Hostname: page-component-78c5997874-s2hrs Total loading time: 0 Render date: 2024-11-06T07:55:21.409Z Has data issue: false hasContentIssue false
  • English
  • Français

A comparison of the welfare of free-ranging native pony herds on common land with those used for conservation grazing in the UK

Published online by Cambridge University Press:  16 September 2024

Sophia McDonald Open the ORCID record for Sophia McDonald [Opens in a new window] ,
Jessica J Harley Open the ORCID record for Jessica J Harley [Opens in a new window]  and
Jo Hockenhull Open the ORCID record for Jo Hockenhull [Opens in a new window]
Sophia McDonald*
Affiliation:
Bristol Veterinary School, University of Bristol, Bristol BS40 5DU, UK
Jessica J Harley
Affiliation:
University Centre Reaseheath, Rease Heath, Nantwich CW5 6DF, UK Knowsley Safari, Knowsley, Prescot L34 4AN, UK
Jo Hockenhull
Affiliation:
Bristol Veterinary School, University of Bristol, Bristol BS40 5DU, UK
*
Corresponding author: Sophia McDonald; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Free-ranging native Dartmoor and Exmoor ponies have not only held strong cultural and environmental significance for thousands of years within their respective national parks, but their environmental benefits and naturally selected characteristics have also been acknowledged and harnessed for conservation grazing and rewilding programmes. Despite a wealth of literature regarding the welfare of sports, leisure and working horses, there is little information concerning the welfare of free-ranging and extensively grazing ponies. The present study compared the welfare of native Exmoor and Dartmoor ponies grazing on the moors in their respective national parks (n = 47) with those that have been translocated to other areas of the UK for use in conservation grazing and rewilding programmes (n = 29) using a specifically designed observational welfare assessment protocol for free-ranging ponies. The results showed a significant difference between common land and conservation grazing ponies in the scores for Body Condition Score, Water Quality and Availability, Environmental Hazards, Human Disturbance, Skin and Coat Condition and the Human Approach Test. Despite no evidence of significant welfare compromise being identified, this study emphasises the importance of year-round monitoring of welfare and the feasibility of the observational welfare protocol to be used by pony keepers and grazing managers in the future.

Keywords

animal welfareDartmoorequineExmoorextensive grazingwelfare assessment
Type
Research Article
Information
Animal Welfare , Volume 33 , 2024 , e30
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of The Universities Federation for Animal Welfare

Introduction

The majority of owned domesticated horses (Equus caballus) in the UK are kept within an intensive husbandry and management system, and only a minority are managed extensively and considered free ranging (Longland Reference Longland, Geor, Harris and Coenen2013; Gonçalves Abrantes Reference Gonçalves Abrantes2021). Dartmoor (945 km2) and Exmoor (693 km2) National Parks in southern England have been populated with free-ranging, semi-feral ponies for thousands of years (Green Reference Green2013), and today herds of native Dartmoor and Exmoor ponies are grazed on the common land within the respective national parks. Extensively grazing herds are free to forage, browse and move freely with conspecifics (Christensen et al. Reference Christensen, Zharkikh, Ladewig and Yasinetskaya2002; King et al. Reference King, Jones, Schwarm and Oberhaus2013; Viksten Reference Viksten2016). Being able to exhibit these natural behaviours means a reduced incidence of health issues (Yngvesson et al. Reference Yngvesson, Rey Torres, Lindholm, Pättiniemi, Andersson and Sassner2019), possibly denoting a more positive welfare state compared to stabled horses whose movement is restricted and access to both forage and conspecifics may be restricted (Hartmann et al. Reference Hartmann, Søndergaard and Keeling2012). This has potentially contributed to the lack of research into the welfare of free-ranging horses, even though this environment does not eliminate the potential for welfare issues to arise (Fraser Reference Fraser2008, Reference Fraser2009).

The genomes of native pony breeds have been shaped by natural selection, meaning that they possess adaptations that are now absent in domesticated breeds (Fraser et al. Reference Fraser, Stanley and Hegarty2019). Native ponies are particularly well-suited to extensive grazing as their hardy nature means they are able to tolerate environmental conditions that other domesticated equines would not be well adapted to (Hodder et al. Reference Hodder, Bullock, Buckland and Kirby2005). However, both the Dartmoor and Exmoor breeds are considered priority equine breeds (Rare Breeds Survival Trust 2022) and UK Native Breeds at Risk. Appropriate management is required to carefully increase the number of registered ponies whilst maintaining genetic diversity (Green Reference Green2013). Furthermore, their longstanding presence has created a strong cultural heritage, and many stakeholders believe declining numbers are impacting biodiversity within their grazing areas (Udall et al. Reference Udall, Fraser and Franklin2023). Low-intensity grazing is beneficial across the trophic levels in upland areas in the UK (Evans et al. Reference Evans, Villar, Littlewood, Pakeman, Evans, Dennis, Skartveit and Redpath2015), where light grazing of swards can increase overall foliage growth (Bott et al. Reference Bott, Greene, Koch, Martinson, Siciliano, Williams and Trottier2013), which increases the number of ecological niches, as well as the habitat quality (Kruess & Tscharntke Reference Kruess and Tscharntke2002; Wallis de Vries et al. Reference Wallis De Vries, Parkinson, Dulphy, Sayer and Diana2007; Bussan Reference Bussan2022). These benefits have been recognised as a conservation tool to reduce the presence of invasive species and promote native and/or high-value species (Fraser et al. Reference Fraser, Stanley and Hegarty2019). Therefore free-ranging native ponies provide an attractive choice for use as conservation grazers (Grazing Animals Project 2008) and in rewilding programmes throughout the UK and Europe (Linnartz & Meissner Reference Linnartz and Meissner2014).

UK equines are protected under the Animal Welfare Act (2006) and the additional Code of Practice for the Welfare of Horses, Ponies, Donkeys and Their Hybrids (DEFRA 2017), but this legislation is problematic to apply to free-ranging ponies. Traditionally, ponies are gathered off the moors and onto farms in the autumn, referred to as ‘drifts’, each pony is checked, with some selectively removed and sold in order to manage the population size (Van de Weerd et al. Reference Van de Weerd, Seaman, Wheeler, Goddard and McLean2012). Despite being in place to assess welfare, ‘drifts’ have been highlighted as a specific welfare issue for free-ranging ponies, alongside overbreeding and lack of supplementary food in winter, as gatherings are considered to be stressful (Horseman et al. Reference Horseman, Buller, Mullan and Whay2016), likely due to infrequent human handling (Jezierski et al. Reference Jezierski, Jaworski and Gorecka1999). There is also a responsibility to ensure the welfare of ponies acquired for use in conservation grazing and rewilding schemes. Lack of knowledge and poor advice-seeking behaviour have been identified as the root causes of equine welfare issues in the UK (Horseman et al. Reference Horseman, Buller, Mullan and Whay2016) and there are anecdotal concerns that those responsible for conservation grazing ponies are unfamiliar with the species or lack prior experience. Although marketed at these programmes for their hardiness and ability to adapt (Grazing Animals Project 2001); ponies are grazing in an unfamiliar environment and with altered social group dynamics which is likely to increase stress levels (van Dierendonck Reference Van Dierendonck2006), and so has the potential to negatively impact their welfare. A lack of awareness could compromise individual welfare and potentially that of the wider equine community, for example if there was an unrecognised infectious disease outbreak.

Continued criticism of the management of free-ranging ponies by both welfare organisations and the public (Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021; Udall et al. Reference Udall, Fraser and Franklin2023), means that necessary action must be taken to adapt present management systems to secure the future of these ponies (Green Reference Green2013). Whilst population-level management (for a discussion, see Green Reference Green2013; Petrie-Ritchie Reference Petrie-Ritchie2015), is important to maximise herd-level welfare; it is also imperative to monitor welfare at an individual level to identify issues and potential risk factors to allow for early intervention and safeguarding of pony welfare (Blokhuis et al. Reference Blokhuis, Veissier, Miele and Jones2010). Welfare assessment protocols for sport, leisure and working horses, of which there are several (e.g. AWIN 2015; Dalla Costa et al. Reference Dalla Costa, Dai, Lebelt, Scholz, Barbieri, Canali, Zanella and Minero2016), often refer to free-ranging horses’ physical and social environments as natural and welfare-friendly conditions (Waran Reference Waran1997). This has impacted the design and utilisation of suitable welfare assessment protocols for free-ranging ponies (Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021). Despite the recent development of a few specific protocols (e.g. Harvey et al. Reference Harvey, Beausoleil, Ramp and Mellor2020; Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021), free-ranging native pony welfare in the UK is under-researched, with no known published studies attempting to report upon individual welfare or make comparisons between populations. This study aims to compare the welfare of free-ranging native pony herds grazing on the common land within Dartmoor and Exmoor National Parks, with herds that have been translocated to other areas for the specific purpose of conservation grazing or rewilding, using an adapted version of the welfare assessment designed by Harley et al. (Reference Harley, Stack, Braid, McLennan and Stanley2021).

Materials and methods

Ethical approval

This study was granted ethical approval by the University of Bristol’s Animal Welfare and Ethical Review Body on 2nd May 2023; unique reference number UIN/23/017.

Study sites and populations

Six study sites, accessible to the public and with a population of free-ranging Dartmoor or Exmoor ponies, were selected (Table 1). These sites hosted registered Exmoor ponies or heritage/registered Dartmoor ponies. Ponies assessed were chosen opportunistically from the free-ranging population during the first visit to each location.

Table 1. Details of free-ranging native pony herds including location, breed, sexes, ages, and numbers of ponies assessed

Data collection

All individual welfare assessments were carried out between 0800 and 1700h from 30th May to 24th July 2023 by the first author (SM) who has extensive background knowledge of equine care and management. Weather conditions, assessment time and necessary assessment data were recorded. A minimum of 3 m was always maintained between the pony and assessor and binoculars were used if necessary. Photographic and written descriptions allowed individual pony identification in subsequent visits, including details of GPS location, sex, colour, markings, and branding/other mutilations (if present).

The welfare assessment protocol comprises 15 animal- and resource-based indicators (fully detailed in Table 2). Indicators are scored on a numerical categorical scale from zero to three. Zero or one indicates a negative state, two is neutral and some indicators can be scored with three representing a positive state. Only specific indicators can be assigned a score of zero (see Table 3), which indicates a more serious welfare compromise. If any pony received a score of zero and was deemed to have seriously compromised welfare, the Horse Grimace Scale (HGS) (developed by Dalla Costa et al. Reference Dalla Costa, Minero, Lebelt, Stucke, Canali and Leach2014a) was used and scored between zero to two. The issue was reported to the relevant welfare authority responsible for that individual.

Table 2. Welfare assessment protocol (adapted from Harley et al., Reference Harley, Stack, Braid, McLennan and Stanley2021) with details of animal- (AB) and resource-based (RB) indicators and scoring categories for each welfare indicator

Table 3. Score frequencies for common land (n = 47) and conservation grazing ponies (n = 29), with the results of Mann Whitney U tests between the two groups for each of the animal- and resource-based welfare indicators that make up the welfare assessment (adapted from Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021). Significant differences between the two groups are represented with bold P-values

* N/A indicates that the statistical test could not be performed due to no data variation for that indicator (i.e. all ponies had the same score).

where there is no value, n = 0 for that score.

A Qualitative Behavioural Assessment (QBA), initially developed by Wemelsfelder et al. (Reference Wemelsfelder, Hunter, Mendl and Lawrence2000, Reference Wemelsfelder, Hunter, Mendl and Lawrence2001) was also carried out. The protocol conducted for the QBA required the assessor to spend two to three minutes familiarising themselves with the pony’s demeanour (expressive behaviour) followed by a 10 minute focal observation (Altmann Reference Altmann1974). Scores were entered after the observation period concluded. Descriptors were selected to represent the expressive qualities of a free-ranging pony and chosen from current equine studies applying QBA to evaluate horses’ behavioural responsiveness (AWIN 2015; Hintze et al. Reference Hintze, Murphy, Bachmann, Wemelsfelder and Würbel2017; Czycholl et al. Reference Czycholl, Klingbeil and Krieter2019). QBA descriptors were initially trialled on 13 individual Carneddau Mountain ponies by one of the authors (JJH), and a specialist equine surgeon. The initial trial resulted in a moderate degree of reliability between assessors for the descriptor ‘friendly’, all other descriptors were good or very good. Prior to inclusion in our study, the definition and description were refined for better context, i.e. ‘friendly’ was changed to Friendly (Sociable) and the definition was expanded to ensure the situation of the behaviour was limited to the pony’s interaction with other pony(s) rather than the assessor (Table 4).

Table 4. List of Qualitative Behavioural Assessment descriptors and definitions (modified from Fleming et al. Reference Fleming, Paisley, Barnes and Wemelsfelder2013; Dalla Costa et al. Reference Dalla Costa, Dai, Lebelt, Scholz, Barbieri, Canali, Zanella and Minero2016; Hintze et al. Reference Hintze, Murphy, Bachmann, Wemelsfelder and Würbel2017)

All locations were revisited within 21 days of the first assessment and the welfare assessment was repeated on individuals that could be successfully re-identified (n = 41) to test for assessor reliability.

Statistical analysis

All analyses were performed in the R-4.2.2 (R-Studio Team 2021). Datasets were checked for violations of the assumptions of normality (normality of residuals and homogeneity of variance), data transformations were attempted, and a non-parametric test was used if unsuccessful. The threshold for significance in all statistical tests was P < 0.05.

Comparing common land and conservation grazing ponies

To investigate if there was a statistically significant difference between each welfare indicator (Table 3) for common land and conservation grazing ponies, Mann-Whitney U tests were performed. To investigate if there was a statistically significant difference between each welfare indicator for Dartmoor and Exmoor breeds grazing on both land types (Dartmoor ponies grazing on common land [CLDM], Exmoor ponies grazing on common land [CLEX], Dartmoor ponies in conservation grazing programmes [CGDM] and Exmoor ponies in conservation grazing programmes [CGEX]), a Kruskal-Wallis test was used. Pair-wise Wilcoxon Rank Sum Tests were calculated with a Benjamini-Hochberg correction for multiple testing to identify groups with significant differences.

Qualitative Behavioural Assessment

To analyse the QBA scores, a Principal Component Analysis (PCA, correlation matrix, no rotation) was conducted separately for common land and conservation grazing ponies. A PCA was used to reduce the number of dimensions to assist in explaining the majority of variation between the individual ponies.

Test/retest reliability

To investigate assessor reliability, test/retest analysis was undertaken using Cohen’s unweighted kappa test statistic and the percentage of agreement between visits for each welfare indicator (as used by Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021). Kappa values were interpreted according to the work of Altman (Reference Altman1991), where values of 0.81–1.00 are considered very good, 0.61–0.80 are considered good, 0.41–0.60 are considered moderate, 0.21–0.40 are considered fair, and < 0.20 are considered poor agreement.

Results

A total of 76 ponies underwent assessment, 38 individuals of each breed (Dartmoor and Exmoor), 47 on the common land and 29 within conservation grazing/rewilding programmes (Table 1).

The Horse Grimace Scale (see Table 2) was not undertaken for any individual as no pony was deemed to have seriously compromised welfare at the time the welfare assessment was conducted.

Comparing common land and conservation grazing ponies

The scores for Body Condition Score (BCS), Human Disturbance, Environmental Hazards and Skin and Coat Condition were significantly lower for conservation grazing ponies compared to common land ponies (Table 3). Scores for Water Quality and Availability, and the Human Approach Test were significantly higher for common land ponies compared to conservation grazing ponies (Table 3). There was no significant difference between the scores of the two groups for Resting Comfort, Thermal Environment and Comfort, Mobility, Mane and Tail Condition, Ocular Discharge, Nasal Discharge, Coughing, Wounds and Swelling, and Social Contact (Table 3).

There was a statistically significant difference between the scores for BCS, Water Quality and Availability, Human Disturbance, Environmental Hazards, and Human Approach Test in the four groups (CLDM, CLEX, CGDM, CGEX) (Table 5). There was no significant difference between the four groups for all other welfare indicators (Table 5). Post hoc pair-wise Wilcoxon Tests with Benjamini-Hochberg Correction are displayed in Table 5, where there were significant pair-wise comparisons for the five welfare indicators listed above.

Table 5. Kruskal-Wallis rank-sum test results between Exmoor common land (CLEX, n = 23), Dartmoor common land (CLDM, n = 24), Exmoor conservation grazing (CGEX, n = 15) and Dartmoor conservation grazing (CGDM, n = 14) ponies, with post hoc pair-wise Wilcoxon tests to determine the significant differences between the four groups for each welfare indicator

Significant differences between the groups are represented with bold P values. Post hoc test P-values with “-” present indicate that a comparison between those groups was not available or applicable

* N/A indicates that the statistical test could not be performed due to no data variation for that indicator and therefore post hoc pair-wise Wilcoxon tests could not be carried out.

Qualitative Behavioural Assessment

Figures 1 and 2 show the distribution of the ten descriptors along the first two principal component (PC) factors for common land and conservation grazing ponies, respectively. Many of the terms load strongly on PC1, accounting for 39.4% of the variation in the data for conservation grazing ponies and 38.2% for common land ponies. PC2 accounts for 19.7% of the variance in the data for common land ponies and 14.9% for conservation grazing ponies. PC1 for common land ponies was characterised by terms ranging from ‘relaxed’ to ‘alert/responsive/agitated’, whereas PC2 was described by ‘apathetic/withdrawn’ to ‘friendly’ (Figure 1). PC1 for conservation grazing ponies was characterised by terms ranging from ‘agitated/curious/responsive/alert’ to ‘relaxed’, and PC2 was described by ‘friendly’ to ‘aggressive/fearful’ (Figure 2).

Figure 1. Loadings of the ten Qualitative Behavioural Assessment descriptors along the first two Principal Component Analysis factors (PC1, PC2) for common land (n = 47) ponies.

Figure 2. Loadings of Qualitative Behavioural Assessment descriptors along the first two Principal Component Analysis factors (PC1, PC2) for conservation grazing ponies (n = 29).

Test/retest reliability

Some of the welfare indicators scored with 100% agreement between the two assessments and could not be tested for reliability using Cohen’s unweighted kappa test statistic (Table 6). There was very good agreement (kappa estimate of 0.83–1.00) for BCS and Human Disturbance, and moderate agreement (kappa estimate of 0.43) for the Human Approach Test. There was no agreement (kappa estimate of 0) for Water Quality and Availability, Thermal Environment and Comfort, Skin and Coat Condition, Coughing and Social Contact. However, the agreement was greater than 90% for these indicators apart from Water Quality and Availability (Table 6). Environmental Hazards has a kappa estimate of –0.17 suggesting this is due to chance.

Table 6. Cohen’s unweighted kappa test statistic results (Kappa estimates, k) and the percentage agreement for each welfare indicator between the two assessments to measure the test/retest reliability

* N/A indicates that the statistical test could not be performed due to no data variation for that indicator.

Discussion

Though there are a number of clear differences in resource-based indicators between common land and conservation grazing ponies, most animal-based indicators showed no significant variation. Animal-based indicators scored positively and consistently suggesting that all surveyed populations were in good general health showing little or no signs of lameness, ocular or nasal discharge, coughing, sweating, shivering, wounds or swelling. Comparable findings have been identified in semi-feral Carneddau Mountain ponies (Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021) and horses grazing on ‘parcours’ (outdoor groups-housing system) in France (Dai et al. Reference Dai, Dalla Costa, Minero and Briant2023), with infrequent observation of ocular and nasal discharge and coughing. These are more frequent problems in stabled horses (Hotchkiss et al. Reference Hotchkiss, Reid and Christley2007; Visser et al. Reference Visser, Neijenhuis, de Graaf-Roelfsema, Wesselink, De Boer, van Wijhe-Kiezebrink, Engel and Van Reenen2014), as respiratory issues are closely linked with indoor housing and have reduced prevalence in the open-air environment of free-ranging ponies.

Although Mane and Tail Condition were consistent across the groups, there was a significant difference in Skin and Coat Condition. Several common land ponies had patchy coats and alopecia (12.7%), which is often attributed to insect irritation causing persistent itching (Górecka & Jezierski Reference Górecka and Jezierski2007; Mullan et al. Reference Mullan, Szmaragd, Hotchkiss and Whay2014; Dai et al. Reference Dai, Dalla Costa, Minero and Briant2023). The welfare assessment was carried out in the summer months on warm, sunny days where insect activity is increased (Strickman et al. Reference Strickman, Wirtz, Lawyer, Glick, Stockwell and Perich1995), providing a likely explanation. Alternatively, bare patches of skin may have been a result of agonistic behaviours (bites or kicks) between mares and sub-adults to express dominance (Sigurjónsdóttir & Haraldsson Reference Sigurjónsdóttir and Haraldsson2019) or herding behaviours by stallions (Ransom et al. Reference Ransom, Cade and Hobbs2010), of which there were none present within the surveyed conservation grazing populations and this may be why coats were in better condition in those groups.

BCS differed between common land ponies and CGEX ponies, where some CGEX mares were identified as ‘fat’ (Henneke et al. Reference Henneke, Potter, Kreider and Yeates1983) and scored zero. Upon assessment, these mares scored two, but when the herd was revisited and after discussion with an experienced equine welfare scientist (JoH), some of the mares’ scores were downgraded to zero and therefore HGS was not undertaken at the time of the assessment. As the assessment is solely observational, and there was a potential for these mares to be in foal, correct assessment of BCS was difficult. In comparison to the upland, dry heath habitats of Exmoor and Dartmoor National Park, the ‘Middle Block’ at Knepp Castle Estate is comprised of traditional parkland that was reseeded with grass seed and a local wild meadow seed mix in 2001 (Tree Reference Tree2018). Horses released in a natural environment within a temperate climate can adapt their daily intake according to pasture availability and changes to climate, maintaining a good BCS (Souris et al. Reference Souris, Kaczensky, Julliard and Walzer2007) as was the case with all other assessed ponies in the study. However, in the summer, increased appetite and metabolic rate (Arnold et al. Reference Arnold, Ruf and Kuntz2006) have been found to result in fat deposition when high-quality forage is available, and this is likely to be the case here. High BCS has also been identified in other ‘rustic’ breeds (Camargue and Merens) grazing on French ‘parcours’ (Dai et al. Reference Dai, Dalla Costa, Minero and Briant2023). Despite the well-reported dangers of a high BCS (e.g. laminitis, colic, insulin resistance), it has been suggested that ponies demonstrate photoperiodically entrained physiological adaptations that promote survival where winter forage is sparse (Fuller et al. Reference Fuller, Cox and Argo2001; Rhind et al. Reference Rhind, Archer and Adam2002; Thiery et al. Reference Thiery, Chemineau, Hernandez, Migaud and Malpaux2002; Henry Reference Henry2003), and so a higher BCS in the summer months may not have negative repercussions for health or reproduction (Górecka et al. Reference Górecka, Jaworski, Jaworska and Siemieniuch2020), though year-round monitoring would be required to confirm if this is the case here. Furthermore, the use of the cresty neck score (Carter et al. Reference Carter, Geor, Burton Staniar, Cubitt and Harris2009) may have been useful as it has been shown to predict insulin dysregulation in ponies (Fitzgerald et al. Reference Fitzgerald, Anderson, Sillence and de Laat2019) and therefore may have provided more robust evidence of a welfare compromise than using BCS alone.

CLDM ponies scored significantly higher than the other groups on the Human Approach Test, with most (66.6%) individuals scoring three. Birke et al. (Reference Birke, Hockenhull, Creighton, Pinno, Mee and Mills2011) identified similar results in flight distances of naïve young Dartmoor ponies, averaging at 2.4 (± 0.54) m in the first session. Reasons for differences between the groups are difficult to determine, as the individual past experiences of each pony are unknown. Some ponies may have been handled more frequently than others, which would have reduced their flight distances over time (as shown by Birke et al. Reference Birke, Hockenhull, Creighton, Pinno, Mee and Mills2011) and resulted in more positive scores. Alternatively, others may have had a negative past experience (e.g. aversive handling, stressful transportation), and associate human approach with negative outcomes (Rushen et al. Reference Rushen, Taylor and de Passillé1999; Fureix et al. Reference Fureix, Bourjade, Henry, Sankey and Hausberger2012). Greater human presence in conservation grazing areas likely stems from specified public walking routes and designated parking facilities, in contrast to more remote areas in Dartmoor and Exmoor National Parks (e.g. Winsford Hill, Widecombe Hill). Conservation grazing ponies scored significantly lower on the Human Approach Test implying that they would keep a greater distance from the public. However, allowing a closer human approach scored positively in the welfare protocol, despite numerous campaigns to deter the public from feeding or touching free-ranging ponies (e.g. Dartmoor National Park Authority 2017). A close human approach could negatively impact ponies’ welfare as it increases the chances of them being fed or touched, though it may be beneficial if an issue is identified and requires treatment.

Resource-based indicators showed greater variability during revisits compared to animal-based indicators. Despite the variability, resource-based indicators implied that all surveyed populations were in the presence of conspecifics and had access to a suitable resting area with both shade and shelter. Access to shelter is crucial during inclement weather (Tyler Reference Tyler1972; Duncan Reference Duncan1985; Autio & Heiskanen Reference Autio and Heiskanen2005), aiding thermoregulation and prevention of the development of other welfare issues (e.g. shivering, sweating). These indicators relied upon surveying the area within a 500-m circular radius of the observed pony (Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021) and were more inconsistent between visits due to differing pony locality. For example, the absence of a water source scored one, implying that the pony may not have access to water. However, nearby water sources may not have been visible or situated differently from where the herd was throughout the assessment, explaining why water quality and availability had a much lower percentage agreement in the test/retest in comparison to the other indicators. Surveying the entire grazing area for water sources and environmental hazards would have reduced subjectivity.

An animal’s affective state moves along a scale of negative and positive valence, influenced by its environment and experience (Mendl et al. Reference Mendl, Burman and Paul2010). Qualitative Behavioural Assessment is a novel, whole-animal method to evaluate an animal’s emotional state and determine its welfare and response to environmental conditions (Wemelsfelder Reference Wemelsfelder2007). PC1 in both common land and conservation grazing ponies reflects activity and arousal levels (Figures 1 and 2), although ‘relaxed’ is on opposing ends of the axis. Mullan et al. (Reference Mullan, Szmaragd, Hotchkiss and Whay2014) observed similar findings in tethered and free-ranging horses on public grazing land in South Wales, where PC1 indicated arousal level. PC2 differs between the two groups, where for common land ponies it explains sociability, but for conservation grazing ponies it explains the mood and subjective experience, akin to Mullan et al. (Reference Mullan, Szmaragd, Hotchkiss and Whay2014). QBA improves understanding of individual affective states and has been shown to correlate with other quantitative indicators (Dalla Costa et al. Reference Dalla Costa, Murray, Dai, Canali and Minero2014b). Statistical analysis is required for QBA interpretation (Dalla Costa et al. Reference Dalla Costa, Murray, Dai, Canali and Minero2014b), which may reduce its viability if the welfare assessment were to be utilised by pony keepers and stock-person managers. In an app developed by the SRUC (2020) to help perform QBAs, charts are automatically displayed for emotional well-being and facilitate comparison with previous assessments, enhancing accessibility for use by key stakeholders in the future.

Welfare was assessed in the early summer and is only representative of the ponies’ welfare at that time. While sufficient for interpopulation comparisons, year-round assessment is more beneficial to effectively monitor welfare, as free-ranging environments are heavily characterised by significant seasonal variation (Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021). Seasons have been shown to significantly affect BCS and the skin condition of extensively grazing Swedish Gotland ponies (Viksten et al. Reference Viksten, Hartmann, Schneller and Steen2023). Utilising a similar methodology to that of Viksten et al. (Reference Viksten, Hartmann, Schneller and Steen2023), assessing welfare every four weeks year-round would enable cross-season comparisons and a better understanding of how each individual adapts to environmental changes (Sterling Reference Sterling and Schulkin2004). The assessment was conducted by one assessor and although the welfare protocol has been previously piloted and tested for reliability (Harley et al. Reference Harley, Stack, Braid, McLennan and Stanley2021), comparing the scores of multiple assessors would have increased reliability. However, re-tests showed a high percentage agreement (> 60%), except for one welfare indicator. Cohen’s unweighted kappa test lacks value and can be misleading when no data variation exists, as the percentage of agreement between the two visits was 100%. The individual welfare state was determined solely from the indicators within the protocol, and being observational, some issues may pass undetected. However, this was the only reasonable approach to take for studying these populations within the given time-frame. Furthermore, the assessment of free-ranging ponies in the field presents the challenge of optimal assessor positioning and distance without disturbing the herd. Sometimes assessment ceased if the herd moved into an unsuitable location (e.g. low, dense trees), reducing sample sizes where all individuals were not able to be sampled.

Animal welfare implications

The information gathered in this study has provided insight into the welfare of extensively grazing Exmoor and Dartmoor ponies on areas of common land within the respectively named national parks and those enlisted for the benefits of their grazing as part of conservation grazing and rewilding programmes. There is evidence to suggest that conservation grazing locations should be selected carefully and be similar to the ponies’ source habitat; ponies should be monitored closely for the first few weeks when they arrive as conservation grazing areas may have greater levels of human disturbance and increased food availability that could cause health issues (e.g. obesity, laminitis) which would impact welfare. This study also highlights the feasibility of an observational assessment for use by pony keepers and grazing managers to monitor welfare at an individual level and avoid unnecessary stress to ponies by rounding them up (‘drifting’), as well as allowing for more targeted treatment of individuals with issues which will improve herd level welfare.

Conclusion

Overall, the welfare of Exmoor and Dartmoor ponies grazing on the common land and in conservation grazing/rewilding programmes scores largely similarly, with all ponies assessed as being sound, within a social group and with sufficient access to food and shelter. The constraints of the welfare assessment protocol may have impacted the scores for some resource-based indicators, in particular water quality and availability but with slight adjustment these then may be more representative of the ponies’ grazing area. This study highlights the importance and encourages the monitoring of the welfare of herds of free-ranging native ponies across the UK into the future. It implies that research into the welfare of other free-ranging populations is necessary to secure the future of Exmoor and Dartmoor ponies on the moors which will allow for them to exhibit their benefits as part of conservation grazing and rewilding programmes.

Acknowledgements

Thank you to Dr Nicola Rooney and the University of Bristol Veterinary School for allowing this study to be undertaken by SM as part of the MSc Global Wildlife Health and Conservation course. This research did not receive any specific grant from funding agencies in the public, commercial or not-for-profit sectors. All authors read and agreed on the final draft manuscript.

Competing interest

None.

Footnotes

Author contributions: Conceptualisation: SM, JoH; Data curation: SM, JoH; Formal analysis: SM, JoH; Investigation: SM, JoH; Methodology: SM, JJH, JoH; Supervision: JoH, JJH; Writing – original draft: SM; Writing – review and editing: SM, JJH, JoH.

References

Altman, DG 1991 Practical Statistics for Medical Research. Chapman and Hall: London, UK.Google Scholar
Altmann, J 1974 Observational study of behavior: Sampling methods. Behaviour 49: 227267. https://doi.org/10.1163/156853974X00534Google ScholarPubMed
Animal Welfare Act 2006 UK Legislation, c 45. https://www.legislation.gov.uk/ukpga/2006/45/contents (accessed 24 May 2024).Google Scholar
Arnold, W, Ruf, T and Kuntz, R 2006 Seasonal adjustment of energy budget in a large wild mammal, the Przewalski horse (Equus ferus przewalskii) II. Energy expenditure. Journal of Experimental Biology 209: 45664573. https://doi.org/10.1242/jeb.02536Google Scholar
Autio, E and Heiskanen, ML 2005 Foal behaviour in a loose housing/paddock environment during winter. Applied Animal Behaviour Science 91: 277288. https://doi.org/10.1016/j.applanim.2004.10.012Google Scholar
AWIN 2015 AWIN welfare assessment protocol for horses. https://doi.org/10.13130/AWIN_HORSES_2015Google Scholar
Birke, L, Hockenhull, J, Creighton, E, Pinno, L, Mee, J and Mills, D 2011 Horses’ responses to variation in human approach. Applied Animal Behaviour Science 134: 5663. https://doi.org/10.1016/j.applanim.2011.06.002Google Scholar
Blokhuis, HJ, Veissier, I, Miele, M and Jones, B 2010 The Welfare Quality® project and beyond: Safeguarding farm animal well-being. Acta Agriculturae Scandinavica Section A 60: 129140. https://doi.org/10.1080/09064702.2010.523480Google Scholar
Bott, RC, Greene, EA, Koch, K, Martinson, KL, Siciliano, PD, Williams, C, Trottier, NL, Burk A and Swinker A 2013 Production and environmental implications of equine grazing. Journal of Equine Veterinary Science 33: 10311043. https://doi.org/10.1016/j.jevs.2013.05.004Google Scholar
Bussan, SK 2022 Can cattle grazing benefit grassland butterflies? Journal of Insect Conservation 26: 359374. https://doi.org/10.1007/s10841-022-00373-8Google Scholar
Carter, RA, Geor, RJ, Burton Staniar, W, Cubitt, TA and Harris, PA 2009 Apparent adiposity assessed by standardised scoring systems and morphometric measurements in horses and ponies. Veterinary Journal 179: 204210. https://doi.org/10.1016/j.tvjl.2008.02.029Google ScholarPubMed
Christensen, JW, Zharkikh, T, Ladewig, J and Yasinetskaya, N 2002 Social behaviour in stallion groups (Equus przewalskii and Equus caballus) kept under natural and domestic conditions. Applied Animal Behaviour Science 76: 1120. https://doi.org/10.1016/S0168-1591(01)00208-8Google Scholar
Czycholl, I, Klingbeil, P and Krieter, J 2019 Interobserver reliability of the animal welfare indicators welfare assessment protocol for horsesJournal of Equine Veterinary Science 75: 112121. https://doi.org/10.1016/j.jevs.2019.02.005Google ScholarPubMed
Dai, F, Dalla Costa, E, Minero, M and Briant, C 2023 Does housing system affect horse welfare? The AWIN welfare assessment protocol applied to horses kept in an outdoor group-housing system: The ‘parcours’. Animal Welfare 32: 111. https://doi.org/10.1017/awf.2023.9Google Scholar
Dalla Costa, E, Dai, F, Lebelt, D, Scholz, P, Barbieri, S, Canali, E, Zanella, AJ and Minero, M 2016 Welfare assessment of horses: The AWIN approach. Animal Welfare 25: 481488https://doi.org/10.7120/09627286.25.4.481Google Scholar
Dalla Costa, E, Minero, M, Lebelt, D, Stucke, D, Canali, E and Leach, MC 2014a Development of the Horse Grimace Scale (HGS) as a pain assessment tool in horses undergoing routine castration. PLoS One 9: e92281. https://doi.org/10.1371/journal.pone.0092281Google ScholarPubMed
Dalla Costa, E, Murray, L, Dai, F, Canali, E and Minero, M 2014b Equine on-farm welfare assessment: a review of animal-based indicators. Animal Welfare 23: 323341. https://doi.org/10.7120/09627286.23.3.323Google Scholar
Dartmoor National Park Authority 2017 Ponies. https://www.dartmoor.gov.uk/living-and-working/farming/ponies (accessed 22 May 2024).Google Scholar
DEFRA 2017 Code of Practice for the Welfare of Horses, Ponies, Donkeys and Their Hybrids. https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/700200/horses-welfare-codes-of-practice-april2018.pdf (accessed 22 May 2024).Google Scholar
Duncan, P 1985 Time-budgets of Camargue horses III. Environmental influences. Behaviour 92: 188208. https://doi.org/10.1163/156853985X00442Google Scholar
Evans, DM, Villar, N, Littlewood, NA, Pakeman, RJ, Evans, SA, Dennis, P, Skartveit, J and Redpath, SM 2015 The cascading impacts of livestock grazing in upland ecosystems: a 10‐year experiment. Ecosphere 6: 15. https://doi.org/10.1890/ES14-00316.1Google Scholar
Fitzgerald, DM, Anderson, ST, Sillence, MN and de Laat, MA 2019 The cresty neck score is an independent predictor of insulin dysregulation in ponies. PLoS One 14: e0220203. https://doi.org/10.1371/journal.pone.0220203Google ScholarPubMed
Fleming, PA, Paisley, CL, Barnes, AL and Wemelsfelder, F 2013 Application of Qualitative Behavioural Assessment to horses during an endurance rideApplied Animal Behaviour Science 144: 8088. https://doi.org/10.1016/j.applanim.2012.12.001Google Scholar
Fraser, D 2008 Understanding animal welfare. Acta Veterinaria Scandinavica 50: 17. https://doi.org/10.1186/1751-0147-50-S1-S1Google Scholar
Fraser, D 2009 Animal behaviour, animal welfare and the scientific study of affect. Applied Animal Behaviour Science 118: 108117. https://doi.org/10.1016/j.applanim.2009.02.020Google Scholar
Fraser, MD, Stanley, CR and Hegarty, MJ 2019 Recognising the potential role of native ponies in conservation management. Biological Conservation 235: 112118. https://doi.org/10.1016/j.biocon.2019.04.014Google Scholar
Fuller, Z, Cox, JE and Argo, CM 2001 Photoperiodic entrainment of seasonal changes in the appetite, feeding behaviour, growth rate and pelage of pony colts. Animal Science 72: 6574. https://doi.org/10.1017/S1357729800055569Google Scholar
Fureix, C, Bourjade, M, Henry, S, Sankey, C and Hausberger, M 2012 Exploring aggression regulation in managed groups of horses Equus caballus. Applied Animal Behaviour Science 138: 216228. https://doi.org/10.1016/j.applanim.2012.02.009Google Scholar
Gonçalves Abrantes, J 2021 Ecological traits of free-ranging horses: Improving methodological approaches and disentangling determinants. Masters Thesis, University of Porto, Portugal.Google Scholar
Górecka, A and Jezierski, T 2007 Protective behaviour of Konik horses in response to insect harassment. Animal Welfare 16: 281283. https://doi.org/10.1017/S0962728600031523Google Scholar
Górecka, A, Jaworski, Z, Jaworska, J and Siemieniuch, M 2020 Welfare of free-roaming horses: 70 years of experience with Konik Polski breeding in Poland. Animals 10: 1094. https://doi.org/10.3390/ani10061094Google Scholar
Grazing Animals Project 2001 A Guide to Animal Welfare in Nature Conservation Grazing. https://www.rbst.org.uk/Handlers/Download.ashx?IDMF=8ef4244f-3b6f-4499-ba6d-f331f0e749ff (accessed 24 May 2024).Google Scholar
Grazing Animals Project 2008 The Breed Profiles Handbook: A Guide to the Selection of Livestock Breeds for Grazing Wildlife Sites. https://drive.google.com/file/d/13vQcYreLLqxXCJ5049K718lCdCJbJovz/view (accessed 22 May 2024).Google Scholar
Green, P 2013 The free-living ponies within the Exmoor National Park: Their status, welfare and future. https://www.burreken.be/wp-content/uploads/2015/11/Final-PDF-Pony-Report-condensed.pdf (accessed 24 May 2024).Google Scholar
Harley, JJ, Stack, JD, Braid, H, McLennan, KM and Stanley, CR 2021 Evaluation of the feasibility, reliability, and repeatability of welfare indicators in free-roaming horses: A pilot study. Animals 11: 1981. https://doi.org/10.3390/ani11071981Google ScholarPubMed
Hartmann, E, Søndergaard, E and Keeling, LJ 2012 Keeping horses in groups: A review. Applied Animal Behaviour Science 136: 7787. https://doi.org/10.1016/j.applanim.2011.10.004Google Scholar
Harvey, AM, Beausoleil, NJ, Ramp, D and Mellor, DJ 2020 A ten-stage protocol for assessing the welfare of individual non-captive wild animals: Free-roaming horses (Equus ferus caballus) as an example. Animals 10: 148. https://doi.org/10.3390/ani10010148Google ScholarPubMed
Henneke, D, Potter, G, Kreider, J and Yeates, B 1983 Relationship between condition score, physical measurements and body fat percentage in mares. Equine Veterinary Journal 15: 371372. https://doi.org/10.1111/j.2042-3306.1983.tb01826.xGoogle ScholarPubMed
Henry, BA 2003 Links between the appetite regulating systems and the neuroendocrine hypothalamus: lessons from the sheep. Journal of Neuroendocrinology 15: 697709. https://doi.org/10.1046/j.1365-2826.2003.01049.xGoogle ScholarPubMed
Hintze, S, Murphy, E, Bachmann, I, Wemelsfelder, F and Würbel, H 2017 Qualitative Behaviour Assessment of horses exposed to short-term emotional treatmentsApplied Animal Behaviour Science 196: 4451. https://doi.org/10.1016/j.applanim.2017.06.012Google Scholar
Hodder, KH, Bullock, JM, Buckland, PC and Kirby, KJ 2005 Large herbivores in the wildwood and in modern naturalistic grazing systems. English Nature Research Report 648.Google Scholar
Horseman, SV, Buller, H, Mullan, S and Whay, HR 2016 Current welfare problems facing horses in Great Britain as identified by equine stakeholders. PLOS One 11: e0160269. https://doi.org/10.1371/journal.pone.0160269Google ScholarPubMed
Hotchkiss, JW, Reid, SWJ and Christley, RM 2007 A survey of horse owners in Great Britain regarding horses in their care. Part 1: Horse demographic characteristics and management. Equine Veterinary Journal 39: 294300. https://doi.org/10.2746/042516407X177538Google ScholarPubMed
Jezierski, T, Jaworski, Z and Gorecka, A 1999 Effects of handling on behaviour and heart rate in Konik horses: comparison of stable and forest reared youngstock. Applied Animal Behaviour Science 62: 111. https://doi.org/10.1016/S0168-1591(98)00209-3Google Scholar
King, SS, Jones, KL, Schwarm, M and Oberhaus, EL 2013 Daily horse behavior patterns depend on management. Journal of Equine Veterinary Science 33: 365366. https://doi.org/10.1016/j.jevs.2013.03.105Google Scholar
Kruess, A and Tscharntke, T 2002 Contrasting responses of plant and insect diversity to variation in grazing intensity. Biological Conservation 106: 293302.Google Scholar
Linnartz, L and Meissner, R 2014 Rewilding horses in Europe: background and guidelines- a living document. Rewilding Europe: Nijmegen, The Netherlands.Google Scholar
Longland, AC 2013 Chapter 18: Pastures and pasture management. In: Geor, RJ, Harris, PA and Coenen, M (eds) Equine Applied and Clinical Nutrition: Health, Welfare and Performance pp 332350. Saunders Elsevier: Edinburgh, UK.Google Scholar
Mendl, M, Burman, OH and Paul, ES 2010 An integrative and functional framework for the study of animal emotion and moodProceedings of the Royal Society B: Biological Sciences 277: 28952904. https://doi.org/10.1098/rspb.2010.0303Google Scholar
Mullan, S, Szmaragd, C, Hotchkiss, J and Whay, HR 2014 The welfare of long-line tethered and free-ranging horses kept on public grazing land in South Wales. Animal Welfare 23: 2537. https://doi.org/10.7120/09627286.23.1.025Google Scholar
Petrie-Ritchie, RJ 2015 An investigation of the management options available to secure a future for the pony on Dartmoor: A behavioural- and opinion-based evaluation. Masters Thesis, Plymouth University, UK.Google Scholar
Ransom, JI, Cade, BS and Hobbs, NT 2010 Influences of immunocontraception on time budgets, social behavior, and body condition in feral horses. Applied Animal Behaviour Science 124: 5160. https://doi.org/10.1016/j.applanim.2010.01.015Google Scholar
Rare Breeds Survival Trust 2022 Watchlist 2022-23. https://www.rbst.org.uk/watchlist-overview (Accessed 22 May 2024).Google Scholar
Rhind, SM, Archer, ZA and Adam, CL 2002 Seasonality of food intake in ruminants: recent developments in understanding. Nutrition Research Reviews 15: 4365. https://doi.org/10.1079/NRR200236Google ScholarPubMed
R-Studio Team 2021 RStudio: Integrated Development for R. RStudio. PBC: Boston, MA, USA.Google Scholar
Rushen, J, Taylor, AA and de Passillé, AM 1999 Domestic animals’ fear of humans and its effect on their welfare. Applied Animal Behaviour Science 65: 285303.Google Scholar
Sigurjónsdóttir, H and Haraldsson, H 2019 Significance of group composition for the welfare of pastured horses. Animals 9: 14. https://doi.org/10.3390/ani9010014Google ScholarPubMed
Souris, A, Kaczensky, P, Julliard, R and Walzer, C 2007 Time budget, behavioral synchrony and body score development of a newly released Przewalski’s horse group Equus ferus przewalskii in the Great Gobi B strictly protected area in SW Mongolia. Applied Animal Behaviour Science 107: 307321. https://doi.org/10.1016/j.applanim.2006.09.023Google ScholarPubMed
Sterling, P 2004 Principles of allostasis: Optimal design, predictive regulation, pathophysiology, and rational therapeutics. In: Schulkin, J (ed) Allostasis, Homeostasis, and the Costs of Physiological Adaptation pp 1764. Cambridge University Press: Cambridge, UK.Google Scholar
Strickman, DWirtz, RLawyer, PGlick, JStockwell, S and Perich, M 1995 Meteorological effects on the biting activity of Leptoconops americanus (Diptera: Ceratopogonidae)Journal of American Mosquito Control Association 111520.Google ScholarPubMed
SRUC 2020 Qualitative Behaviour Assessment app. https://www.sruc.ac.uk/research/research-areas/animal-behaviour-welfare/qualitative-behaviour-assessment-app/ (Accessed 22 May 2024).Google Scholar
Thiery, JC, Chemineau, P, Hernandez, X, Migaud, M and Malpaux, B 2002 Neuroendocrine interactions and seasonality. Domestic Animal Endocrinology 23: 87100. https://doi.org/10.1016/S0739-7240(02)00148-0Google ScholarPubMed
Tree, I 2018 Wildling: The Return of Nature to a British Farm. Pan Macmillan: London, UK.Google Scholar
Tyler, SJ 1972 The behaviour and social organisation of the New Forest ponies. Animal Behaviour Monographs 5: 87196. https://doi.org/10.1016/0003-3472(72)90003-6Google Scholar
Udall, DM, Fraser, MD and Franklin, A 2023 Stakeholder Perceptions on Holistic Approaches to Landscape Management Using Semi-Feral Native Ponies in Wales. Considerations for Policy Development. http://doi.org/10.2139/ssrn.4395661 (Accessed 22 May 2024).Google Scholar
Van de Weerd, HA, Seaman, S, Wheeler, K, Goddard, P and McLean, B 2012 Use of artificial drinkers by unhandled semi-feral ponies. Applied Animal Behaviour Science 139: 8695. https://doi.org/10.1016/j.applanim.2012.03.012Google Scholar
Van Dierendonck, MC 2006 The importance of social relationships in horses. Utrecht University: Utrecht, The Netherlands.Google Scholar
Viksten, SM 2016 Improving horse welfare through assessment and feedback. Department of Animal Environment and Health, p 93. Swedish University of Agricultural Sciences: Uppsala, Sweden.Google Scholar
Viksten, SM, Hartmann, E, Schneller, K and Steen, M 2023 Welfare of extensively managed Swedish Gotland ponies. Animal Welfare 32: 112 https://doi.org/10.1017/awf.2023.20Google ScholarPubMed
Visser, E, Neijenhuis, F, de Graaf-Roelfsema, E, Wesselink, H, De Boer, J, van Wijhe-Kiezebrink, M, Engel, B and Van Reenen, C 2014 Risk factors associated with health disorders in sport and leisure horses in the Netherlands. Journal of Animal Science 92: 844855. https://doi.org/10.2527/jas.2013-6692Google ScholarPubMed
Wallis De Vries, MF, Parkinson, AE, Dulphy, JP, Sayer, M and Diana, E 2007 Effects of livestock breed and grazing intensity on biodiversity and production in grazing systems. Effects on animal diversity. Grass and Forage Science 62: 185197. https://doi.org/10.1111/j.1365-2494.2007.00568.xGoogle Scholar
Waran, NK 1997 Can studies of feral horse behaviour be used for assessing domestic horse welfare? Equine Veterinary Journal 29: 249251. https://doi.org/10.1111/j.2042-3306.1997.tb03117.xGoogle ScholarPubMed
Wemelsfelder, F 2007 How animals communicate quality of life: the qualitative assessment of behaviour. Animal Welfare 16: 2531. https://doi.org/10.1017/S0962728600031699Google Scholar
Wemelsfelder, F, Hunter, EA, Mendl, MT and Lawrence, AB 2000 The spontaneous qualitative assessment of behavioural expressions in pigs: first explorations of a novel methodology for integrative animal welfare measurement. Applied Animal Behaviour Science 67: 193215. http://doi.org/10.1016/S0168-1591(99)00093-3Google ScholarPubMed
Wemelsfelder, F, Hunter, TE, Mendl, MT and Lawrence, AB 2001 Assessing the ‘whole animal’: a free choice profiling approach. Animal Behaviour 62: 209220. https://doi.org/10.1006/anbe.2001.1741Google Scholar
Yngvesson, J, Rey Torres, JC, Lindholm, J, Pättiniemi, A, Andersson, P and Sassner, H 2019 Health and body conditions of riding school horses housed in groups or kept in conventional tie-stall/box housing. Animals 9: 73. https://doi.org/10.3390/ani9030073Google ScholarPubMed
Figure 0

Table 1. Details of free-ranging native pony herds including location, breed, sexes, ages, and numbers of ponies assessed

Figure 1

Table 2. Welfare assessment protocol (adapted from Harley et al., 2021) with details of animal- (AB) and resource-based (RB) indicators and scoring categories for each welfare indicator

Figure 2

Table 3. Score frequencies for common land (n = 47) and conservation grazing ponies (n = 29), with the results of Mann Whitney U tests between the two groups for each of the animal- and resource-based welfare indicators that make up the welfare assessment (adapted from Harley et al. 2021). Significant differences between the two groups are represented with bold P-values

Figure 3

Table 4. List of Qualitative Behavioural Assessment descriptors and definitions (modified from Fleming et al. 2013; Dalla Costa et al. 2016; Hintze et al. 2017)

Figure 4

Table 5. Kruskal-Wallis rank-sum test results between Exmoor common land (CLEX, n = 23), Dartmoor common land (CLDM, n = 24), Exmoor conservation grazing (CGEX, n = 15) and Dartmoor conservation grazing (CGDM, n = 14) ponies, with post hoc pair-wise Wilcoxon tests to determine the significant differences between the four groups for each welfare indicator

Figure 5

Figure 1. Loadings of the ten Qualitative Behavioural Assessment descriptors along the first two Principal Component Analysis factors (PC1, PC2) for common land (n = 47) ponies.

Figure 6

Figure 2. Loadings of Qualitative Behavioural Assessment descriptors along the first two Principal Component Analysis factors (PC1, PC2) for conservation grazing ponies (n = 29).

Figure 7

Table 6. Cohen’s unweighted kappa test statistic results (Kappa estimates, k) and the percentage agreement for each welfare indicator between the two assessments to measure the test/retest reliability