Project summary

Urbanisation causes profound changes to biodiversity. For many species living in urban areas, there is evidence that urban living leads to greater disease prevalence. It is unclear, however, (a) what factors drive this higher disease prevalence and (b) whether this leads to poorer wild animal welfare. We propose a study to compare two urban-dwelling species, red foxes and Eurasian hedgehogs, where we will characterize pathogen prevalence, load, and diversity across an urban-rural gradient. This study will be carried out at two scales: firstly, we will link pathogen loads, faecal glucocortoicoids and habitat at the landscape level, allowing us to broadly understand if urbanisation is associated with increased pathogen loads. We will then carry out a second, more detailed data collection where we will combine pathogen data with measures of stress (infra-red thermography, faecal glucocorticoids) and behavioural measures of affective valence (novel object and judgement bias tests). Here, we will link together pathogen loads and different measures of welfare at the individual level. Ultimately, our aim is to test, within each species, whether population differences in health and welfare are explained by environmental stressors arising from urbanisation (e.g., increased human population density and reduced habitat heterogeneity).

Why we funded this project

We appreciate that this project considers specific characteristics of urban environments, as opposed to simply comparing urban environments with rural ones. This way, it has more potential to inform near-term interventions. Plus, the project design humanely allows for animals’ voluntary participation. In addition to using an effective suite of welfare indicators to investigate the impact of different parasite loads on welfare, the combination of cognitive bias testing with non-invasive physiological stress metrics will provide information on the validity of those metrics, which are being used concurrently in other projects.

Project summary

Parasite-mediated changes in host traits can have far-reaching ecological effects. Even sublethal infections affect hosts by increasing energetic costs and altering behavior, immunity, and physiology. Yet while many studies have investigated parasite effects on specific host traits, our understanding of how parasites influence overall individual welfare is limited, especially for wild animals. For example, parasites can drive changes in host diet and habitat use that reduce parasite exposure but not necessarily improve other metrics of host welfare. A holistic approach that captures different types of individual-level responses to parasitism is needed to advance our overall understanding of sublethal infections on host welfare. We propose to investigate how parasite burden is associated with individual-level host welfare using white-footed deer mice (Peromyscus leucopus) and their helminth parasites as a model system. Specifically, by experimentally removing gastrointestinal helminth parasites from P. leucopus, we will test how variation in parasite burden influences individual host body condition, diet and nutrition, microbiome, stress physiology, anxiety-like behavior, and exploratory behavior in forested ecosystems. P. leucopus has become the dominant small mammal species over the last 40 years in the northern Great Lakes region. It experiences sublethal infection by a range of helminth parasites and is a reservoir for several zoonotic pathogens, making its host-parasite dynamics highly relevant to the health of humans and other wildlife. By examining how infection levels relate to the diet, body functions, and behavior of P. leucopus, this study will advance our understanding of how non-lethal parasitic infections affect the welfare of an extremely widespread wild animal species.

Why we funded this project

We are excited to fund a study on wild mice, a highly numerous and neglected group, and especially one with such a welfare-friendly experimental approach — curing parasitic infections rather than causing them. The project also uses a holistic suite of physiological and behavioral indicators that should allow the researchers to disentangle overall welfare from narrow, mechanistic impacts of infection on the health and nutrition domains.

Project summary

The development of the cognitive judgment bias (CJB) task for non-human animals revolutionised the field of animal welfare. The CJB task: (a) is thought to measure both relatively better and relatively poorer welfare across the full spectrum of possible welfare states, (b) is non-invasive, and (c) has been validated using a meta-analytic approach. Moreover, the theoretical basis of the predictions for the CJB task should be applicable across taxa and, accordingly, it has been used successfully in many species. However, to date, its use has largely been in captive species and there are a dearth of examples in wild animals. A key barrier to implementation is that it is difficult to train animals to associate stimuli with particular outcomes: the time needed to do so makes these studies unsuccessful or infeasible in non-captive populations of animals. We propose that this could be overcome by capitalising on the natural behaviour of a species to reduce training time and by using equipment that allows automation of stimulus presentation and data collection.

The main aim of our proposed project is to develop a CJB task for use in wild animals, in particular wild squirrels. Our key objectives are to develop a task for collecting CJB data from grey squirrels which: (1) capitalises on their innate behaviour, obviating the need for extensive training, and (2) makes use of Raspberry Pi equipment so that the task can be easily implemented by other researchers and straightforwardly adapted for use across species to measure welfare and validate novel potential measures of welfare.

To assess that our task works as anticipated, secondary objectives will be to: (1) assess how CJB varies with task manipulations designed to alter affective valence (the distance of the equipment from cover, and levels of food provisioning in the environment), and (2) assess how CJB correlates with other potential non-invasive indicators of welfare (e.g. flight distance in response to humans, QBA scores, retrapability, social status, hair cortisol concentration, and fluctuations in eye temperature following positive and negative stimuli on the judgement bias test measured using infrared thermal cameras).

Why we funded this project

As noted above, cognitive bias tests are generally considered to be exceptionally robust welfare indicators, while gray squirrels are an abundant species and a prime target for near-term interventions. Therefore, we are excited to support the development of a cognitive judgment bias test for use on free-living gray squirrels, which will also help to assess the validity of simpler indicators, such as eye temperature and flight initiation distance.

Project summary

Cognitive bias is a robust and validated measure of affective valence effective in a wide variety of animal species. However, this valuable approach has been primarily focused on the welfare assessment of captive animals and has not yet been demonstrated in wild free-living animal populations. This goal is crucial for addressing urgent contemporary issues such as the impact of anthropogenic and climatic change on wild animal welfare and to tackle key conservation challenges. In the first attempt to apply a cognitive judgement bias task in a free-living wild animal population, we found that wild birds struggled to complete the necessary training (discrimination) stage of the cognitive bias task. In the proposed project, our aim is therefore to validate two novel cognitive approaches to assessing affective valence in wild animals that do not require training, in conjunction with established behavioural and physiological indicators of welfare. Firstly, we will investigate a modified cognitive judgement bias task based on the innate avoidance of naturally occurring aversive prey, using the principle of imperfect Batesian mimicry. Secondly, we will modify and validate a cognitive attention bias task that relies on a spontaneous response to a potential threat. Both tasks will be assessed in populations of wild birds using natural variation in affective valence. Our anticipated outcomes are the development of an effective, validated measure of affective valence applicable to wild birds without the need for capture/restraint that can be translated across species; an invaluable tool in the assessment of wild animal welfare in response to a wide variety of environmental challenges.

Why we funded this project

This project’s results are intended to be generalizable to numerous woodland bird species (e.g., tits, wrens, starlings). We also appreciate its creatively humane approach to validation, using innate preferences and natural variation in affective valence, rather than training and experimental manipulation. Plus, the project considers both presumably positive (e.g., food, shelter) and presumably negative (e.g., predator abundance) welfare factors, which further strengthens the validation.

Project summary

From an evolutionary perspective, health and well-being is best expressed in terms of fitness variation, the logic being that animals who are optimally adapted to their local environment should be healthy. Hence, health and fitness are intimately entwined on a conceptual level. Morphological, behavioral, and physiological traits that are predictive of fitness could provide potential biomarkers of health, and such approaches have been developed for many different wild vertebrate species. However, due to their small size and mobility, it has proven exceedingly challenging to follow individual insects longitudinally in the wild, let alone their descendants, to measure individual performance and fitness. Consequently, there is a paucity of literature on wild insect health and well-being.

The aim of this project is to address this knowledge gap by developing a non-invasive frailty index that measures the health of individual insects in their natural habitat and that can be applied across species. Analogizing to frailty indices used in human patients, this project will develop an insect frailty index using relevant traits applicable to many different insect species. In humans, the frailty index is highly predictive of morbidity and remaining life expectancy. Similarly, this project seeks to validate the insect frailty index against mortality and fitness data in an insect population by testing whether “frail” individuals have increased mortality risk and reduced fitness. 

This project is made possible by the work that we have done to establish a long-term field study of a natural population of crickets (WildCrickets.org). Using a network of 140 video cameras, all the adults in the population are longitudinally monitored from their emergence in early spring to their natural death in late summer. All their movements, reproductive behaviors, fights, and predation events are recorded, and fitness is measured by genotyping and counting the number of surviving genetic descendants in the next year.

Why we funded this project

Willingness to investigate the welfare of insects is somewhat rare, as are creative ways to assess their welfare. This project both proposed a potentially usable metric, and has access to an unusually useful resource through the WildCrickets.org project. While any particular approach to assessing welfare in insects is unlikely to work, we are hoping to seed enough approaches and strategies that others take up the call, eventually drawing in enough different approaches to produce usable strategies for assessing insect welfare in the wild. Finally, because many of the project resources were already acquired through other sources, we were to fund exclusively the welfare-focused aspects of the project.

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Project summary

In many cases, the process of releasing a rehabilitated or translocated animal can be traumatic and removes the animal’s agency, potentially weakening their ability to thrive in the wild. This project investigates post-release support and monitoring to improve outcomes for rehabilitated juvenile pinnipeds. Post-release support will include familiar cognitive enrichment to help released animals adjust gradually and buffer their affective state. Post-release monitoring will consider metrics such as behavioral diversity, energy expenditure (distance traveled), and body condition, and the animals’ specific behavioral profiles (e.g. foraging behavior) will be compared with those recorded from healthy, wild individuals. These metrics will be used to evaluate the effectiveness of post-release enrichment as an intervention for improving welfare outcomes. Cognitive bias tests for affective state carried out during rehabilitation and prior to release will also be considered as potential predictors of post-release welfare.

Why we funded this project

We envision a world in which people take responsibility for improving wild animals’ lives and have the knowledge they need to do so effectively. Rehabilitation is a part of that. However, there has been relatively little research on post-release outcomes for rehabilitated animals. Understanding those outcomes and identifying strategies to improve them could have significant welfare implications, especially for the treatment of juvenile animals, whose life trajectories may be powerfully affected by the rehabilitation and release process. We appreciate that this project combines post-release monitoring with both a specific intervention and pre-release tests of affective state that would not be possible in a wild context.

Project summary

This project will investigate the welfare impacts of translocating captive-bred white-clawed crayfish (Austropotamobius pallipes) into an existing wild population. Both resident and introduced individuals will be fitted with transponders and marked for behavioral monitoring. To evaluate welfare, the researchers will observe social interactions (e.g. aggressive interactions), behavioral diversity, and the animals’ use of their habitat. For example, emigration of native individuals from the focal habitat may be indicative of intraspecific competition intensified by the translocation. Body condition will also be scored as a metric of health and resource access.

Why we funded this project

We are excited to fund a project focused on the welfare of invertebrates, in this case an aquatic crustacean. The monitoring methods and some findings of this project may also be applicable to other aquatic taxa. Translocation is already a commonly used intervention in conservation, yet its welfare implications are poorly understood. By learning about these, translocation strategies could potentially be improved, and we might gain insights that could be applied to other welfare-motivated interventions.

Project summary

This project will monitor the welfare of three species of fish in the Grand Canyon using a battery of metrics including body condition, gut microbiome, parasite load, and cortisol in skin mucus. The researchers will attempt to validate these as welfare indicators by testing whether they correlate with one another within individual fish, and whether they follow consistent patterns across the three focal species. Finally, they will use long-term population monitoring data to investigate potential correlations between these individual-based welfare indicators and environmental and demographic characteristics of individual study sites, such as food availability and age structure. 

Why we funded this project

We appreciate the variety of potential welfare indicators that this study will measure, and that there will be an explicit attempt to test the validity of the indicators for these particular species. It is exciting to see such a comprehensive analysis of wild fish welfare. We are also interested in the project’s comparison of individual welfare indicators to population-level demographic parameters, as better understanding those relationships could help with both identifying welfare threats from more readily available population data, and with predicting indirect impacts of welfare interventions.

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Project summary

In this project, wild-caught guppies (Poecilia reticulata) will be exposed to an apparent threat of predation by transferring water from a tank containing a common predator (pike cichlid) into their tank. The amount of water transferred from the predators’ tank will be varied to simulate a range of predator densities. Then, cortisol levels will be measured in both the tissue of guppies and the water they are kept in. These tissue and water cortisol measurements will be compared to develop a protocol for inferring the cortisol levels of fish based on non-invasive water measurements. The researchers hypothesize that the strength of the guppies’ physiological stress response (cortisol) will vary with apparent predation risk, and they intend to eventually build on this pilot study by using the developed non-invasive protocol to compare guppies from populations the are adapted to varying intensities of predation. 

Why we funded this project

This project will develop a protocol for inferring the cortisol levels of fish based on non-invasive water measurements, which should allow researchers seeking to use cortisol as a metric of physiological stress to avoid needing to kill fish in order to measure the chemical in their tissues. In terms of broader wild animal welfare theory, we also appreciate the project’s focus on the indirect effects of predator-induced fear, which are likely ubiquitous. This project is also intended as a pilot for a larger project that would investigate the impact of evolutionary adaptation to avoid predation on the stress response to the presence of predators.

Project summary

This project will investigate the welfare of a common fish species in Lake Tanganyika, the princess cichlid (Neolamprologus pulcher), as they are exposed to varying levels of human activity. Across eight populations representing a range of distances to human settlements and shipping routes, the researchers will monitor behaviors indicative of stress or aggression, and measure body condition and the brain tissue expression of five genes involved in stress physiology (glucocorticoid response pathway; crf, cyp11b, gr1, gr2, mr). These welfare indicators will be compared with specific environmental characteristics, including boat noise, water visibility (sedimentary and algal load), human fishing intensity, temperature stress, and structural complexity of the local environment.

Why we funded this project

By focusing on an established model system (cichlids), this project is able to benefit from background knowledge of the species’ ecology and behavior and proceed to more neglected welfare questions, as well as potentially engaging a ready audience of cichlid researchers. An especially interesting component of this project is its investigation of brain gene expression to potentially better understand how stress physiology relates to an animal’s subjective experience.