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ORIGINAL RESEARCH article

Front. Vet. Sci., 10 January 2019
Sec. Animal Behavior and Welfare
This article is part of the Research Topic Animal Transport and Related Management View all 6 articles

Do Pigs Have Adequate Space in Animal Transportation Vehicles?—Planimetric Measurement of the Floor Area Covered by Finishing Pigs in Various Body Positions

  • 1Clinic for Cattle, University of Veterinary Medicine Hannover, Foundation, Hannover, Germany
  • 2Institute for Animal Hygiene, Animal Welfare and Farm Animal Behaviour (ITTN), University of Veterinary Medicine Hannover, Foundation, Hannover, Germany

In this study, the floor area covered by individual finishing pigs in various body positions was measured using a contrast-based planimetric method for computer-assisted analysis of two-dimensional images. Two hundred and thirty-two finishing pigs were weighed during the last fifth of the fattening period and measured in different body positions using contrast-based planimetry. Thirteen body positions were defined based on characteristic directions of the head, legs and body. The lowest average covered floor area was found for body position A (pig standing up straight, nose touching the ground) with 0.288 ± 0.026 m2. The highest average covered floor area for a standing pig amounted to 0.335 ± 0.030 m2 in body posture ES (pig standing curved sideways, head raised above the dorsal line) and, for a lying pig, 0.486 ± 0.040 m2 (posture LL, pig lying in fully lateral recumbent position). The covered floor surface significantly depended on the weight of the animal and the body posture. Allometric estimations previously described for calculating the floor area physically covered by a pig's body are not consistently precise in depicting the actual areas covered. The minimal floor area offered in animal transportation vehicles, according to European legislation, is insufficient in the case of all pigs lying in the fully recumbent position simultaneously, without the pigs being forced to partially overlap one another. Therefore, both allometric formulas and legislation should be modified on the basis of these results and further studies with pigs of modern genetic origin should be conducted.

Introduction

In the European Union about 255 million pigs are slaughtered each year (1). Most of these are fattening pigs transported to the slaughterhouse by trucks. During these journeys, fattening pigs are exposed to numerous and variable stressors, such as variations in ambient temperature, vehicle movements, handling by humans, social pressure by mixing unfamiliar pigs or inappropriate space available (24). It is generally accepted that the loading density on the transport vehicle has a strong influence on the welfare of the pigs and that the provision of appropriate space is a key factor (5). To provide recommendations for statutory space requirements, the floor area covered by a pig's body (referring to the static space) requires a precise definition. This can either be calculated with mathematical formulas by means of allometric principles (69), or determined using data collected directly on the animal's body or measured indirectly using image analysis (10, 11). Allometric formulas were drawn up based on measurements of length, width and height of whole animals' bodies, or their body parts. In pigs, these measurements were carried out by Petherick and Baxter (12) in the 1980s and the derived allometric formulas were designated by the authors as a “good starting point” (13). However, on-going technological progress has enabled more precise methods, such as computer-based planimetric image analysis, which considers the animals' accurate actual body outline, as shown in poultry (14, 15). Methods for area calculation from two-dimensional images of pig body dimensions were also tested for various fields of application (10, 1618). However, data from various genetics or weight classes for the verification of allometric estimations or recommendations for loading densities are lacking.

Accordingly, current European legislation is based on outdated data. In Council Regulation (EC) No 1/2005 (19) for pigs of around 100 kg, a maximum of 235 kg live weight per m2 floor area on a road transport vehicle is given. This is intended to ensure that all pigs are able to stand and to lie in their natural body position. The value of 235 kg/m2 has been adopted from the Council Directive 95/29/EC (20) without modifications, because the member states were not able to agree on a revision of stocking densities until the adoption of the current regulation. Clarification of this issue in a separate proposal, written within 4 years of coming into effect, was decided but is missing until today (21). Originally, the value of 235 kg/m2 was based on recommendations by Lambooy et al. (22), who rated this minimum loading density for finishing pigs as a compromise of “animal welfare, meat quality aspects and economy of transport.” Thus, the base for loading densities recommended by European legislation dates back a few decades. Since then, the genetics in fattening pigs, not only in Germany, have changed, resulting in an increase of slaughter weights from around 83 kg in 1984 to 95 kg nowadays (23), and live weights increased from around 100 kg to around 110 kg or more. This should influence the spatial needs considerably, although the regulation also states that depending on the breed, size and physical condition of the pigs, the weather and the journey time, an undefined increase of up to 20% of the minimum floor area may be required. There lacks, however, a more precise definition.

The aim of this study was to determine the actual floor taken up by finishing pigs of a modern pig hybrid type in different body positions. An existing computer-assisted planimetric image analysis method was modified for application on fattening pigs. By considering measured values according to the live weight, and comparison with values calculated by allometric formulas, the accuracy and practicability of existing allometric formulas estimating the floor area physically occupied by an individual pig's body were assessed. Based on the static space measurements, a further objective was to examine whether sufficient space on road transport vehicles is provided to fattening pigs in the actual European regulation if the minimum requirements are met.

Materials and Methods

Animals

A total of 232 modern finishing pig hybrids (108 ♂ neutered and 124 ♀) that are genetically prevalent in Europe (Danish Breed Sows x Pietrain boar) were weighed within the last fifth of the fattening period, representing the weights expected on animal transport vehicles, and measured by contrast-based planimetry. The measurements were carried out on one farm with two compartments, each with 200 fattening places in total in 13 trial days from June until November 2013. All animals originated from the farm's own piglet production. All animals in this study were kept in accordance with European Union guidelines (24). The protocol was approved by the University's Animal Protection commissioner.

Experimental Setup for the Assessment of Area Values

For the determination of the static space, the KobaPlan method (11), until now mainly used for surveying poultry, was used for computer-assisted analysis of two-dimensional images (11, 14, 15). The method setup had to be adapted for application on fattening pigs. A planimetry box (245.00 × 125.00 × 120.00 cm) was constructed. To prevent slipping, the base plate consisted of an aluminum checker plate (125.00 × 245.00 cm, thickness 4.0 mm). The side panels were built of solid wooden material (thickness: 9.0 mm) to resist the occasionally rough exploratory behavior of pigs. To enhance the contrast between background and animal, the base and side plates were painted with fluorescent color, the surrounding area was darkened and the box was lighted with ultraviolet light [Omnilux UV- energy-efficient lamp: 85 W (2x), 25 W (2x); Omnilux, Waldbüttelbrunn, Germany and Eurolite UV- neon tube; Eurolite, Waldbüttelbrunn, Germany]. A digital SLR camera (Canon EOS 600D; Canon Deutschland GmbH, Krefeld, Germany) with a standard camera lens (18-55 IS II; Canon Deutschland GmbH, Krefeld, Germany) was fixed centrally above the box and focused on the bottom plate. The distance was 245.00 cm between the bottom surface and the lens. The camera was connected to a notebook via a serial USB interface. Using control software (EOS Utility, Canon Deutschland GmbH, Krefeld, Germany) a live image was transferred, and the camera was triggered via the notebook keyboard manually.

First the current live weight of each individual pig was documented by weighing with a livestock scale (Box livestock scales; Baumann Waagen- und Maschinenbau GmbH, Thiersheim, Germany). Then, the animal was led into the planimetry box where various two-dimensional plan top view photographs were taken under constant shooting conditions (focal length 18.0 mm, consistent focus) (Supplementary Figure 1). An attempt was made to photograph each animal in 10 standing and three lying body positions, chosen with the intent to reflect the natural movement of pigs. Later, one single characteristic image of each pig was chosen for each available position. The 13 positions, explained by exemplary images, the numbers of pictures for each position, information on gender and weight structures of the total data set are listed in Table 1.

TABLE 1
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Table 1. Description of evaluated pigs' body positions, number of analyzed individual pictures (n; ntotal = 1,583 from 232 pigs) for each position, gender (tot = total sample; tot_fem = females of total sample; tot_mn = neutered males of total sample), and live weights (Mean, SD = standard deviation, Min = Minimum, Max = Maximum); a,bColumns with different superscripts differ significantly (p < 0.05).

Image Analysis

KobaPlan software (11) was used in version “KobaPlan v.01.teta” (© Briese 2007–2013, eduToolbox@Bri-C GmbH, Sarstedt, Germany). On the basis of the contrast between the animal and its environment, the area occupied by the animal's body was calculated automatically by the software. For this, a reference surface was formed by a planar rectangular wooden board with an extent similar to a fattening pig body in supervision (0.420 m2). This reference surface was used to calculate the relation between known area and number of pixels as base for the assessment of the area occupied by the animal's body. To analyze the images of standing pigs, the reference was mounted at a height of 69.00 cm, which was the mean height by measuring pigs in standing position using a stick measuring device and a folding rule (n = 348, height 68.54 ± 10.69 cm). For lying pigs, a mean height of 29.00 cm (n = 171, height 29.44 ± 5.90 cm) was measured with the same procedure. The reference surface was photographed under the same conditions as the animals, and information about size and the dimensions on the picture were imported to the software. Additionally, the program created a copy of the original image, which showed the calculated area colored blue for the visual verification of the recognition accuracy. About one third of the images were recognized without further processing, and two thirds had to be adapted using photo editing software (Adobe Photoshop CS6, Adobe Systems GmbH, Munich, Germany). In many cases, a subsequent increase in contrast was sufficient to ensure correct recognition of images. Shadows, feces or other contamination of the planimetry box had to be partly retouched to enable detection.

Statistical Analyses

The measured data were described with basic descriptive statistical analysis parameters (averages, minimum and maximum values, standard deviations) calculated by the Excel program (Microsoft EXCEL 2014, Microsoft Corporation, Redmond, USA). Further statistical analyses were performed using SAS 9.4 (SAS Institute Inc., Cary, USA). For examining normal distribution, the procedure PROC UNIVARIATE was used. The differences of weights between the groups of position were tested with PROC GLM and the Tukey method was applied for the least square means. Comparisons of means were carried out using the PROC TTEST. Furthermore, the Spearman's correlation between mean weights and the covered floor area within the groups of body position were calculated using the SAS procedure PROC CORR. Results were considered statistically significant if the related p-values were <0.05.

Comparison With Results From Allometric Formulas for the Calculation of the Floor Space Physically Covered

Values calculated on the basis of recommended allometric formulas taken from the review of Petherick and Phillips (25) were compared with the corresponding measured values. For the calculation of the covered floor area of single pigs while “standing” and while “lying on sternum/belly with legs folded beneath the body” the same allometric formula was recommended: a = 0.019 W0.66 m2 (a = covered area, W = live weight) (25). As W, the mean weight assessed for the different body position groups was used. The floor areas needed for pigs of both postures were calculated by this formula and were compared with the planimetric values measured for pigs in different standing body positions and with those measured for the LBC position [“lying in sternal (belly chest) recumbency”]. The values calculated for “semirecumbent lying” [formula according to Petherick and Phillips (25): a = 0.025 W0.66 m2] were compared to those measured by planimetry for position LCL [“lying in semilateral (lateral chest) recumbency”], and for “fully recumbent lying” (formula: a = 0.047 W0.66 m2) with position LL [“lying in lateral (fully) recumbency”].

Comparison With Recommended Legal Space Requirements on Transport Vehicles in Europe

The floor area values measured were set into relation to legal space requirements of Council Regulation (EC) No 1/2005 (19). Therefore, the average covered areas measured for each position group were compared with the minimum legal recommendations of 235 kg/m2, calculated for the average animal weights within the 13 body position groups.

Results

Measured Area Values

In total, 1,583 (n) pictures of 232 pigs were evaluated. The weight range was between 75.00 and 133.00 kg (mean ± standard deviation: 109.01 ± 11.45 kg; Table 1). Given that not all pigs could be assessed in all positions, we compared average body weights of position groups to make sure that there were no or only small differences between the groups, and therefore comparability exists. Only the mean weights for body position group E (106.26 ± 11.45 kg) and position group CS (111.22 ± 10.59 kg) varied significantly, while for all other position groups, no significant variations were detected (Table 1). Thus, the different area values between standing and lying animals can be related to the position and not to any weight differences.

The covered floor area depended on the animal's body position, as shown in Table 2. In general, lying positions required significantly more space than standing positions (Figure 1). In more detail, the assessed values for the different body position groups are reflected in Figure 2. In standing positions, the mean covered area values varied between 0.288 ± 0.026 m2 for position A (“Standing up straight, nose touching the ground”) and 0.335 ± 0.030 m2 for body position ES (“Standing curved sideways, head raised above the dorsal line”). In lying positions, the occupied space ranged between 0.428 ± 0.032 m2 for pigs in body position LBC [“Lying in sternal [belly chest] recumbency”] and 0.486 ± 0.040 m2 in body position L [“Lying in lateral (full) recumbency”]. The absolute minimum value of 0.203 m2 floor area physically covered by an individual pig was measured for a pig of 83.50 kg while standing in body position A. The absolute maximum value of 0.578 m2 was found for a pig of 131.00 kg lying fully recumbently in body posture LL (Table 2).

TABLE 2
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Table 2. Floor area (m2) physically covered by a fattening pig in various body positions (ntotal = 1,583 pictures from 232 pigs; Mean, SD = standard deviation, Min = Minimum, Max = Maximum).

FIGURE 1
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Figure 1. Covered floor area of pigs in standing and lying body positions; standing positions A-ES, lying positions LBC -LL (see Tables 1, 2), ***p < 0.001.

FIGURE 2
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Figure 2. Covered floor area of pigs in body positions AL-LL (see Tables 1, 2).

In all position groups, the covered floor surface depended significantly on the weight of the animal (p < 0.0001). Though areas corresponding to lying positions appear to have smaller correlation coefficients compared to standing positions, this could be related to the shape of the pigs and the mass of the hind quarters, but a final explanation cannot be given. Correlations between the covered floor area and live weight are represented in Table 3.

TABLE 3
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Table 3. Spearman's correlations between mean weights and covered floor area within the groups of body positions A-LL (see Tables 1,2); all results: p < 0.05.

Comparison With Results From Allometric Formulas for the Calculation of the Floor Space Physically Covered

The calculation of the covered floor space by allometric formulas, based on the respective mean live weights in the different body position groups resulted in areas between 0.41m2 (Position E) and 1.03 m2 [Position LL, “lying in lateral (full) recumbency”]. The comparison of the calculated covered areas according to Petherick and Phillips (25) for both standing and lying positions revealed that the values calculated were—with the exception of one position (LBC)—significantly above the average values assessed by planimetric measurements (Figure 3). For animals “lying on sternum/belly with legs beneath the body,” the calculated area was less than the mean area measured for position LBC with a deviation of 0.010 m2. For the ten standing postures (A-ES), the average deviation between calculated and measured areas was 0.107 m2 (± 0.017, minimum: 0.089 m2 for body position ES, maximum: 0.132 m2 for body position A). For animals lying semirecumbently (according to body position LCL), the calculated area was 0.103 m2 above the mean area actually measured. The highest deviation was found for animals in body position LL, with a 0.544 m2 difference between the calculated and measured space.

FIGURE 3
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Figure 3. Measured values (m2) of floor area physically covered in various body positions (A-LL; see Tables 1, 2) in comparison with values calculated with allometric formulas by Petherick and Philips (2009) according to the body posture (a = 0.019 W0.66 m2 (a = covered area, W = live weight (kg) for “standing” and “lying on sternum/belly with legs folded beneath the body” according to position A-LBC; a = 0.025 W0.66 m2 for “semirecumbent lying” according to LCL; a = 0.047 W0.66 m2for “fully recumbent lying” according to LL) and the mean live weight of each body position group, ***p < 0.001.

Comparison With Recommended Legal Space Requirements on Transport Vehicles in Europe

The calculation of legal space requirements based on Council Regulation (EC) No 1/2005 (19)—without the 20% addition—showed minimum space requirements for the respective mean live weights in the different body position groups between 0.452 m2 (Position E) and 0.473 m2 (Position CS). Concerning these legal minimum requirements, no differentiation between different body positions is given.

Comparing the averages of the measured floor areas by planimetry with the minimum space requirements, the measured covered areas for the static space were below the legally required minimums for 12 of the 13 positions, with the exception of body position LL, exceeding the legal recommendations by 0.028 m2. The other deviations varied between 0.012 m2 for body posture E and 0.177 m2 for body posture AS (Figure 4). Except for LBC, those deviations between measured and legally required space were significant. Deviations correspond to the floor space that remains available to an individual pig to carry out further movements, respectively, to sustain their individual distance. For instance, for a pig “lying in sternal (belly chest) recumbency” (LSL) a free area of 0.033 m2 remained, while in a fully recumbent body posture (LL), the floor space actually physically needed was above the minimum legal recommendation (Figure 4).

FIGURE 4
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Figure 4. Measured values (m2) of floor area physically covered in various body positions (A-LL; see Tables 1, 2) in comparison with values calculated according to the space requirements from Council Regulation (EC) No 1/2005 (2004) (for pigs of around 100 kg” a maximum of 235 kg live weight per m2, adapted to the mean live weight of each body position group), **p < 0.01, ***p < 0.001.

Discussion

Commercial transport is a complex stressor with potential negative consequences for animal welfare (2628). The impact on animal welfare is related to different factors with various and often not clearly defined impacts, and space is one of the most important influencing factors. The precise determination of space requirements is essential. The minimum space requirement of an animal is given by its physical dimensions, defined as static space. One aim of this study was to assess the static space of finishing pigs in different body positions by planimetry. By applying this method, our study supports the approach of calculating floor area needs based on the animal's weight and body position, which is supported by previous scientific studies (25) and is a legal requirement (19).

The limitation of such planimetric measurements is that additional demands, defined by dynamic and social space, are disregarded. While static space takes the body dimensions of the pig into account, dynamic and social space include the additional space needed for (non-) locomotor body movements and social interactions, respectively (7, 18). Moreover, the applied planimetric measurement is on a single animal basis and does not take social group aspects such as huddling into account.

However, as a minimum requirement, the static space is of essential importance. The planimetric method used in this study is an established and well-tried method for different animal species, including chickens, rabbits and piglets (15, 2932), but needed to be modified for application on fattening pigs. This modification worked well and delivered good results, even though modern technologies, for instance three-dimensional cameras, offer further, less labor-intensive options (33, 34). With the modified planimetric method, the assessment of 13 different body positions was realized. The consideration of different standing and lying positions is of special importance for the recommendations of space requirements on transportation vehicles, especially for long-distance transports. Pigs on transport vehicles should be able to rest simultaneously (35). Therefore, not only the space for standing, but also for lying positions had to be considered. In this study, for the first time, data of the actual floor area physically needed by finishing pigs of current genetics for different positions are represented. Comparable data on static space covered by a pig's body from older studies are rare, for instance McGlone and Pond (36) stated that a lying pig in the lateral position of around 100 kg covers 0.56 m2, which is about 0.08 m2 more than in our study for the respective position.

The larger body size of genetically modern pigs is also reflected in increased mean weights. The assessed variation between 75.00 and 133.00 kg allowed an analysis for correlations between body weight and allocated space. It was shown that the floor area covered by an individual fattening pig body depends mainly on its weight, and on the pig's body position, as other studies had already reported (6, 10). This confirmed correlation between weight and space reveals the importance of adapting recommendations for space requirements, such as Council Regulation (EC) No 1/2005 (19), based on conditions over 30 years ago, to the realities of transporting modern finishing pigs. Concerning the results for the allocated space in different body positions, lying pigs, especially in lateral recumbency, need significantly more space than standing ones. This fact is of critical importance with regards to determining the required space in transportation vehicles, as all pigs should be able to lie down (35). With the values determined in our study, this can be assumed not only for lying fully recumbent, but also for lying in half recumbency there is little space. For higher weights (130–135 kg), exceeding the limit values for semi-recumbent lying is conceivable. Depending on the ambient temperature and group composition, animals may be either dense or loose together. However, it can be assumed that the problem of “too much” space is more applicable to standing animals, although the literature does not provide adequate explanations. A central problem with the determination of space requirements in transport vehicles, especially on long-distance-journeys, is the animals' behavior and, following, the problem of too much or too less space. It can be assumed that pigs take a standing position at the beginning of the journey and lie down at a later time to rest. This is the reason why sometimes for short journeys less space requirements are suggested. To our knowledge, no studies are available describing the behavior of pigs on transport vehicles sufficiently to derive representative durations of “standing periods” and “lying periods,” especially because those are influenced by many other factors. For that, further comprehensive studies are needed.

As the measurement of allocated space in living animals is not easy to determine, certain formulas have been developed to calculate the respective areas by the weight of the animal. Proposed by Petherick (7) and supported in additional studies (25, 37), all equations used transform bodyweight into space with the help of a space allowance coefficient. As this coefficient differs even for same body weight classes in these studies, likely based on variations in the study designs, different recommendations for space allowance were given if allometric formulas had been used (34, 37). In our study, a comparison of measured areas for the defined body positions with the results of three different formulas for three respective body positions described by Petherick and Phillips (25) was realized. The results clearly indicate that, especially with regards to “fully recumbent lying,” the equitation was not precise; even though both in measurements and in calculations, the fully recumbent body position requires the largest space, the equitation resulted in a difference of 0.544 m2 above the measured value of 0.486 ± 0.040 m2. These results clearly show that there is room for improvement in allometric formulas with respect to accuracy for finishing pigs in different body positions.

Regarding the comparison with recommended legal space requirements on transport vehicles in Europe, the average mean weight of the finishing pigs in this study was 109.01 ± 11.45 kg, about 10 kg higher than the weight mentioned in Council Regulation (EC) No 1/2005 (19), which is “around 100 kg.” The recommendation of a loading density of 235 kg/m2 was adapted to the actual mean weights of the different body position groups. In this context, it has to be emphasized that the considerations in this study are on a theoretical base. Under practical conditions, there is no individual calculation of the space offered per pig, rather according to the average weight of the loaded lot, usually estimated by the transportation staff.

For the best possible animal welfare on transport vehicles, not only the static space has to be taken into account, but also the additional remaining free space. When comparing the measured values with the legally required ones, it is important to keep in mind that only static space is considered by planimetric measurements. The deviations between measured and legally required space assessed in this study reflect the free space that is available for finishing pigs' dynamic and social space needs. However, knowledge or recommendations on these dynamic and social space needs, especially on transportation vehicles, are lacking. Particularly on long-distance transports, all pigs in the transportation vehicle should be able to lie down and get up with normal movements. With too little floor space available, the pigs are forced to stand very close to each other and to balance vehicle movements. Lying down in exhaustion can be impaired and the animals could fall over one another. These situations may increase stress, the number of injuries or even animal mortality (3840). Moreover, animal body temperature can rise, resulting in discomfort or even in transport deaths (38). Crowding can also cause social pressure, resulting in conflicts and fights, or a constant change of body positions, which may lead to physiological reactions and exhaustion (22, 41). Therefore, sufficient space has to be provided to allow the animals to lie down (35) and evade other individuals. On the contrary, the provision of too much space may also be a risk factor, and hence should probably be avoided as well (26, 35). At low loading densities, the animals might not be able to keep the balance on turbulent route sections or during sudden braking and can be thrown through the vehicle (42).

Even though deviations for standing positions seem to hint on an adequate space provision, we cannot answer the question of whether the remaining free floor space is enough for an individual standing pig. For the space allocated for lying positions, the conclusion is clearer; deviations are much lower and even negative in the case of body position LL for the pigs examined in this study. Therefore, for lying finishing pigs, the minimal floor area offered on animal transportation vehicles according to European legislation is insufficient for modern finishing pigs.

Conclusion

The results of this study reveal that finishing pigs of modern genetics are heavier than the average pig of 30 years ago, when scientific results on body dimensions first entered into legislation. It can be assumed also that the static space that is taken by the pigs has increased, as the weights are significantly related to this space. It was found that allometric estimations scientifically described for calculating the floor area physically covered by a pig's body are not consistently accurate. Especially for lying positions, allometric formulas need to be modified. Moreover, this data provides a basis for reflecting and discussing legal requirements for pig transport. It was shown that the minimal floor area offered on animal transportation vehicles, according to European legislation, is not sufficient to grant finishing pigs of modern genetic origin enough static space in the fully recumbent body position. Therefore, further data of body dimensions of single pigs, and especially groups of animals, are needed to determine the static space needs. Even more important, further studies on the behavior of pigs in transport situations have to be considered to increase our understanding of the required free space.

Data Availability Statement

The datasets for this study are available on request. The raw data supporting the conclusions of this manuscript will be made available by the authors (without undue reservation) to any qualified researcher.

Author Contributions

JH, BS, HA, and NK contributed to the study design. HA organized and conducted the field work. HA and NV performed the statistical analysis. BS supported the field work. HA prepared the original draft of the manuscript. NK reviewed and edited the first version of the manuscript. JH and NK supervised the project. JH and HA acquired the funding. All authors contributed to manuscript revisions, read, and approved the submitted version.

Funding

This study was financially supported by the foundation Tönnies Forschung. It was part of a doctoral project within the Lower Saxony Doctoral Program Animal Welfare in Intensive Livestock Production Systems.

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

The authors thank the staff of the farm, and those who have assisted in the development and construction of the experimental setup and in the measurements. Moreover, the authors thank Dr. Andreas Briese for the provision of the KobaPlan software.

Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fvets.2018.00330/full#supplementary-material

Supplementary Figure 1. Picture of the experimental set up on farm (Photo: H. Arndt).

References

1. Eurostat. Slaughtering in Slaughterhouses - Annual Data. (2018). Available online at: http://ec.europa.eu/eurostat/web/products-datasets/-/apro_mt_pann (Accessed 10.08.2018).

2. Barton Gade P. Effect of rearing system and mixing at loading on transport and lairage behaviour and meat quality: comparison of free range and conventionally raised pigs. Animal (2008) 2:1238–46. doi: 10.1017/S1751731108002565

PubMed Abstract | CrossRef Full Text | Google Scholar

3. Barton Gade P. Effect of rearing system and mixing at loading on transport and lairage behaviour and meat quality: comparison of outdoor and conventionally raised pigs. Animal (2008) 2:902–11. doi: 10.1017/S1751731108002000

PubMed Abstract | CrossRef Full Text | Google Scholar

4. EFSA. European food safety agency: panel on animal health and welfare: scientific opinion concerning the welfare of animals during transport. EFSA J. (2011) 9:1966. doi: 10.2903/j.efsa.2011.1966

CrossRef Full Text

5. Broom DM. Causes of poor welfare in large animals during transport. Veter Res Commun. (2003) 27(Suppl 1):515–8. doi: 10.1023/B:Verc.0000014210.29852.9a

PubMed Abstract | CrossRef Full Text | Google Scholar

6. Petherick JC. A note on allometric relationships in Large White X Landrace pigs. Anim Product. (1983) 36:497–500.

Google Scholar

7. Petherick JC. A biological basis for the design of space in livestock housing. In: Baxter SH, Baxter MR, MacCormack JAC. editors. Farm Animal Housing and Welfare. The Hague: Martinus Nijhoff Publishers (1983). p. 103–20.

Google Scholar

8. Petherick JC. Spatial requirements of animals: allometry and beyond. J Veter Behav Clin Appl Res. (2007) 2:197–204. doi: 10.1016/j.jveb.2007.10.001

CrossRef Full Text | Google Scholar

9. Randall JM. Environmental parameters necessary to define comfort for pigs, cattle and sheep in livestock transporters. Anim Sci. (1993) 57:299–307. doi: 10.1017/S0003356100006929

CrossRef Full Text | Google Scholar

10. Brandl N, Jorgensen E. Determination of live weight of pigs from dimensions measured using image analysis. Comput Electron Agric. (1996) 15:57–72. doi: 10.1016/0168-1699(96)00003-8

CrossRef Full Text | Google Scholar

11. Briese A, Hartung J. Measurement of floor space allowance of Lohmann Silver hens using biometric data. Berliner Munchner Tierarztliche Wochenschrift (2009) 122:241–8. doi: 10.2376/0005-9366-122-241

PubMed Abstract | CrossRef Full Text | Google Scholar

12. Petherick JC, Baxter SH. Modelling the static spatial requirements of livestock. In: MacCormack JAD, editor. Modelling, Design and Evaluation of Agricultural Buildings. Commission Internationale de Genie Rurale, Section II Seminar. Scottish Farm Buildings Investigation Unit, Aberdeen. (1981). p. 75–82.

13. Baxter SH, Petherick JC. Space requirements of pigs. Anim Product. (1983) 36:531.

14. Briese A, Spindler B. Discussion of actual legal minimum requirements for feeder space and perch length in laying hen husbandry in the light of the body widths measured in Lohmann Selected Leghorn and Lohmann Brown laying hens. Berliner Munchner Tierarztliche Wochenschrift (2013) 126:163–8.

PubMed Abstract | Google Scholar

15. Spindler B, Clauss M, Briese A, Hartung J. Planimetric measurement of floor space covered by pullets. Berliner Munchner Tierarztliche Wochenschrift (2013) 126:156–62.

PubMed Abstract | Google Scholar

16. Doeschl-Wilson AB, Green DM, Fisher AV, Carroll SM, Schofield CP, Whittemore CT. The relationship between body dimensions of living pigs and their carcass composition. Meat Sci. (2005) 70:229–40. doi: 10.1016/j.meatsci.2005.01.010

PubMed Abstract | CrossRef Full Text | Google Scholar

17. Doeschl-Wilson AB, Whittemore CT, Knap PW, Schofield CP. Using visual image analysis to describe pig growth in terms of size and shape. Animal Sci. (2004) 79:415–27. doi: 10.1017/S1357729800090287

CrossRef Full Text | Google Scholar

18. Pastorelli G, Musella M, Zaninelli M, Tangorra F, Corino C. Static space requirements of growing-finishing and heavy pigs. Livestock Sci. (2006) 105:260–4. doi: 10.1016/j.livsci.2006.05.022

CrossRef Full Text | Google Scholar

19. Council Regulation EC No 1/2005 (2004) of 22 December 2004 on the protection of animals during transport and related operations and amending Directives 64/432/EEC and 93/119/EC and Regulation (EC) No 1255/97 (2004).

20. Council Directive 95/29/EC (1995) of 29 June 1995 amending Directive 91/628/EEC concerning the protection of animals during transport (1995).

21. Deutscher Bundestag. Die Tiertransportverordnung der EU. Wissenschaftliche Dienste 46/06 (2006).

22. Lambooy E, Garssen GJ, Walstra P, Mateman G, Merkus GSM. Transport of pigs by car for 2 days - some aspects of watering and loading density. Livestock Product Sci. (1985) 13:289–99. doi: 10.1016/0301-6226(85)90007-7

CrossRef Full Text | Google Scholar

23. Statistisches Bundesamt. Land- und Forstwirtschaft, Fischerei; Viehbestand und tierische Erzeugung 2016. Fachserie 3 Reihe 4 (2017).

24. Council Directive 2010/63/EU (2010) of the European Parliament and of the Council of 22 September 2010 on the protection of animals used for scientific purposes (2010).

25. Petherick JC, Phillips CJC. Space allowances for confined livestock and their determination from allometric principles. Appl Anim Behav Sci. (2009) 117:1–12. doi: 10.1016/j.applanim.2008.09.008

CrossRef Full Text | Google Scholar

26. Broom DM. The effects of land transport on animal welfare. Rev Sci Tech Office Int Des Epizooties (2005) 24:683–91.

PubMed Abstract | Google Scholar

27. Fazio E, Ferlazzo A. Evaluation of stress during transport. Veter Res Commun. (2003) 27:519–24. doi: 10.1023/B:Verc.0000014211.87613.D9

PubMed Abstract | CrossRef Full Text | Google Scholar

28. Warriss PD. The welfare of slaughter pigs during transport. Anim Welfare (1998) 7:365–81.

Google Scholar

29. Fels M, Sange MD, Kemper N. Planimetric measurement as a method of scientific assessment of space requirement of young suckling piglets in the creep area. Livestock Sci. (2016) 191:37–42. doi: 10.1016/j.livsci.2016.07006

CrossRef Full Text | Google Scholar

30. Giersberg MF, Kemper N, Fels M. Planimetric measurement of floor space covered by fattening rabbits and breeding does in different body positions and weight classes. Livestock Sci. (2015) 177:142–50. doi: 10.1016/j.livsci.2015.04.010

CrossRef Full Text | Google Scholar

31. Giersberg MF, Hartung J, Kemper N, Spindler B. Floor space covered by broiler chickens kept at stocking densities according to Council Directive 2007/43/EC. Veter Rec. (2016) 179:124. doi: 10.1136/vr.103563

PubMed Abstract | CrossRef Full Text | Google Scholar

32. Habig C, Beyerbach M, Kemper N. Comparative analyses of layer males, dual purpose males and mixed sex broilers kept for fattening purposes regarding their floor space covering, weight-gain and several animal health traits. Eur Poultry Sci. (2016) 80:128. doi: 10.1399/eps.2016.128

CrossRef Full Text

33. Fels M, Konen K, Hessel E, Kemper N. Biometric measurement of static space required by weaned piglets kept in groups of eight during 6 weeks. Anim Product Sci. (2018). doi: 10.1071/AN17445 [Epub ahead of print].

CrossRef Full Text | Google Scholar

34. Fels M, Konen K, Hessel E, Kemper N. Determination of static space occupied by individual weaner and growing pigs using an image-based monitoring system. J Agric Sci. (2018) 156:282–90. doi: 10.1017/S002185961800014X

CrossRef Full Text | Google Scholar

35. Broom DM. How well do farm animals cope with their environment during transport? Fleischwirtschaft (1996) 76:279–81.

36. McGlone J, Pond WG. Pig Production: Biological Principles and Applications. 1st Edn. Boston, MA: Cengage Learning (2003). p. 203.

Google Scholar

37. Gonyou HW, Brumm MC, Bush E, Deen J, Edwards SA, Fangman T, et al. Application of broken-line analysis to assess floor space requirements of nursery and grower-finisher pigs expressed on an allometric basis. J Anim Sci. (2006) 84:229–35. doi: 10.2527/2006.841229x

PubMed Abstract | CrossRef Full Text | Google Scholar

38. Ritter MJ, Ellis M, Brinkmann J, DeDecker JM, Keffaber KK, Kocher ME, et al. Effect of floor space during transport of market-weight pigs on the incidence of transport losses at the packing plant and the relationships between transport conditions and losses. J Anim Sci. (2006) 84:2856–64. doi: 10.2527/Jas.2005-577

PubMed Abstract | CrossRef Full Text | Google Scholar

39. Warriss PD. Choosing appropriate space allowances for slaughter pigs transported by road: a review. Veter Rec. (1998) 142:449–54.

PubMed Abstract | Google Scholar

40. Warriss PD, Brown SN, Knowles TG, Edwards JE, Kettlewell PJ, Guise HJ. The effect of stocking density in transit on the carcass quality and welfare of slaughter pigs: 2. results from the analysis of blood and meat samples. Meat Sci. (1998) 50:447–56. doi: 10.1016/S0309-1740(98)00057-6

PubMed Abstract | CrossRef Full Text | Google Scholar

41. Lambooy E, Engel B. Transport of slaughter pigs by truck over a long-distance - some aspects of loading density and ventilation. Livestock Product Sci. (1991) 28:163–74. doi: 10.1016/0301-6226(91)90006-C

CrossRef Full Text | Google Scholar

42. Gade PB, Christensen L. Effect of different stocking densities during transport on welfare and meat quality in Danish slaughter pigs. Meat Science (1998) 48:237–47.

PubMed Abstract | Google Scholar

Keywords: body dimensions, image analysis, loading density, physical space, stocking densities

Citation: Arndt H, Volkmann N, Spindler B, Hartung J and Kemper N (2019) Do Pigs Have Adequate Space in Animal Transportation Vehicles?—Planimetric Measurement of the Floor Area Covered by Finishing Pigs in Various Body Positions. Front. Vet. Sci. 5:330. doi: 10.3389/fvets.2018.00330

Received: 02 September 2018; Accepted: 13 December 2018;
Published: 10 January 2019.

Edited by:

Mette S. Herskin, Aarhus University, Denmark

Reviewed by:

Xavier Averós, Neiker Tecnalia, Spain
Tomas Norton, KU Leuven, Belgium

Copyright © 2019 Arndt, Volkmann, Spindler, Hartung and Kemper. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Nicole Kemper, bmljb2xlLmtlbXBlckB0aWhvLWhhbm5vdmVyLmRl

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