.g., forests) and do only detect a limited variability of potential hosts. Therefore, CT is probably the new technology with the highest potential to become a useful tool for IWM, not only overcoming the mentioned limitations but also adding value and capabilities in the detection of host species beyond those identified through the traditional population estimations methodologies. Although less developed and still being tested as a proof of concept, sound detection of species can be relevant, particularly for the taxa more difficult to detect with other methods (including CT) and traditionally underestimated or ignored in HCM and WHM, such as birds, small mammals, and bats.

CT provides advantages as compared to other methods, since it generates information regarding both aspects of the host populations. Occasionally, camera traps deployed for population monitoring will generate wildlife disease surveillance data for diseases with visible signs, such as mange (Oleaga et al., Reference Oleaga, Casais, Balseiro, Espí, Llaneza, Hartasánchez and Gortázar2011). However, the financial and logistical barriers for CT at broad geographical scales are a concern (Steenweg et al., Reference Steenweg, Hebblewhite, Kays, Ahumada, Fisher, Burton, Townsend, Carbone, Rowcliffe, Whittington, Brodie, Royle, Switalski, Clevenger, Heim and Rich2017). One limitation to including HCM on IWM systems is the initial cost associated with camera purchase. The number of camera traps deployed and the time these cameras remain in the field determine our capability to (i) obtain reliable estimates of population density (Palencia et al., Reference Palencia, Barroso, Vicente, Hofmeester, Ferreres and Acevedo2022), and (ii) characterize host communities in terms of composition and structure (Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023).

On a local scale (e.g., management units), CT is a method that can be conducted in different environmental conditions and at any time to collect robust data, taking advantage of the multi-species reliability (Palencia et al., Reference Palencia, Barroso, Vicente, Hofmeester, Ferreres and Acevedo2022). In open areas, with high detectability, direct methods such as vantage points and linear transects could be recommended against CT, especially in areas in which high vandalism is expected increasing the cost of camera repositioning and reducing the data recorded. If direct methods are selected survey design and reference method should be adapted to each species.

Limitations will depend on the socioeconomic context and are listed in Table 1. One challenge is finding the balance between field and deskwork effort and information yield. As mentioned above, the number of camera traps deployed in the field and the number of days of camera trap activity influence the reliability of population density estimates and the accuracy of the host community characterization. In our experience in Spain, 70%–80% of the detectable species were detected after 18 days of functioning and 8.5 camera traps (Figure 3). Camera traps can generate tremendous amounts of image data, and thus, attention has been given to developing artificial intelligence approaches for processing images. These allow scientists to remove empty images, identify species, count individuals in an image, and individual recognition (Vélez et al., Reference Vélez, McShea, Shamon, Castiblanco‐Camacho, Tabak, Chalmers, Fergus and Fieberg2023). Photogrammetry tools are used to save time and gain precision in animal density estimation (Palencia et al., Reference Palencia, Vada, Zanet, Calvini, De Giovanni, Gola, Ferroglio and Chen2023b). Other aspects to consider include the variations between camera trap models (Palencia et al., Reference Palencia, Vicente, Soriguer and Acevedo2021b), and choosing the right camera trap settings for a broad range of study species (Hofmeester et al., Reference Hofmeester, Cromsigt, Odden, Andrén, Kindberg and Linnell2019). Finally, there is a need to identify biases in the detection of species and quantification of interspecies interactions due to differences in size, movement ecology, and habitat preferences (Hofmeester et al., Reference Hofmeester, Thorsen, Cromsigt, Kindberg, Andrén, Linnell and Odden2021). Moreover, camera traps are not the universal solution as they face strong limitations in the biodiversity assessment of taxa other than terrestrial mammals (Ortmann and Johnson, Reference Ortmann and Johnson2021). Addressing bird diversity, for instance, implies involving trained ornithologists or, eventually, making use of AI-based sound identification devices (Toenies and Rich, Reference Toenies and Rich2021). Similar devices are used for bat monitoring (Russo and Voigt, Reference Russo and Voigt2016).

Figure 3. Percentage of species detected depending on the number of camera traps deployed in the field and the effort in days (number of operative days). Data was obtained from a nationwide pilot trial on integrated wildlife monitoring in Spain.

Proposed solutions

Table 2 lists the main limitations to IWM identified in the sections above, along with suggested solutions for each one. Of the two general limitations, funding, and harmonization, the second one would seem easier to solve. There is potential to overcome four of these 11 limitations through increased information exchange and transparency and promoting collaborative and inclusive workflows. A further three limitations need, at least partially, to be addressed through ongoing research, two of them possibly with the support of artificial intelligence. Furthermore, a few technical innovations might contribute to IWM optimization, namely sound identification artificial intelligence, nonspecific health markers, microfluidic PCR, filter paper samples, and environmental nucleic acid detection, as specified above.

Table 2. Main limitations found in the development of each component of integrated wildlife monitoring (IWM) systems and solutions proposed

General discussion

Current wildlife health surveillance schemes present major flaws (Ryser-Degiorgis, Reference Ryser-Degiorgis2013; OIE, 2019; Lawson et al., Reference Lawson, Neimanis, Lavazza, López-Olvera, Tavernier, Billinis, Duff, Mladenov, Rijks, Savić, Wibbelt, Ryser-Degiorgis and Kuiken2021; Machalaba et al., Reference Machalaba, Uhart, Ryser-Degiorgis and Karesh2021; Giacinti et al., Reference Giacinti, Pearl, Ojkic, Campbell and Jardine2022; Mazzamuto et al., Reference Mazzamuto, Schilling and Romeo2022; Delgado et al., Reference Delgado, Ferrari, Fanelli, Muset, Thompson, Sleeman, White, Walsh, Wannous and Tizzani2023; Pruvot et al., Reference Pruvot, Denstedt, Latinne, Porco, Montecino-Latorre, Khammavong, Milavong, Phouangsouvanh, Sisavanh, Nga, Ngoc, Thanh, Chea, Sours, Phommachanh, Theppangna, Phiphakhavong, Vanna, Masphal, Sothyra, San, Chamnan, Long, Diep, Duoc, Zimmer, Brown, Olson and Fine2023) and have not been able to forecast and prevent the onset of new epidemics jumping interspecific barriers and even becoming pandemics (Konda et al., Reference Konda, Dodda, Konala, Naramala and Adapa2020; Delahay et al., Reference Delahay, de la Fuente, Smith, Sharun, Snary, Flores Girón, Nziza, Fooks, Brookes, Lean, Breed and Gortázar2021; Sharun et al., Reference Sharun, Dhama, Pawde, Gortázar, Tiwari, Bonilla-Aldana, Rodríguez-Morales, de la Fuente, Michalak and Attia2021; Keusch et al., Reference Keusch, Amuasi, Anderson, Daszak, Eckerle, Field, Koopmans, Lam, Das Neves, Peiris, Perlman, Wacharapluesadee, Yadana and Saif2022). The combination of WHM and HCM to achieve effective IWM has the potential to overcome these limitations, but it also faces new challenges and biases that must be considered and addressed when implementing IWM. Some of these limitations are inherited from conceptions of the former WHM schemes, as the restricted scope of host and pathogen monitoring biased to species phylogenetically related to and diseases shared with domestic livestock, respectively (Wiethoelter et al., Reference Wiethoelter, Beltran-Alcrudo, Kock and Mor2015), which leaves aside potentially sources of new pathogens such as rodents or bats, as well as pathogens from out of the system (Mazzotta et al., Reference Mazzotta, Bellinati, Bertasio, Boniotti, Lucchese, Ceglie, Martignago, Leopardi and Natale2023). Since monitoring all the vertebrate hosts and pathogens in a system is physically impossible, selecting indicator host species through network analysis (Godfrey, Reference Godfrey2013; Gortázar et al., Reference Gortázar, Barroso, Nova and Cáceres2021; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023) and identifying key pathogens to investigate and monitor covering the main transmission pathways (Ciliberti et al., Reference Ciliberti, Gavier-Widén, Yon, Hutchings and Artois2015; ENETWILD consortium et al. Reference Ferroglio, Avagnina, Barroso, Benatti, Cardoso, Gómez, Goncalves, Neimanis, Poncina, Ruiz Rodríguez, Vada, Vicente, Zanet and Gavier‐Widén D2022) should allow IWM to overcome the limitations of previous schemes. Since host contact and interactions leading to potential disease transmission are heterogeneous, interspecific social network analyses are useful for wildlife disease ecology, epidemiology, and management beyond the traditionally assumed density-dependent models. The individuals (in intraspecific analyses) and species (in interspecific analyses, sometimes including pathogens) with higher and closer contact rates with other individuals or species are potentially more relevant for pathogen maintenance, transmission, and circulation (Craft and Caillaud, Reference Craft and Caillaud2011; Craft, Reference Craft2015; Silk et al., Reference Silk, Croft, Delahay, Hodgson, Boots, Weber and McDonald2017, Reference Silk, Hodgson, Rozins, Croft, Delahay, Boots and McDonald2019; González-Crespo et al., 2023a; Silk et al., Reference Silk, Croft, Delahay, Hodgson, Boots, Weber and McDonald2017). Thus, network analysis within the HCM component of IWM can contribute to identify the ideal target host species to monitor diseases in the most cost and effort-efficient way. Moreover, when coupling the information from network analyses with the information on disease susceptibility and prevalence obtained through targeted surveillance within the WHM, the selection can be further refined to specific host species-pathogen combinations. Such procedure has allowed, for example, identifying the wildlife hosts of Rift Valley fever virus (Walsh and Mor, Reference Walsh and Mor2018) or selecting wild boar as the most relevant host species for IWM in Mediterranean environments (Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023; Figure 4). Once selected the ideal host species-pathogen combinations in each system, the correspondence between the prevalence and population trend of the indicator host species and the global prevalence and population dynamics of the hole system, as monitored through IWM, should allow the validation of such choice.

Figure 4. Illustrative cases of integrated wildlife monitoring: a theoretical approach for Rift Valley fever virus in Africa and the Arabian Peninsula and a practical pilot study in Spain.

As compared to previous WHM schemes focused on limited host species and pathogens, the main step forward of IWM is adding HCM to WHM (Cardoso et al., Reference Cardoso, García-Bocanegra, Acevedo, Cáceres, Alves and Gortázar2022; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023). Within WHM, general disease surveillance generates reports of disease or mortality outbreaks to the corresponding national and international health authorities, thus improving the likelihood of early detection of emerging diseases. The periodic (usually annual) disease analyses obtained through targeted surveillance do not only allow the early detection of the targeted pathogens in areas where they were absent, but also, and more importantly, the monitoring of diseases already present in the system and identify their drivers. As for HCM, the spatial characterization of host community allows to identify both geographic hotspots and key species for disease maintenance and transmission, providing wildlife population managers and animal health authorities with specific targets to increase the efficacy and efficiency of mitigation measures. Finally, the regular monitoring of host populations allows the analysis of population trends, which wildlife managers and other can use both for quantitatively assessing the related disease-transmission risk and for the detection of potential epidemics onsets (Figure 1). By merging both HCM and WHM, IWM allows a comprehensive understanding of role of each species in pathogen transmission and maintenance, transmission routes, and disease status in a system (Fenton and Pedersen, Reference Fenton and Pedersen2005; Pepin et al., Reference Pepin, Kay, Golas, Shriner, Gilbert, Miller, Graham, Riley, Cross, Samuel, Hooten, Hoeting, Lloyd‐Smith, Webb, Buhnerkempe and Aubry2017; Gortázar et al., Reference Gortázar, Barroso, Nova and Cáceres2021), requiring collaboration among health, wildlife, and livestock authorities and managers. Furthermore, achieving knowledge of the host community assemblage allows identifying the drivers of epidemiology and infection within the system (Martínez-López et al., Reference Martínez-López, Pérez and Sánchez-Vizcaíno2009; Barasona et al., Reference Barasona, Gortázar, de la Fuente and Vicente2019; Triguero-Ocaña et al., Reference Triguero-Ocaña, Martínez-López, Vicente, Barasona, Martínez-Guijosa and Acevedo2020; Barroso et al., Reference Barroso, Relimpio, Zearra, Cerón, Palencia, Cardoso, Ferreras, Escobar, Cáceres, López-Olvera and Gortázar2023), and monitoring the host network community and the population structure of the indicator host species provide additional early indicators of trends and changes in disease and mortality through network imbalances before the pathogen crosses the interspecies barrier (Craft, Reference Craft2015; Espinaze et al., Reference Espinaze, Hellard, Horak and Cumming2018; Garrido-Amaro et al., Reference Garrido-Amaro, Jolles, Velarde, López-Olvera and Serrano2023).

Nevertheless, IWM has also drawbacks, limitations, and constraints beyond the restricted scope of each one of its components. Both WHM and HCM have associated costs and are labor-intensive, which raise funding constraints and logistic limitations, respectively. Such constraint and limitations are logically more difficult to overcome in LMICs without ongoing IWM (Table 1). This study proposes solutions aimed at addressing and overcome such limitations and constraints both in industrialized and LMIC countries (Table 2).

Additionally, methodological limitations are also challenging to achieve comprehensive IWM. Upcoming sampling and diagnostic techniques may contribute to increase and widen the pathogen range covered by WHM, new methodologies to estimate population density and abundance may allow a more complete assessment of biodiversity and the populations of the indicator species identified by the network analysis. However, the sampling and diagnostic techniques, the population estimation methodologies, and the network analyses performed will vary in their capability to identify pathogens, hosts, and indicator species, leading to biases that must be taken into account when assessing the actual performance of IWM schemes. Further characterization of such biases through comparative assessment of the aforementioned techniques, methodologies, and analyses will help to be aware of the limitations of the resulting IWM.

Conclusion

To summarize, IWM is the necessary step beyond to target the management of shared diseases from a One Health approach and preventing future pandemics. However, IWM must still face serious scope, funding, logistic, and methodological challenges to be implemented, particularly in LMIC countries. This study proposes solutions aimed at addressing and overcome such limitations and constraints both in industrialized and LMIC countries.

Data availability statement

Not applicable.

Author contribution

Patricia Barroso: Conceptualization, visualization, writing – original draft, and writing – review and editing; Théophile: writing – original draft and writing – review and editing; Jorge Ramón López-Olvera: conceptualization, supervision, validation, visualization, writing – original draft, and writing – review and editing; Christian Gortázar: conceptualization, supervision, validation, visualization, writing – original draft, and writing – review and editing.

Financial support

This research received no specific grant from any funding agency, commercial, or not-for-profit sectors. P.B. was supported by the EU-NextGenerationEU funds through the 2022–2024 Margarita Salas call for the requalification of the Spanish University System, convened by the University of Castilla-La Mancha.

Competing interests

None.

Ethics statement

Ethical approval and consent are not relevant to this article type.

References

Connections references

Stephen, C. (2023). How do the practical and pragmatic limitations in the design or implementation of wildlife disease surveillance systems bias our understanding of the drivers, epidemiology, and impact of pathogen traffic between wildlife and people or domestic species, or within wildlife host populations? Research Directions: One Health, 1, e4, 1. https://doi.org/10.1017/one.2022.5Google Scholar

References

Acevedo, P, Ruiz-Fons, F, Vicente, J, Reyes-García, AR, Alzaga, V and Gortázar, C (2008) Estimating red deer abundance in a wide range of management situations in Mediterranean habitats. Journal of Zoology 276, 1, 3747. https://doi.org/10.1111/j.1469-7998.2008.00464.x.CrossRefGoogle Scholar
Acevedo, P, Vicente, J, Höfle, U, Cassinello, J, Ruiz-Fons, F and Gortázar, C (2007) Estimation of European wild boar relative abundance and aggregation: a novel method in epidemiological risk assessment. Epidemiology and Infection 135, 3, 519527. https://doi.org/10.1017/S0950268806007059.CrossRefGoogle ScholarPubMed
Allocati, N, Petrucci, AG, Di Giovanni, P, Masulli, M, Di Ilio, C and De Laurenzi, V (2016) Bat-man disease transmission: zoonotic pathogens from wildlife reservoirs to human populations. Cell Death Discovery 2, 1, 16048. https://doi.org/10.1038/cddiscovery.2016.48.CrossRefGoogle ScholarPubMed
APHAEA Consortium (2023) Harmonised approaches in monitoring wildlife population health, and ecology and abundance (APHAEA). Available at https://www.aphaea.eu/cards/species.Google Scholar
Artois, M, Ben Jebara, K, Warns-Petit, E and Leighton, FA (2012) National wildlife disease surveillance systems. In Animal Health and Biodiversity: Preparing for the Future. Compendium of the OIE Global Conference on Wildlife, Paris, France.Google Scholar
Artois, M, Bengis, R, Delahay, RJ, Smith, GC and Hutchings, MR (2009) Wildlife disease surveillance and monitoring. In Management of Disease in Wild Mammals. Tokyo: Springer Japan, pp. 187213. https://doi.org/10.1007/978-4-431-77134-0_10.CrossRefGoogle Scholar
Barasona, JA, Gortázar, C, de la Fuente, J and Vicente, J (2019) Host richness increases tuberculosis disease risk in game-managed areas. Microorganisms 7, 6, 182. https://doi.org/10.3390/microorganisms7060182.CrossRefGoogle ScholarPubMed
Barasona, JA, Latham, MC, Acevedo, P, Armenteros, JA, Latham, ADM, Gortázar, C, Carro, F, Soriguer, RC and Vicente, J (2014a) Spatiotemporal interactions between wild boar and cattle: implications for cross-species disease transmission. Veterinary Research 45, 1, 122. https://doi.org/10.1186/s13567-014-0122-7.CrossRefGoogle ScholarPubMed
Barasona, JA, Mulero-Pázmány, M, Acevedo, P, Negro, JJ, Torres, MJ, Gortázar, C and Vicente, J (2014b) Unmanned aircraft systems for studying spatial abundance of ungulates: relevance to spatial epidemiology. PLoS ONE 9, 12, e115608. https://doi.org/10.1371/journal.pone.0115608.CrossRefGoogle ScholarPubMed
Barroso, P, Barasona, JA, Acevedo, P, Palencia, P, Carro, F, Negro, JJ, Torres, MJ, Gortázar, C, Soriguer, RC and Vicente, J (2020a) Long-term determinants of tuberculosis in the ungulate host community of Doñana National Park. Pathogens 9, 6, 445. https://doi.org/10.3390/pathogens9060445.CrossRefGoogle ScholarPubMed
Barroso, P, García-Bocanegra, I, Acevedo, P, Palencia, P, Carro, F, Jiménez-Ruiz, S, Almería, S, Dubey, JP, Cano-Terriza, D and Vicente, J (2020b) Long-term determinants of the seroprevalence of Toxoplasma gondii in a wild ungulate community. Animals 10, 12, 2349. https://doi.org/10.3390/ani10122349.CrossRefGoogle Scholar
Barroso, P, Relimpio, D, Zearra, JA, Cerón, JJ, Palencia, P, Cardoso, B, Ferreras, E, Escobar, M, Cáceres, G, López-Olvera, JR and Gortázar, C (2023) Using integrated wildlife monitoring to prevent future pandemics through one health approach. One Health 16, 100479. https://doi.org/10.1016/j.onehlt.2022.100479.CrossRefGoogle ScholarPubMed
Beaver, JT, Baldwin, RW, Messinger, M, Newbolt, CH, Ditchkoff, SS and Silman, MR (2020) Evaluating the use of drones equipped with thermal sensors as an effective method for estimating wildlife. Wildlife Society Bulletin 44, 2, 434443. https://doi.org/10.1002/wsb.1090.CrossRefGoogle Scholar
Boadella, M, Gortázar, C, Acevedo, P, Carta, T, Martín-Hernando, MP, de la Fuente, J and Vicente, J (2011a) Six recommendations for improving monitoring of diseases shared with wildlife: examples regarding mycobacterial infections in Spain. European Journal of Wildlife Research 57, 4, 697706. https://doi.org/10.1007/s10344-011-0550-x.CrossRefGoogle Scholar
Boadella, M, Lyashchenko, K, Greenwald, R, Esfandiari, J, Jaroso, R, Carta, T, Garrido, JM, Vicente, J, de la Fuente, J and Gortázar, C (2011b) Serologic tests for detecting antibodies against Mycobacterium bovis and Mycobacterium avium subspecies paratuberculosis in Eurasian wild boar (Sus scrofa scrofa). Journal of Veterinary Diagnostic Investigation 23, 1, 7783. https://doi.org/10.1177/104063871102300111.CrossRefGoogle ScholarPubMed
Boadella, M, Vicente, J, Ruiz-Fons, F, de la Fuente, J and Gortázar, C (2012) Effects of culling Eurasian wild boar on the prevalence of Mycobacterium bovis and Aujeszky’s disease virus. Preventive Veterinary Medicine 107, 3-4, 214221. https://doi.org/10.1016/j.prevetmed.2012.06.001.CrossRefGoogle ScholarPubMed
Calisher, CH, Childs, JE, Field, HE, Holmes, KV and Schountz, T (2006) Bats: important reservoir hosts of emerging viruses. Clinical Microbiology Reviews 19, 3, 531545. https://doi.org/10.1128/CMR.00017-06.CrossRefGoogle ScholarPubMed
Cano-Terriza, D, Risalde, MA, Jiménez-Ruiz, S, Vicente, J, Isla, J, Paniagua, J, Moreno, I, Gortázar, C, Infantes-Lorenzo, JA, García-Bocanegra, I (2018) Management of hunting waste as control measure for tuberculosis in wild ungulates in south-central Spain. Transboundary and Emerging Diseases 65, 5, 11901196. https://doi.org/10.1111/tbed.12857.CrossRefGoogle ScholarPubMed
Cardoso, B, García-Bocanegra, I, Acevedo, P, Cáceres, G, Alves, PC and Gortázar, C (2022) Stepping up from wildlife disease surveillance to integrated wildlife monitoring in Europe. Research in Veterinary Science 144, 149156. https://doi.org/10.1016/j.rvsc.2021.11.003.CrossRefGoogle ScholarPubMed
Ciliberti, A, Gavier-Widén, D, Yon, L, Hutchings, MR and Artois, M (2015) Prioritisation of wildlife pathogens to be targeted in European surveillance programmes: expert-based risk analysis focus on ruminants. Preventive Veterinary Medicine 118, 4, 271284. https://doi.org/10.1016/j.prevetmed.2014.11.021.CrossRefGoogle ScholarPubMed
Cortez, MH and Duffy, MA (2021) The context-dependent effects of host competence, competition, and pathogen transmission mode on disease prevalence. The American Naturalist 198, 2, 179194. https://doi.org/10.1086/715110.CrossRefGoogle ScholarPubMed
Craft, ME (2015) Infectious disease transmission and contact networks in wildlife and livestock. Philosophical Transactions of the Royal Society B: Biological Sciences 370, 1669, 20140107. https://doi.org/10.1098/rstb.2014.0107.CrossRefGoogle ScholarPubMed
Craft, ME and Caillaud, D (2011) Network models: an underutilized tool in wildlife epidemiology? Interdisciplinary Perspectives on Infectious Diseases 2011, 112. https://doi.org/10.1155/2011/676949.CrossRefGoogle ScholarPubMed
Delahay, RJ, de la Fuente, J, Smith, GC, Sharun, K, Snary, EL, Flores Girón, L, Nziza, J, Fooks, AR, Brookes, SM, Lean, FZX, Breed, AC and Gortázar, C (2021) Assessing the risks of SARS-CoV-2 in wildlife. One Health Outlook 3, 1, 7. https://doi.org/10.1186/s42522-021-00039-6.CrossRefGoogle ScholarPubMed
Delgado, M, Ferrari, N, Fanelli, A, Muset, S, Thompson, L, Sleeman, JM, White, CL, Walsh, D, Wannous, C and Tizzani, P (2023) Wildlife health surveillance: gaps, needs and opportunities. Revue Scientifique et Technique de l’OIE 42, 161172. https://doi.org/10.20506/rst.42.3359.Google ScholarPubMed
Dhama, K, Patel, SK, Sharun, K, Pathak, M, Tiwari, R, Yatoo, MI, Malik, YS, Sah, R, Rabaan, AA, Panwar, PK, Singh, KP, Michalak, I, Chaicumpa, W, Martínez-Pulgarín, DF, Bonilla-Aldana, DK and Rodríguez-Morales, AJ (2020) SARS-CoV-2 jumping the species barrier: zoonotic lessons from SARS, MERS and recent advances to combat this pandemic virus. Travel Medicine and Infectious Disease 37, 101830. https://doi.org/10.1016/j.tmaid.2020.101830.CrossRefGoogle ScholarPubMed
Dudas, G, Carvalho, LM, Rambaut, A and Bedford, T (2018) MERS-CoV spillover at the camel-human interface. eLife 7, e31257. https://doi.org/10.7554/eLife.31257.CrossRefGoogle ScholarPubMed
EFSA (2023) European food safety authority. Available at https://www.efsa.europa.eu/en.Google Scholar
Elmore, SA, Samelius, G, Al-Adhami, B, Huyvaert, KP, Bailey, LL, Alisauskas, RT, Gajadhar, AA and Jenkins, EJ (2016) Estimating Toxoplasma gondii exposure in Arctic foxes (Vulpes lagopus) while navigating the imperfect world of wildlife serology. Journal of Wildlife Diseases 52, 1, 4756. https://doi.org/10.7589/2015-03-075.CrossRefGoogle ScholarPubMed
ENETWILD (2023) ENETWILD: Wildlife: collecting and sharing data on wildlife populations, transmitting animal disease agents. Available at https://enetwild.com/the-project/.Google Scholar
ENETWILD consortium, Ferroglio, E, Avagnina, A, Barroso, P, Benatti, F, Cardoso, B, Gómez, A, Goncalves, C, Neimanis, A, Poncina, M, Ruiz Rodríguez, C, Vada, R, Vicente, J, Zanet, S and Gavier‐Widén D, (2022) Literature review on disease ranking tools, their characterisation, and recommendations for the method to be used by EFSA. EFSA Supporting Publications 19, 9, 7578E. https://doi.org/10.2903/sp.efsa.2022.EN-7578.Google Scholar
ENETWILD consortium, Grignolio, S, Apollonio, M, Brivio, F, Vicente, J, Acevedo, P, Petrovic, K and Keuling, O (2018) Guidance on estimation of abundance and density data of wild ruminant population: methods, challenges, possibilities. EFSA Supporting Publications 17, 6, 1876E. https://doi.org/10.2903/sp.efsa.2020.EN-1876.Google Scholar
ENETWILD consortium, Keuling, O, Sange, M, Acevedo, P, Podgorski, T, Smith, G, Scandura, M, Apollonio, M, Ferroglio, E and Vicente, J (2018) Guidance on estimation of wild boar population abundance and density: methods, challenges, possibilities. EFSA Supporting Publications 15, 7, 1449E. https://doi.org/10.2903/sp.efsa.2018.EN-1449.Google Scholar
Espinaze, MPA, Hellard, E, Horak, IG and Cumming, GS (2018) Domestic mammals facilitate tick-borne pathogen transmission networks in South African wildlife. Biological Conservation 221, 228236. https://doi.org/10.1016/j.biocon.2018.03.017.CrossRefGoogle Scholar
Fenton, A and Pedersen, AB (2005) Community epidemiology framework for classifying disease threats. Emerging Infectious Diseases 11, 12, 18151821. https://doi.org/10.3201/eid1112.050306.CrossRefGoogle ScholarPubMed
Gardner, B, Reppucci, J, Lucherini, M and Royle, JA (2010) Spatially explicit inference for open populations: estimating demographic parameters from camera-trap studies. Ecology 91, 11, 33763383. https://doi.org/10.1890/09-0804.1.CrossRefGoogle ScholarPubMed
Garrido-Amaro, C, Jolles, A, Velarde, R, López-Olvera, JR and Serrano, E (2023) The synzootic potential of common epidemics in chamois populations. European Journal of Wildlife Research 69, 4, 79. https://doi.org/10.1007/s10344-023-01700-3.CrossRefGoogle Scholar
Gervasi, SS, Stephens, PR, Hua, J, Searle, CL, Xie, GY, Urbina, J, Olson, DH, Bancroft, BA, Weis, V, Hammond, JI, Relyea, RA, Blaustein, AR and Lötters, S (2017) Linking ecology and epidemiology to understand predictors of multi-host responses to an emerging pathogen, the amphibian chytrid fungus. PLOS ONE 12, 1, e0167882. https://doi.org/10.1371/journal.pone.0167882.CrossRefGoogle Scholar
Giacinti, JA, Pearl, DL, Ojkic, D, Campbell, GD and Jardine, CM (2022) Genetic characterization of canine distemper virus from wild and domestic animal submissions to diagnostic facilities in Canada. Preventive Veterinary Medicine 198, 105535. https://doi.org/10.1016/j.prevetmed.2021.105535.CrossRefGoogle ScholarPubMed
Glidden, CK, Beechler, B, Buss, PE, Charleston, B, de Klerk-Lorist, L-M, Maree, FF, Muller, T, Pérez-Martin, E, Scott, KA, van Schalkwyk, OL and Jolles, A (2018) Detection of pathogen exposure in African buffalo using non-specific markers of inflammation. Frontiers in Immunology 8, 1944. https://doi.org/10.3389/fimmu.2017.01944 .CrossRefGoogle ScholarPubMed
Godfrey, SS (2013) Networks and the ecology of parasite transmission: a framework for wildlife parasitology. International Journal for Parasitology: Parasites and Wildlife 2, 235245. https://doi.org/10.1016/j.ijppaw.2013.09.001.Google ScholarPubMed
Godfroid, J, Nielsen, K and Saegerman, C (2010) Diagnosis of brucellosis in livestock and wildlife. Croatian Medical Journal 51, 4, 296305. https://doi.org/10.3325/cmj.2010.51.296.CrossRefGoogle ScholarPubMed
González-Crespo, C, Martínez-López, B, Conejero, C, Castillo-Contreras, R, Serrano, E, López-Martín, JM, Serra-Cobo, J, Lavín, S and López-Olvera, JR (2023a) Assessing the epidemiological risk at the human-wild boar interface through a one health approach using an agent-based model in Barcelona, Spain. One Health 17, 100598. https://doi.org/10.1016/j.onehlt.2023.100598.Google Scholar
González-Crespo, C, Martínez-López, B, Conejero, C, Castillo-Contreras, R, Serrano, E, López-Martín, JM, Lavín, S and López-Olvera, JR (2023b) Predicting human-wildlife interaction in urban environments through agent-based models. Landscape and Urban Planning 240, 104878. https://doi.org/10.1016/j.landurbplan.2023.104878.CrossRefGoogle Scholar
Gortázar, C, Barroso, P, Nova, R and Cáceres, G (2021) The role of wildlife in the epidemiology and control of Foot-and-mouth-disease And Similar Transboundary (FAST) animal diseases: a review. Transboundary and Emerging Diseases 69, 5, 24622473. https://doi.org/10.1111/tbed.14235.CrossRefGoogle ScholarPubMed
Gortázar, C, de la Fuente, J, Perelló, A and Domínguez, L (2023) Will we ever eradicate animal tuberculosis? BMC Irish Veterinary Journal 76, S1, 24. https://doi.org/10.1186/s13620-023-00254-9.CrossRefGoogle ScholarPubMed
Gortázar, C, Díez-Delgado, I, Barasona, JA, Vicente, J, De La Fuente, J and Boadella, M (2015) The wild side of disease control at the wildlife-livestock-human interface: a review. Frontiers in Veterinary Science 1, 27. https://doi.org/10.3389/fvets.2014.00027.CrossRefGoogle ScholarPubMed
Gortázar, C, Ferroglio, E, Höfle, U, Frölich, K and Vicente, J (2007) Diseases shared between wildlife and livestock: a European perspective. European Journal of Wildlife Research 53, 4, 241256. https://doi.org/10.1007/s10344-007-0098-y.CrossRefGoogle Scholar
Gortázar, C, Reperant, LA, Kuiken, T, de la Fuente, J, Boadella, M, Martínez-López, B, Ruiz-Fons, F, Estrada-Peña, A, Drosten, C, Medley, G, Ostfeld, R, Peterson, T, VerCauteren, KC, Menge, C, Artois, M, Schultsz, C, Delahay, R, Serra-Cobo, J, Poulin, R, Keck, F, Aguirre, AA, Henttonen, H, Dobson, AP, Kutz, S, Lubroth, J, Mysterud, A and Racaniello, V (2014) Crossing the interspecies barrier: opening the door to zoonotic pathogens. PLoS Pathogens 10, 6, e1004129. https://doi.org/10.1371/journal.ppat.1004129.CrossRefGoogle ScholarPubMed
Gortázar, C, Ruiz-Fons, JF and Höfle, U (2016) Infections shared with wildlife: an updated perspective. European Journal of Wildlife Research 62, 5, 511525. https://doi.org/10.1007/s10344-016-1033-x.CrossRefGoogle Scholar
Halliday, JEB, Meredith, AL, Knobel, DL, Shaw, DJ, Bronsvoort, BMC and Cleaveland, S (2007) A framework for evaluating animals as sentinels for infectious disease surveillance. Journal of The Royal Society Interface 4, 16, 973984. https://doi.org/10.1098/rsif.2007.0237.CrossRefGoogle ScholarPubMed
Hanisch, SL, Riley, SJ and Nelson, MP (2012) Promoting wildlife health or fighting wildlife disease: insights from history, philosophy, and science. Wildlife Society Bulletin 36, 3, 477482. https://doi.org/10.1002/wsb.163.CrossRefGoogle Scholar
Hassell, JM, Begon, M, Ward, MJ and Fèvre, EM (2017) Urbanization and disease emergence: dynamics at the wildlife-livestock–human interface. Trends in Ecology and Evolution 32, 1, 5567. https://doi.org/10.1016/j.tree.2016.09.012.CrossRefGoogle ScholarPubMed
Hodgson, JC, Baylis, SM, Mott, R, Herrod, A and Clarke, RH (2016) Precision wildlife monitoring using unmanned aerial vehicles. Scientific Reports 6, 1, 22574. https://doi.org/10.1038/srep22574.CrossRefGoogle ScholarPubMed
Hofmeester, TR, Cromsigt, JPGM, Odden, J, Andrén, H, Kindberg, J and Linnell, JDC (2019) Framing pictures: a conceptual framework to identify and correct for biases in detection probability of camera traps enabling multi-species comparison. Ecology and Evolution 9, 4, 23202336. https://doi.org/10.1002/ece3.4878.CrossRefGoogle ScholarPubMed
Hofmeester, TR, Thorsen, NH, Cromsigt, JPGM, Kindberg, J, Andrén, H, Linnell, JDC and Odden, J (2021) Effects of camera-trap placement and number on detection of members of a mammalian assemblage. Ecosphere 12, 7, e03662. https://doi.org/10.1002/ecs2.3662.CrossRefGoogle Scholar
Iijima, H (2020) A review of wildlife abundance estimation models: comparison of models for correct application. Mammal Study 45, 3, 177. https://doi.org/10.3106/ms2019-0082.CrossRefGoogle Scholar
Keesing, F and Ostfeld, RS (2021) Dilution effects in disease ecology. Ecology Letters 24, 11, 24902505. https://doi.org/10.1111/ele.13875.CrossRefGoogle ScholarPubMed
Keusch, GT, Amuasi, JH, Anderson, DE, Daszak, P, Eckerle, I, Field, H, Koopmans, M, Lam, SK, Das Neves, CG, Peiris, M, Perlman, S, Wacharapluesadee, S, Yadana, S and Saif, L (2022) Pandemic origins and a One Health approach to preparedness and prevention: solutions based on SARS-CoV-2 and other RNA viruses. Proceedings of The National Academy of Sciences of The United States of America 119, 42, e2202871119. https://doi.org/10.1073/pnas.2202871119.CrossRefGoogle Scholar
Konda, M, Dodda, B, Konala, VM, Naramala, S and Adapa, S (2020) Potential zoonotic origins of SARS-CoV-2 and insights for preventing future pandemics through One Health approach. Cureus, 12, 6, e8932. https://doi.org/10.7759/cureus.8932.Google ScholarPubMed
Lancia, RA, Nichols, JD and Pollock, KH (1994) Estimating the number of animals in wildlife populations. In Bookhout, TA (ed.), Research and Management Techniques for Wildlife and Habitats. Bethesda, MD: The Wildlife Society, pp. 215253.Google Scholar
Lawson, B, Neimanis, A, Lavazza, A, López-Olvera, JR, Tavernier, P, Billinis, C, Duff, JP, Mladenov, DT, Rijks, JM, Savić, S, Wibbelt, G, Ryser-Degiorgis, M-P and Kuiken, T (2021) How to start up a national wildlife health surveillance programme. Animals 11, 9, 2543. https://doi.org/10.3390/ani11092543.CrossRefGoogle Scholar
Lawson, B, Petrovan, SO and Cunningham, AA (2015) Citizen science and wildlife disease surveillance. EcoHealth 12, 4, 693702. https://doi.org/10.1007/s10393-015-1054-z.CrossRefGoogle ScholarPubMed
Le Moullec, M, Pedersen, ÅØ, Yoccoz, NG, Aanes, R, Tufto, J and Hansen, BB (2017) Ungulate population monitoring in an open tundra landscape: distance sampling versus total counts. Wildlife Biology 2017, 1, 111. https://doi.org/10.2981/wlb.00299.CrossRefGoogle Scholar
Leighton, A (1995) Surveillance of wild animal diseases in Europe. Revue Scientifique et Technique (International Office of Epizootics) 14, 3, 819830.Google ScholarPubMed
Linchant, J, Lisein, J, Semeki, J, Lejeune, P and Vermeulen, C (2015) Are unmanned aircraft systems (UASs) the future of wildlife monitoring? A review of accomplishments and challenges. Mammal Review 45, 4, 239252. https://doi.org/10.1111/mam.12046.CrossRefGoogle Scholar
López-Olvera, JR, Fernández-de-Mera, IG, Serrano, E, Vidal, D, Vicente, J, Fierro, Y and Gortázar, C (2013) Sex-related differences in body condition and serum biochemical parameters in red deer (Cervus elaphus) naturally infected with Mycobacterium bovis . Veterinary Journal 198, 3, 702706. https://doi.org/10.1016/j.tvjl.2013.10.002.CrossRefGoogle Scholar
López-Olvera, JR, Serrano, E, Armenteros, A, Pérez, JM, Fandos, P, Carvalho, J, Velarde, R, Cano-Manuel, FJ, Ráez, A, Espinosa, J, Soriguer, RC and Granados, JE (2015) Sex-biased severity of sarcoptic mange at the same biological cost in a sexually dimorphic ungulate. Parasites & Vectors 8, 1, 583. https://doi.org/10.1186/s13071-015-1186-6.CrossRefGoogle Scholar
Luikart, G, Ryman, N, Tallmon, DA, Schwartz, MK and Allendorf, FW (2010) Estimation of census and effective population sizes: the increasing usefulness of DNA-based approaches. Conservation Genetics 11, 2, 355373. https://doi.org/10.1007/s10592-010-0050-7.CrossRefGoogle Scholar
Luo, M, Shoemaker, S, Pak, JE and Marqusee, S (2023) Epitope mapping of diagnostic anti-rabies monoclonal antibodies provide structural insight into rabies variant identification in infected wildlife. Biophysical Journal 122, 3, 331a. https://doi.org/10.1016/j.bpj.2022.11.1847.CrossRefGoogle Scholar
Lyons, MB, Brandis, KJ, Murray, NJ, Wilshire, JH, McCann, JA, Kingsford, RT, Callaghan, CT and Shepard, E (2019) Monitoring large and complex wildlife aggregations with drones. Methods in Ecology and Evolution 10, 7, 10241035. https://doi.org/10.1111/2041-210X.13194.CrossRefGoogle Scholar
Maaz, D, Gremse, C, Stollberg, K C, Jäckel, C, Sutrave, S, Kästner, C, Korkmaz, B, Richter, MH, Bandick, N, Steinhoff-Wagner, J, Lahrssen-Wiederholt, M and Mader, A (2022) Standardised sampling approach for investigating pathogens or environmental chemicals in wild game at community hunts. Animals 12, 7, 888. https://doi.org/10.3390/ani12070888.CrossRefGoogle ScholarPubMed
Machalaba, C, Uhart, M, Ryser-Degiorgis, M-P and Karesh, WB (2021) Gaps in health security related to wildlife and environment affecting pandemic prevention and preparedness, 2007-2020. Bulletin of the World Health Organization 99, 5, 342350B. https://doi.org/10.2471/BLT.20.272690.CrossRefGoogle ScholarPubMed
Martin, C, Pastoret, P-P, Brochier, B, Humblet, M-F and Saegerman, C (2011) A survey of the transmission of infectious diseases/infections between wild and domestic ungulates in Europe. Veterinary Research 42, 1, 70. https://doi.org/10.1186/1297-9716-42-70.CrossRefGoogle ScholarPubMed
Martínez-Guijosa, J, Romero, B, Infantes-Lorenzo, JA, Díez, E, Boadella, M, Balseiro, A, Veiga, M, Navarro, D, Moreno, I, Ferreres, J, Domínguez, M, Fernández, C, Domínguez, L, Gortázar, C and Serrano, E (2020) Environmental DNA: a promising factor for tuberculosis risk assessment in multi-host settings. PLOS ONE 15, 5, e0233837. https://doi.org/10.1371/journal.pone.0233837.CrossRefGoogle ScholarPubMed
Martínez-López, B, Pérez, AM and Sánchez-Vizcaíno, JM (2009) Social network analysis. Review of general concepts and use in preventive veterinary medicine. Transboundary and Emerging Diseases 56, 4, 109120. https://doi.org/10.1111/j.1865-1682.2009.01073.x.CrossRefGoogle ScholarPubMed
Mason, SS, Hill, RA, Whittingham, MJ, Cokill, J, Smith, GC and Stephens, PA (2022) Camera trap distance sampling for terrestrial mammal population monitoring: lessons learnt from a case study. Remote Sensing in Ecology and Conservation 8, 5, 717730. https://doi.org/10.1002/rse2.272.CrossRefGoogle Scholar
Mazzamuto, MV, Schilling, A-K and Romeo, C (2022) Wildlife disease monitoring: methods and perspectives. Animals 12, 21, 3032. https://doi.org/10.3390/ani12213032.CrossRefGoogle Scholar
Mazzotta, E, Bellinati, L, Bertasio, C, Boniotti, MB, Lucchese, L, Ceglie, L, Martignago, F, Leopardi, S and Natale, A (2023) Synanthropic and wild animals as sentinels of zoonotic agents: a study of Leptospira genotypes circulating in Northeastern Italy. International Journal of Environmental Research and Public Health 20, 5, 3783. https://doi.org/10.3390/ijerph20053783.CrossRefGoogle ScholarPubMed
Michel, AL, Van Heerden, H, Crossley, B, Al Dahouk, S, Prasse, D and Rutten, V (2021) Pathogen detection and disease diagnosis in wildlife: challenges and opportunities. Revue Scientifique et Technique de l’OIE 40, 1, 105118. https://doi.org/10.20506/rst.40.1.3211.Google ScholarPubMed
Miller, RS, Bevins, SN, Cook, G, Free, R, Pepin, KM, Gidlewski, T and Brown, VR (2022) Adaptive risk-based targeted surveillance for foreign animal diseases at the wildlife-livestock interface. Transboundary and Emerging Diseases 69, 5, e2329e2340. https://doi.org/10.1111/tbed.14576.CrossRefGoogle ScholarPubMed
Miller, RS, Farnsworth, ML and Malmberg, JL (2013) Diseases at the livestock-wildlife interface: status, challenges, and opportunities in the United States. Preventive Veterinary Medicine 110, 2, 119132. https://doi.org/10.1016/j.prevetmed.2012.11.021.CrossRefGoogle ScholarPubMed
Moore, CT and Kendall, WL (2004) Costs of detection bias in index-based population monitoring. Animal Biodiversity and Conservation 27, 1, 287296.Google Scholar
Mörner, T, Obendorf, D, Artois, M and Woodford, MH (2002) Surveillance and monitoring of wildlife diseases. Revue Scientifique et Technique de l’OIE 21, 1, 6776. https://doi.org/10.20506/rst.issue.21.1.19.CrossRefGoogle ScholarPubMed
Moussy, C, Burfield, IJ, Stephenson, PJ, Newton, AFE, Butchart, SHM, Sutherland, WJ, Gregory, RD, McRae, L, Bubb, P, Roesler, I, Ursino, C, Wu, Y, Retief, EF, Udin, JS, Urazaliyev, R, Sánchez‐Clavijo, LM, Lartey, E and Donald, PF (2022) A quantitative global review of species population monitoring. Conservation Biology 36, 1, e13721. https://doi.org/10.1111/cobi.13721.CrossRefGoogle ScholarPubMed
Norvell, RE, Howe, FP and Parrish, JR (2003) A seven-year comparison of relative-abundance and distance-sampling methods. The Auk 120, 4, 10131028. https://doi.org/10.1093/auk/120.4.1013.CrossRefGoogle Scholar
Nugent, G (2011) Maintenance, spillover and spillback transmission of bovine tuberculosis in multi-host wildlife complexes: a New Zealand case study. Veterinary Microbiology 151, 1-2, 3442. https://doi.org/10.1016/j.vetmic.2011.02.023.CrossRefGoogle ScholarPubMed
Oleaga, Á, Casais, R, Balseiro, A, Espí, A, Llaneza, L, Hartasánchez, A and Gortázar, C (2011) New techniques for an old disease: sarcoptic mange in the Iberian wolf. Veterinary Parasitology 181, 2-4, 255266. https://doi.org/10.1016/j.vetpar.2011.04.036.CrossRefGoogle ScholarPubMed
Ortmann, CR and Johnson, SD (2021) How reliable are motion-triggered camera traps for detecting small mammals and birds in ecological studies? Journal of Zoology 313, 3, 202207. https://doi.org/10.1111/jzo.12849.CrossRefGoogle Scholar
Palencia, P, Barroso, P, Vicente, J, Hofmeester, TR, Ferreres, J and Acevedo, P (2022) Random encounter model is a reliable method for estimating population density of multiple species using camera traps. Remote Sensing in Ecology and Conservation 8, 5, 670682. https://doi.org/10.1002/rse2.269.CrossRefGoogle Scholar
Palencia, P, Blome, S, Brook, RK, Ferroglio, E, Jo, Y-S, Linden, A, Montoro, V, Penrith, M-L, Plhal, R, Vicente, J, Viltrop, A and Gortázar, C (2023a) Tools and opportunities for African swine fever control in wild boar and feral pigs: a review. European Journal of Wildlife Research 69, 4, 69. https://doi.org/10.1007/s10344-023-01696-w.CrossRefGoogle Scholar
Palencia, P, Rowcliffe, JM, Vicente, J and Acevedo, P (2021a) Assessing the camera trap methodologies used to estimate density of unmarked populations. Journal of Applied Ecology 58, 8, 15831592. https://doi.org/10.1111/1365-2664.13913.CrossRefGoogle Scholar
Palencia, P, Vada, R, Zanet, S, Calvini, M, De Giovanni, A, Gola, G, Ferroglio, E and Chen, N-H (2023b) Not just pictures: utility of camera trapping in the context of African swine fever and wild boar management. Transboundary and Emerging Diseases 2023, 19. https://doi.org/10.1155/2023/7820538.CrossRefGoogle Scholar
Palencia, P, Vicente, J, Soriguer, RC and Acevedo, P (2021b) Towards a best-practices guide for camera trapping: assessing differences among camera trap models and settings under field conditions. Journal of Zoology 316, 3, 197208. https://doi.org/10.1111/jzo.12945.CrossRefGoogle Scholar
Payne, A, Philipon, S, Hars, J, Dufour, B and Gilot-Fromont, E (2017) Wildlife interactions on baited places and waterholes in a French area infected by bovine tuberculosis. Frontiers in Veterinary Science 3, 122. https://doi.org/10.3389/fvets.2016.00122.CrossRefGoogle Scholar
Pepin, KM, Kay, SL, Golas, BD, Shriner, SS, Gilbert, AT, Miller, RS, Graham, AL, Riley, S, Cross, PC, Samuel, MD, Hooten, MB, Hoeting, JA, Lloyd‐Smith, JO, Webb, CT, Buhnerkempe, MG and Aubry, L (2017) Inferring infection hazard in wildlife populations by linking data across individual and population scales. Ecology Letters 20, 3, 275292. https://doi.org/10.1111/ele.12732.CrossRefGoogle ScholarPubMed
Portier, J, Ryser-Degiorgis, M-P, Hutchings, MR, Monchâtre-Leroy, E, Richomme, C, Larrat, S, van der Poel, WH M, Domínguez, M, Linden, A, Santos, PT, Warns-Petit, E, Chollet, J-Y, Cavalerie, L, Grandmontagne, C, Boadella, M, Bonbon, E and Artois, M (2019) Multi-host disease management: the why and the how to include wildlife. BMC Veterinary Research 15, 1, 295. https://doi.org/10.1186/s12917-019-2030-6.CrossRefGoogle ScholarPubMed
Pruvot, M, Denstedt, E, Latinne, A, Porco, A, Montecino-Latorre, D, Khammavong, K, Milavong, P, Phouangsouvanh, S, Sisavanh, M, Nga, NTT, Ngoc, PTB, Thanh, VD, Chea, S, Sours, S, Phommachanh, P, Theppangna, W, Phiphakhavong, S, Vanna, C, Masphal, K, Sothyra, T, San, S, Chamnan, H, Long, PT, Diep, NT, Duoc, VT, Zimmer, P, Brown, K, Olson, SH and Fine, AE (2023) WildHealthNet: supporting the development of sustainable wildlife health surveillance networks in Southeast Asia. Science of The Total Environment 863, 160748. https://doi.org/10.1016/j.scitotenv.2022.160748.CrossRefGoogle ScholarPubMed
Ráez-Bravo, A, Granados, JE, Cerón, JJ, Cano-Manuel, FJ, Fandos, P, Pérez, JM, Espinosa, J, Soriguer, RC and López-Olvera, JR (2015) Acute phase proteins increase with sarcoptic mange status and severity in Iberian ibex (Capra pyrenaica, Schinz 1838). Parasitology Research 114, 11, 40054010. https://doi.org/10.1007/s00436-015-4628-3.CrossRefGoogle ScholarPubMed
Ráez-Bravo, A, Granados, JE, Serrano, E, Dellamaria, D, Casais, R, Rossi, L, Puigdemont, A, Cano-Manuel, FJ, Fandos, P, Pérez, JM, Espinosa, J, Soriguer, RC, Citterio, C and López-Olvera, JR (2016) Evaluation of three enzyme-linked immunosorbent assays for sarcoptic mange diagnosis and assessment in the Iberian ibex, Capra pyrenaica . Parasites & Vectors 9, 1, 558. https://doi.org/10.1186/s13071-016-1843-4.CrossRefGoogle ScholarPubMed
Riedel, S (2006) Crossing the species barrier: the threat of an avian influenza pandemic. Baylor University Medical Center Proceedings 19, 1, 1620. https://doi.org/10.1080/08998280.2006.11928118.CrossRefGoogle ScholarPubMed
Robinson, RA, Morrison, CA and Baillie, SR (2014) Integrating demographic data: towards a framework for monitoring wildlife populations at large spatial scales. Methods in Ecology and Evolution 5, 12, 13611372. https://doi.org/10.1111/2041-210X.12204.CrossRefGoogle Scholar
Ruiz-Rodríguez, C, Blanco-Aguiar, JA, Gómez-Molina, A, Illanas, S, Fernández-López, J, Acevedo, P and Vicente, J (2022) Towards harmonizing the collection of game statistics in Europe: a case study. European Journal of Wildlife Research, 69, 6, 122. https://doi.org/10.21203/rs.3.rs-2138283/v1.CrossRefGoogle Scholar
Russo, D and Voigt, CC (2016) The use of automated identification of bat echolocation calls in acoustic monitoring: a cautionary note for a sound analysis. Ecological Indicators 66, 598602. https://doi.org/10.1016/j.ecolind.2016.02.036.CrossRefGoogle Scholar
Ryser-Degiorgis, M-P (2013) Wildlife health investigations: needs, challenges and recommendations. BMC Veterinary Research 9, 1, 223. https://doi.org/10.1186/1746-6148-9-223.CrossRefGoogle ScholarPubMed
Santos, N, Nunes, T, Fonseca, C, Vieira-Pinto, M, Almeida, V, Gortázar, C and Correia-Neves, M (2018) Spatial analysis of wildlife tuberculosis based on a serologic survey using dried blood spots, Portugal. Emerging Infectious Diseases 24, 12, 21692175. https://doi.org/10.3201/eid2412.171357.CrossRefGoogle ScholarPubMed
Schwartz, ALW, Shilling, FM and Perkins, SE (2020) The value of monitoring wildlife roadkill. European Journal of Wildlife Research 66, 1, 18. https://doi.org/10.1007/s10344-019-1357-4.CrossRefGoogle Scholar
Serra-Cobo, J and López-Roig, M (2016) Bats and emerging infections: an ecological and virological puzzle. Advances in Experimental Medicine and Biology 972, 3548. https://doi.org/10.1007/5584_2016_131.CrossRefGoogle Scholar
Sharun, K, Dhama, K, Pawde, AM, Gortázar, C, Tiwari, R, Bonilla-Aldana, DK, Rodríguez-Morales, AJ, de la Fuente, J, Michalak, I and Attia, YA (2021) SARS-CoV-2 in animals: potential for unknown reservoir hosts and public health implications. Veterinary Quarterly 41, 1, 181201. https://doi.org/10.1080/01652176.2021.1921311.CrossRefGoogle ScholarPubMed
Silk, MJ, Croft, DP, Delahay, RJ, Hodgson, DJ, Boots, M, Weber, N and McDonald, RA (2017) Using social network measures in wildlife disease ecology, epidemiology, and management. Bioscience 67, 3, 245257. https://doi.org/10.1093/biosci/biw175.CrossRefGoogle Scholar
Silk, MJ, Hodgson, DJ, Rozins, C, Croft, DP, Delahay, RJ, Boots, M and McDonald, RA (2019) Integrating social behaviour, demography and disease dynamics in network models: applications to disease management in declining wildlife populations. Philosophical Transactions of the Royal Society B 374, 1781, 20180211. https://doi.org/10.1098/rstb.2018.0211.CrossRefGoogle ScholarPubMed
Sobrino, R, Acevedo, P, Escudero, MA, Marco, J and Gortázar, C (2009) Carnivore population trends in Spanish agrosystems after the reduction in food availability due to rabbit decline by rabbit haemorrhagic disease and improved waste management. European Journal of Wildlife Research 55, 2, 161165. https://doi.org/10.1007/s10344-008-0230-7.CrossRefGoogle Scholar
Sonnenburg, J, Ryser-Degiorgis, M-P, Kuiken, T, Ferroglio, E, Ulrich, RG, Conraths, FJ, Gortázar, C and Staubach, C (2017) Harmonizing methods for wildlife abundance estimation and pathogen detection in Europe—a questionnaire survey on three selected host-pathogen combinations. BMC Veterinary Research 13, 1, 53. https://doi.org/10.1186/s12917-016-0935-x.CrossRefGoogle ScholarPubMed
Stallknecht, DE (2007) Impediments to wildlife disease surveillance, research, and diagnostics. Current Topics in Microbiology and Immunology 315, 445461. https://doi.org/10.1007/978-3-540-70962-6_17.Google ScholarPubMed
Steenweg, R, Hebblewhite, M, Kays, R, Ahumada, J, Fisher, JT, Burton, C, Townsend, SE, Carbone, C, Rowcliffe, JM, Whittington, J, Brodie, J, Royle, JA, Switalski, A, Clevenger, A P, Heim, N, Rich, LN (2017) Scaling- up camera traps: monitoring the planet’s biodiversity with networks of remote sensors. Frontiers in Ecology and the Environment 15, 1, 2634. https://doi.org/10.1002/fee.1448.CrossRefGoogle Scholar
Stephen, C (2014) Toward a modernized definition of wildlife health. Journal of Wildlife Diseases 50, 3, 427430. https://doi.org/10.7589/2013-11-305.CrossRefGoogle Scholar
Stephen, C (2018) Evolving urban wildlife health surveillance to intelligence for pest mitigation and monitoring. Frontiers in Ecology and Evolution 6, 127. https://doi.org/10.3389/fevo.2018.00127.CrossRefGoogle Scholar
Stephen, C (2023) How do the practical and pragmatic limitations in the design or implementation of wildlife disease surveillance systems bias our understanding of the drivers, epidemiology, and impact of pathogen traffic between wildlife and people or domestic species, or within wildlife host populations? Research Directions: One Health 1, e4, 1. https://doi.org/10.1017/one.2022.5.Google Scholar
Thomas, J, Balseiro, A, Gortázar, C and Risalde, MA (2021) Diagnosis of tuberculosis in wildlife: a systematic review. Veterinary Research 52, 1, 31. https://doi.org/10.1186/s13567-020-00881-y.CrossRefGoogle ScholarPubMed
Toenies, M and Rich, L (2021) Advancing bird survey efforts through novel recorder technology and automated species identification. California Fish and Wildlife Journal 107, 2, 5670. https://doi.org/10.51492/cfwj.107.5.CrossRefGoogle Scholar
Tomaselli, M, Kutz, S, Gerlach, C and Checkley, S (2018) Local knowledge to enhance wildlife population health surveillance: conserving muskoxen and caribou in the Canadian Arctic. Biological Conservation 217, 337348. https://doi.org/10.1016/j.biocon.2017.11.010.CrossRefGoogle Scholar
Triguero-Ocaña, R, Martínez-López, B, Vicente, J, Barasona, JA, Martínez-Guijosa, J and Acevedo, P (2020) Dynamic network of interactions in the wildlife-livestock interface in mediterranean spain: an epidemiological point of view. Pathogens 9, 2, 116. https://doi.org/10.3390/pathogens9020120.CrossRefGoogle ScholarPubMed
Trolliet, F, Huynen, M-C, Vermeulen, C and A, Hambuckers (2014) Use of camera traps for wildlife studies: a review. Biotechnologie, Agronomie, Société et Environnement 18, 3, 446454.Google Scholar
Uchtmann, N, Herrmann, JA, Hahn, EC and Beasley, VR (2015) Barriers to, efforts in, and optimization of integrated One Health surveillance: a review and synthesis. EcoHealth 12, 2, 368384. https://doi.org/10.1007/s10393-015-1022-7.CrossRefGoogle ScholarPubMed
Vélez, J, McShea, W, Shamon, H, Castiblanco‐Camacho, PJ, Tabak, MA, Chalmers, C, Fergus, P and Fieberg, J (2023) An evaluation of platforms for processing camera-trap data using artificial intelligence. Methods in Ecology and Evolution 14, 2, 459477. https://doi.org/10.1111/2041-210X.14044.CrossRefGoogle Scholar
Vicente, J, Martínez-Guijosa, J, Tvarijonaviciute, A, Fernández-de Mera, IG, Gortázar, C, Cerón, JJ and Martínez-Subiela, S (2019) Serum haptoglobin response in red deer naturally infected with tuberculosis. Comparative Immunology, Microbiology and Infectious Diseases 64, 2530. https://doi.org/10.1016/j.cimid.2019.01.021.CrossRefGoogle Scholar
von Thaden, A, Nowak, C, Tiesmeyer, A, Reiners, TE, Alves, PC, Lyons, LA, Mattucci, F, Randi, E, Cragnolini, M, Galián, J, Hegyeli, Z, Kitchener, AC, Lambinet, C, Lucas, JM, Mölich, T, Ramos, L, Schockert, V and Cocchiararo, B (2020) Applying genomic data in wildlife monitoring: development guidelines for genotyping degraded samples with reduced single nucleotide polymorphism panels. Molecular Ecology Resources 20, 3, 662680. https://doi.org/10.1111/1755-0998.13136.CrossRefGoogle ScholarPubMed
Walsh, MG and Mor, SM (2018) Interspecific network centrality, host range and early-life development are associated with wildlife hosts of Rift Valley fever virus. Transboundary and Emerging Diseases 65, 6, 15681575. https://doi.org/10.1111/tbed.12903.CrossRefGoogle ScholarPubMed
Wiethoelter, AK, Beltran-Alcrudo, D, Kock, R and Mor, SM (2015) Global trends in infectious diseases at the wildlife-livestock interface. Proceedings of the National Academy of Sciences of the United States of America 112, 31, 96629667. https://doi.org/10.1073/pnas.1422741112.CrossRefGoogle ScholarPubMed
Witmer, GW (2005) Wildlife population monitoring: some practical considerations. Wildlife Research 32, 3, 259. https://doi.org/10.1071/WR04003.CrossRefGoogle Scholar
Wobeser, G (2007) Disease in Wild Animals. Investigation and Management. 2nd edn. New York, Berlin Heidelberg: Springer-Verlag.CrossRefGoogle Scholar
Yip, DA, Knight, EC, Haave‐Audet, E, Wilson, SJ, Charchuk, C, Scott, CD, Sólymos, P and Bayne, EM (2020) Sound level measurements from audio recordings provide objective distance estimates for distance sampling wildlife populations. Remote Sensing in Ecology and Conservation 6, 3, 301315. https://doi.org/10.1002/rse2.118.CrossRefGoogle Scholar
Figure 0

Figure 1. Components of Integrated wildlife monitoring (IWM) and main actions belonging to each component.

Figure 1

Figure 2. Wild boar as indicator species: main characteristics and examples of pathogens which can be monitored through wild boar serology.

Figure 2

Table 1. The perspective (limitations and challenges) on integrated wildlife monitoring (IWM) development in industrialized countries and in low- and middle-income countries (LMICs)

Figure 3

Figure 3. Percentage of species detected depending on the number of camera traps deployed in the field and the effort in days (number of operative days). Data was obtained from a nationwide pilot trial on integrated wildlife monitoring in Spain.

Figure 4

Table 2. Main limitations found in the development of each component of integrated wildlife monitoring (IWM) systems and solutions proposed

Figure 5

Figure 4. Illustrative cases of integrated wildlife monitoring: a theoretical approach for Rift Valley fever virus in Africa and the Arabian Peninsula and a practical pilot study in Spain.

Author comment: Overcoming the limitations of wildlife disease monitoring — R0/PR1

Comments

No accompanying comment.

Review: Overcoming the limitations of wildlife disease monitoring — R0/PR2

Conflict of interest statement

Reviewer declares none.

Comments

This paper discusses the importance of wildlife disease surveillance and the challenges and limitations of current approaches. The authors propose a system that integrates host community characterization, population monitoring and different disease surveillance streams as an alternative approach. Limitations and biases are discussed with suggestions for overcoming these challenges, with a focus on new technologies.

I concur with the premise that current wildlife disease surveillance systems are inadequate for decision making and new approaches would be beneficial. The ideas presented in this paper are intriguing; however, I believe the paper needs more work to further define this approach, specifically what the outputs of this system would be and how these outputs would be translated into information and intelligence for action.

Specific comments are listed below:

a) Use of indicator species and pathogens/diseases make sense in this context; however, it is unclear how network analysis would be used to select these species. Can the authors expand on this point, and perhaps provide some examples? What are the criteria for selecting the indicator species and how would this be validated?

b) Figure 1 does a nice job of visualizing the inputs to the system, but it is not clear what the outputs would be and how they would be used. Can the authors expand on figure 1 to show how the data from the four streams will be translated into products/tools such as analyses, reports, data visualization, etc., and how these tools would be used for decision making?

c) It is not clear what figure 4 contributes to the paper. I suggest deleting it.

d) One or two examples of the use of IWM would be helpful to understand how IWM would lead to better surveillance, information and decision making, even if these examples are theoretical.

In summary, I think there is merit in this paper and approach, and I was left wanting to understand more deeply how it would be used in practice, and how it would result in better information, or more efficient/effective use of resources. If the authors can address these points, I believe the manuscript merits publication.

Review: Overcoming the limitations of wildlife disease monitoring — R0/PR3

Conflict of interest statement

Reviewer declares none.

Comments

The authors provide a well-written and useful summary of the components and process of wildlife disease monitoring, its challenges and limitations, and useful directions and solutions to these challenges. I found the article informative, easy to digest, and is a useful contribution to the literature.

Recommendation: Overcoming the limitations of wildlife disease monitoring — R0/PR4

Comments

This is a subject which the global health agencies and community are trying to tackle currently, under the One Health paradigm. There is no doubt wildlife health surveillance has been neglected and under-resourced hitherto but increasing threats of emerging pathogens is leading to calls for new capacities and innovative surveillance approaches. The reviewers (we need a minimum of 2) have completed their review and this has been to accept and revise majorly respectively, leaving me the decision on how to proceed. I don't see any problems with this divergence, and perspective and the paper should be published after refinement. I agree this is required but I don't see a major revision in this process as they are providing ideas and stimulating thinking. This is not a done deal and much discussion and more science is needed to bring anything concrete to fruition. I don't expect a solution on this subject yet! If they follow the reviewers comments it should not be too difficult. I concur that you cannot survey all wildlife or any wildlife species everywhere, the challenges and costs are prohibitive so an indicator approach is our only option but even here we should not underestimate the difference between a focused research approach that might be possible on a few diseases and species with a routine national activity to feed into health security and management systems whether animal or human oriented. We fail to deal adequately with endemic known zoonosis surveillance let alone the much trickier zoonotic origin pathogens that emerge from time to time. The importance of this process for wildlife itself, is understated in this paper, given the state of biodiversity and the many threats to their future surveillance is also of critical importance. This bias in One Health publication is common and needs balancing. Yes, financial resources to undertake surveillance of wildlife disease threats to humans and domestic animals are probably more accessible but this is not going to resolve many of the issues that cause these threats in the first place, factors which are mostly anthropogenic and associated with agricultural development, land use changes and other stressors. Better surveillance of wildlife to show the processes and impacts from domestic animals and humans on wildlife would provide useful indicators as well for better environmental care and more biodiversity sensitive healthy development processes. The technologies proposed make sense but again we need to think beyond laboratories and pathogen hunting as these are largely fishing expeditions and to do this comprehensively is unrealistic eve with a population approach. I see a trend in the paper towards more systems/population approach and thinking which is good. In the end realising this proposed approach will depend on resources and the ambition may be well beyond the current scope and finances of the health communities globally. Risk of the status quo and potential threats are hard to gauge but perhaps a process of prioritisation needs to be built into the approach, using risk based sciences and I expect they have thought of this but again if brought out it will be helpful. I would hope that some of the practicalities of doing all of this are considered seriously, current capacities are really inadequate.

Author comment: Overcoming the limitations of wildlife disease monitoring — R1/PR5

Comments

No accompanying comment.

Decision: Overcoming the limitations of wildlife disease monitoring — R1/PR6

Comments

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