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Comparison of three different farrowing systems: skin lesions and behaviour of sows with special regard to nursing behaviour in a group housing system for lactating sows

Published online by Cambridge University Press:  20 May 2019

T. Nicolaisen Open the ORCID record for T. Nicolaisen [Opens in a new window] ,
B. Risch ,
E. Lühken ,
C. van Meegen ,
M. Fels  and
N. Kemper
T. Nicolaisen*
Affiliation:
Institute for Animal Hygiene, Animal Welfare and Farm Animal Behaviour, University of Veterinary Medicine Hannover, Foundation, Bischofsholer Damm 15, 30173 Hannover, Germany
B. Risch
Affiliation:
Clinic for Swine, Small Ruminants and Forensic Medicine, University of Veterinary Medicine Hannover, Foundation, Bischofsholer Damm 15, 30173 Hannover, Germany
E. Lühken
Affiliation:
Institute for Animal Hygiene, Animal Welfare and Farm Animal Behaviour, University of Veterinary Medicine Hannover, Foundation, Bischofsholer Damm 15, 30173 Hannover, Germany
C. van Meegen
Affiliation:
Statistical Consulting and Analysis Center, Department of Statistics, TU Dortmund University, Vogelpothsweg 87, 44221 Dortmund, Germany
M. Fels
Affiliation:
Institute for Animal Hygiene, Animal Welfare and Farm Animal Behaviour, University of Veterinary Medicine Hannover, Foundation, Bischofsholer Damm 15, 30173 Hannover, Germany
N. Kemper
Affiliation:
Institute for Animal Hygiene, Animal Welfare and Farm Animal Behaviour, University of Veterinary Medicine Hannover, Foundation, Bischofsholer Damm 15, 30173 Hannover, Germany
*
E-mail: thies.jesper.nicolaisen@tiho-hannover.de

Abstract

While group housing (GH) is mandatory in the European Union for the greater part of pregnancy, single housing in farrowing crates (FCs) during lactation that restrict sows in most of their natural behaviour patterns is still practised on a large scale. Research is urgently needed to develop alternative farrowing systems that improve sows’ welfare. Therefore, sows in three different farrowing systems – pens with FC, loose housing (LH) pens and GH for six sows – were compared regarding the level of skin injuries and their active and resting behaviour. A skin injury score was assessed for 15 body parts of 102 sows in six batches on 3 days (days 1, 14 and 34). In total, the active and resting behaviour of 77 sows in six batches was examined on 3 days (days 18, 25 and 32) between 0700 h and 1900 h by means of a scan sampling method. The suckling behaviour and the level of cross-suckling were analysed in GH by means of direct observation in four batches during three 4-h sampling periods (days 17, 24 and 31). No significant differences were found in total skin injuries when the sows entered the systems (day 1), but GH sows showed significantly higher total skin injuries compared to FC and LH sows in the middle (day 14) and at the end (day 34) of the lactation period. A significant difference between FC and LH sows was never seen. Differences were found for the proportion of different body postures between the three systems. The odds for lying in lateral recumbency versus standing and sitting versus standing were significantly higher for FC and LH sows compared to GH sows. Additionally, sows were significantly more likely to be standing as opposed to lying in lateral recumbency as the lactation period progressed. Cross-suckling was a frequent behaviour in GH, seen in 35.0% of all successful suckling bouts. However, only an average of 0.56 piglets per successful suckling bout was observed cross-suckling, suggesting only a few piglets were engaged in cross-suckling. In conclusion, the skin injury score was only moderately increased in GH compared to FC and LH and comparable to pregnant group-housed sows, both free farrowing systems seemed to be an environmental enrichment for lactating sows and good management cannot prevent the occurrence of cross-suckling in a GH system, but can probably reduce it.

Keywords

pigskin injuriescross-sucklingloose housinggroup housing
Type
Research Article
Information
animal , Volume 13 , Issue 11 , November 2019 , pp. 2612 - 2620
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits noncommercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
Copyright
© The Animal Consortium 2019

Implications

Free farrowing seems to be a proper instrument to enrich sows’ environment and, therefore, possibly contribute to welfare for lactating sows. Group housing could be a practical alternative to individual housing of lactating sows, if a proper pen design prevents conflicts over resources and enables a stable hierarchy. Furthermore, good management is able to reduce the extent of cross-suckling in a group housing system.

Introduction

While group housing (GH) is legally required for pregnant sows in the European Union during the period between four weeks after insemination and one week before farrowing (Council Directive 2008/120/EC), the individual housing of lactating sows in farrowing crates (FCs) throughout the entire lactation period is still permitted and, moreover, it is the dominating farrowing system in many countries. This common practice has led to animal welfare concerns because the FC restricts the sow in a couple of natural behavioural patterns, e.g., in movement, defaecation behaviour, thermoregulation or nest-building behaviour (Baxter et al., Reference Baxter, Lawrence and Edwards2011). Sows in crates are also more susceptible to stereotypes such as vacuum chewing or bar biting compared to group-housed sows (Arellano et al., Reference Arellano, Pijoan, Jacobson and Algers1992; Arey and Sancha, Reference Arey and Sancha1996). The main reason for the widely used restriction of lactating sows is the assumption of higher piglet mortality due to crushing in systems without confinement of the sows. However, a number of studies exist in which no difference in piglet mortality was found between pens with FCs and free farrowing pens (Weber et al., Reference Weber, Keil, Fehr and Horat2007; Pedersen et al., Reference Pedersen, Berg, Jørgensen and Andersen2011). These studies illustrate that it is possible to find ways to improve the welfare of lactating sows without impairing the welfare of suckling piglets.

Different types of alternative farrowing systems have been investigated in numerous studies (Baxter et al., Reference Baxter, Lawrence and Edwards2012), but GH best reflects the observed natural behaviour of domestic pigs kept under semi-natural conditions (Jensen, Reference Jensen1986), if the specific needs of the sows in this period (e.g., increased urge to move, separation close to farrowing, performing of nest-building behaviour and reintegration into the herd after farrowing) are taken into consideration.

Nonetheless, new challenges for animal welfare can arise when lactating sows are kept in groups. For example, aggressive conflicts among the sows can occur due to enabled social interaction, or the appearance of cross-suckling can have detrimental consequences for the piglets (Pedersen et al., Reference Pedersen, Studnitz, Jensen and Giersing1998). On the other hand, there is evidence that piglets cope better with challenges at weaning (e.g., mixing), when pre-weaning socialisation with other litters occurred (Weary et al., Reference Weary, Pajor, Bonenfant, Ross, Fraser and Kramer1999).

In this study, two prototypes of free farrowing systems – a single loose housing (LH) pen and a GH system for six lactating sows (both developed by Big Dutchman International GmbH, Vechta, Germany) – were compared with conventional pens with a FC. In order to assess the system’s influence on the sows’ and piglets’ behaviour and welfare, skin injuries and the active and resting behaviour of sows, as well as the occurrence of cross-suckling were evaluated.

Material and methods

Animals and housing conditions

All experiments were conducted on the experimental farm for pig breeding and pig husbandry of the Chamber of Agriculture for Lower Saxony in Wehnen, Germany, between July 2016 and August 2017.

Three different farrowing systems were tested: a conventional pen with FC, a single LH pen, and a GH system for six lactating sows. The sows were a crossbreed between Landrace and Large White (genetics: BHZP, db. Viktoria).

All farrowing systems were located in the same building. Two compartments existed for each farrowing system. While GH and LH compartments included six pens each, there were eight pens in the FC compartments.

The FC pens (Figure 1a) were 260 cm long and 200 cm wide, had a fully slatted plastic floor and an open creep area (160 cm × 50 cm), which was heated by an infrared light. The crate itself was 190 cm long and 80 cm wide. Tiles were recessed in the floor of the sow’s lying area (120 cm × 110 cm) to ensure thermal conduction.

Figure 1 (a) Conventional pen with farrowing crate (FC); (b) Single loose housing (LH) pen; (c) Group-housing system for lactating sows (GH). CoA = common area. © Big Dutchman; CrA = creep area; Sw = swing gate.

In total, the LH pens (Figure 1b) were 270 cm long and 270 cm wide. A swing gate divided the pen and reduced the space that was actually accessible for the sow. The creep area (100 cm × 80 cm) was located in the part of the pen that was not accessible for the sow. It was a closed creep area with one big opening on the front side and a small gate on a lateral side, and it was heated by an infrared radiation element (CE-REXTM IRX-300; Rexlan Europe, Sorø, Denmark). The floor of the LH pen was similar to that in the FC pens.

The GH (Figure 1c) consisted of two opposite rows of three pens each and a central common area. Each pen measured 202 cm × 245 cm, with a lockable large opening on the front side that granted access to a common area (size 610 cm × 235 cm). An approximately 20-cm-high roll at the bottom of the opening prevented the passing of piglets. An additional small opening on the front side of each pen granted access for the piglets to the common area. The floor of the pens was divided into a part with a fully slatted concrete floor (in the rear part of the pen, 120 cm × 202 cm) and a part with a fully slatted cast-iron floor (in the front of the pen, 125 cm × 202 cm). The creep areas were similar to those in the LH pen. One part of the common area was only accessible for piglets (about 100 cm × 235 cm). The floor in the common area was a fully slatted concrete floor. Sows were tagged with an electronic ear tag and were only able to receive feed from an electronically controlled feeder in their own pen. Nipple drinkers were located in the pens and in the common area for both sows and piglets.

The sows in the LH pens and in the GH were not fixated at any point in time during the lactation period. Anti-crushing bars were installed in the pens of both systems and in the common area of the GH system.

All sows were fed with a standard diet for lactating sows (14.7 MJ ME/kg, 16.0% crude protein). Farrowing crate and LH sows were fed twice a day, whereas GH sows were fed by an automatic feeder and were able to receive a certain percentage of their daily ration on three (until 10 days p.p.) and four (from day 11 p.p. until weaning) feeding periods (between 0800 h and 2000 h) per day, respectively. On the first day p.p., sows received 3.0 kg feed per day, this amount increased to 7.0 kg on day 9 p.p. and to 8.5 kg on day 15 p.p. This was the maximal amount for FC and LH sows, whereas GH sows received up to 9.0 kg feed from day 17 p.p. until weaning. A commercial creep feed was offered to the suckling piglets from the tenth day of life.

Manipulable material was offered to sows and piglets for the entire lactation period (gunny sacks around birth, cotton ropes for sows and piglets and straw racks in LH and GH pens).

Farrowing, cross-fostering and piglet treatment

The sows entered the pens on day 1, one week before the expected farrowing date (day 7). Weaning took place after a lactation period of four weeks (day 34). Although there was no special treatment for the FC and LH sows, the GH sows were separated in the pens for the first 24 h after move in. Afterwards, the pens were opened for 48 h to enable socialisation among the six sows. Subsequently, the sows were penned in again to ensure that farrowing occurred in the pens (day 5). Re-opening of the GH took place for sows and piglets when the last born litter was at least five days old (day 13 in five batches and day 14 in one batch), and it stayed open for the remainder of the lactation period. Sows could move freely through the whole GH system (all pens and common area) when the pens were open. Due to the fact that sows were kept in small groups of four to five during pregnancy and distributed randomly to the farrowing systems, not all GH sows were unacquainted to each other.

At the beginning of the experiment, all multiparous sows had farrowed in FCs in previous lactations. All sows were allocated randomly to the farrowing systems, i.e., provided that a sow participated in the experiment for a second time, the sow was randomly assigned to one of the three farrowing systems again.

If cross-fostering was necessary, it was performed within 48 h after birth and only within the same farrowing system. Teeth clipping and ear tagging were performed on day 1 p.p., castration of male piglets on day 4 p.p. Tail docking was done under veterinary advisement on day 4 p.p.

Video recording

In total, 26 cameras (EverFocus ez.HD; Everfocus, Taiwan) and two video recorders (EverFocus ECOR FHD 16 × 1; Everfocus, Taiwan) were used to monitor and to record the sows’ behaviour continuously. Eight cameras were installed in each of the two GHs (one for each pen and two for the common area). Three of the six pens were video recorded in the LH compartments (one camera per pen) and four of the eight FC pens were monitored in each compartment (one camera for two pens).

Skin injuries

One hundred two sows (36 GH sows, 32 LH sows, 34 FC sows; mean parities and SEM: GH = 2.19 (±0.21), LH = 3.00 (±0.41), FC = 2.97 (±0.44)) were examined for the level of skin injuries in six batches. All sows of the three tested farrowing systems were examined at three points in time per batch. The first scoring took place on the day the sows entered the farrowing pens (day 1), the second occurred 24 h after re-opening the pens in the GH (day 14 in five batches and day 15 in one batch) and the last scoring was conducted at weaning (day 34). The modified skin injury score was used based on the studies by Parratt et al. (Reference Parratt, Chapman, Turner, Jones, Mendl and Miller2006) and Schrey et al. (2018), which ranged from 0 to 3 and is explained in Table 1. Fifteen parts of the body were inspected and scored: Head, ear, neck/shoulder, forelimb, flank, ham, hind limb on both body sides and the dorsal line. The skin injury score was assessed by one trained person.

Table 1 Skin injury scoring system for sows (modified from Parratt et al., Reference Parratt, Chapman, Turner, Jones, Mendl and Miller2006 and Schrey et al., 2018)

Superficial scratch: Injury of upper dermal layers, slight reddening, possibly minimum bleeding or scab.

Deep scratch: Injury of deeper dermal layers with reddening/bleeding/scab, necrotic or purulent processes possible.

No discrimination was made between new and healing scratches. Scars and shoulder ulcers were not regarded.

Active and resting behaviour

The active and resting behaviour of sows were analysed via video observations. Data were collected for 77 sows (36 GH sows, 18 LH sows, 23 FC sows; mean parities and standard error of mean (SEM): GH = 2.19 (±0.21), LH = 3.00 (±0.52), FC = 3.04 (±0.57)) in six batches and assessed on three sampling days (day 18, 25 and 32) per batch between 0700 h and 1900 h. A scan sampling method with 10-min-intervals over the 12 h was chosen to analyse body postures of each sow (standing, sitting, sternal recumbency or lateral recumbency).

The mean temperatures of all video observation periods were 23.45°C for FC, 22.41°C for LH and 23.96°C for GH.

Space utilisation in the group housing system

Space utilisation in the GH was assessed in a sub-sampling that included four batches. The location of each GH sow (pen or common area) was determined on four sampling days (days 3, 18, 25 and 32) per batch between 0700 h and 1900 h. A scan sampling method with 10-min-intervals was chosen.

Suckling behaviour and cross-suckling

The occurrence and the level of cross-suckling were assessed by direct observations in the GH in four batches (n = 24 sows, mean parity and SEM: 2.3 (±0.26)). Three 4-h sampling periods (from 1200 h to 1600 h) took place per batch on days 17, 24 and 31. At the beginning of the measurements on day 17, litter size per sow was 13.1 (SEM ±0.25).

Different colours of animal marking spray were used to differentiate the six litters. Marking of piglets was finished 1 h before the observation period started. The following parameters were assessed: number of cross-suckling piglets, nursing synchronisation, location (pen or common area) and success/failure of each suckling bout. The number of cross-suckling piglets was assessed in the phase of milk ejection, which is characterised by quick and rhythmical sucking on the sows’ teats (Fraser, Reference Fraser1980). The end of milk ejection was determined when piglets began to switch between teats or restarted udder massage (Maletínská and Špinka, Reference Maletínská and Špinka2001). The first sow which started a suckling bout became the focus animal. Every sow which started nursing within 4 minu after the focus animal began was regarded as being “synchronised” with it. The start of a suckling bout was determined by the following definition: a sow was lying in lateral recumbency and started characteristic grunting to attract her piglets (Maletínská and Špinka, Reference Maletínská and Špinka2001). A suckling bout was classified as being “successful” when the piglets could finish the phase of milk ejection on the udder.

Statistical analysis

The statistical analysis was carried out using SAS® Enterprise Guide software (SAS® EG, Version 7.1, Copyright © 2014; SAS Institute Inc., Cary, NC, USA) as well as the statistical open source software R (Version 3.4.4) with the packages Ime4, ImerTest and mclogit (Bates et al., Reference Bates, Maechler, Bolker and Walker2015; Elff, Reference Elff2017; Kuznetsova et al., Reference Elff2017; R Core Team, 2018).

Concerning skin injuries, a “cumulative rating index” (CRI) was generated for each sow at each time-point of examination by adding up the individual scores of the 15 body parts (CRI range: 0–45). The CRI was used for further statistical analysis. First, it was tested whether the residual of the CRIs showed a normal distribution using the Kolmogorov–Smirnov-test (SAS® EG, PROC UNIVARIATE). Subsequently, the CRI of the three tested systems were compared by one-factor analysis of variance and the Fisher`s Least Significance Test was chosen as a post-hoc-test to determine differences between the systems at 3 different examination days (SAS® EG, PROC ANOVA). Afterwards, a one sample t-test was conducted to detect differences between the three examination points within one of the three systems (SAS® EG, PROC MIXED).

Differences between the three systems concerning injuries in single body parts were identified using the Exact-Fisher-test (SAS® EG, PROC FREQ). Bonferroni alpha adjustment for multiple comparisons was conducted and the significance level was determined as P < 0.0167.

In addition, a linear model was adapted to model the impact of parity on the CRI taking account of the farrowing system and examination point as fixed effects and the individual sow as a random effect (R, ImerTest::Imer).

Regarding active and resting behaviour, a multinomial logit model with random effects (i.e., individual sow) was calculated to model the body postures in dependence of the number of gestations, farrowing system and examination point (R, mclogit::mblogit). Thereby, the odds of one body posture versus a reference category were modelled. Because standing is classified as the most strenuous body posture, it was chosen as a reference category.

A logistic mixed effect model was fitted to describe the odds of the preferred location “common area” versus “pen” dependent on the parity and the examination day (R, lme4::glmer).

Descriptive statistics were used to present the results of success of suckling, suckling frequency, location of suckling and cross-suckling.

Results

Skin injuries

An overview of the results is given in Figure 2. No significant differences of CRI were observed between the three farrowing systems on day 1 (mean values and SEM for CRI: FC = 7.50 (±0.63), LH = 7.00 (±0.67), GH = 6.86 (±0.53)), P > 0.05). Significant differences between GH and both single housing systems were found on day 14. CRI was significantly higher in GH sows than in LH sows and FC sows (mean values and SEM: FC = 3.68 (±0.45), LH = 4.13 (±0.44), GH = 7.36 (±0.66), P < 0.05). There was no significant difference between the FC sows and the LH sows on day 14 (P > 0.05). Significantly higher CRIs were found in GH compared with both single housing systems on day 34 (P < 0.05), but no difference existed between the CRIs of the two single housing systems (mean values and SEM: FC = 2.50 (±0.41), LH = 2.97 (±0.48), GH = 5.92 (±0.41), P > 0.05).

Figure 2 Mean cumulative rating score (CRI) and standard error of the mean in the three systems (pens with farrowing crate = FC (n = 34 sows), single loose housing pens = LH (n = 32 sows), group housing system = GH (n = 36 sows)) on different examination days. Different letters within one examination point mark significant differences (P<0.05). Significant differences within one farrowing system between examination points are marked by * (P<0.05) or *** (P<0.001).

A significant decline in CRI was found in FC between day 1 and day 14 (P < 0.001), but not between day 14 and day 34 (P > 0.05). On the other hand, the CRI of the LH decreased both between day 1 and day 14 (P < 0.001) and day 14 and day 34 (P < 0.05). No significant difference was detected in GH between day 1 and day 14 (P > 0.05), but CRI was significantly lower on day 34 compared to day 14 (P < 0.05).

An overview of skin injury scores of single body parts at different examination days is given in Supplementary Figures S1, S2 and S3. A difference in the skin injury scores of single body parts was not detected between FC sows and LH sows (P > 0.0167). The body parts “neck/shoulder” (P < 0.001), “forelimb” (P < 0.01) and “flank” (P < 0.0167) of GH sows were significantly more severely injured than those of FC sows on day 14. At weaning, the body parts “neck/shoulder” (P < 0.001), “forelimb” (P < 0.01), “flank” (P < 0.01) and “ham” (P < 0.01) of GH sows showed significantly more severe lesions compared to FC sows. GH sows had significantly more severe forelimb lesions than LH sows at all examination points (days 1, 14 and 34: P < 0.0167). Additionally, significantly higher injury scores were detected in GH sows compared to LH sows in the following body parts on the two latter examination points: “Head” (day 14: P < 0.001; day 34: P < 0.0167) and “neck/shoulder” (days 14 and 34: P < 0.001).

The results of the estimated linear mixed model (Supplementary Table S1) showed a significant effect of the parity on the injury score. If the number of gestation increased by 1, the CRI increases by 0.258 (P = 0.0125).

Active and resting behaviour

A complete overview of percentages for single body postures on different examination days is given in Table 2 and an overview of the results for the multinomial logit model is given in Supplementary Table S2.

Table 2 Mean percentage of sows’ body postures on different examination days

Farrowing system: FC = pen with farrowing crate; LH = loose housing pen; GH = group housing system.

Body posture: LR = lateral recumbency; SR = sternal recumbency; TL = total lying; Si = sitting; St = standing.

It could be shown that FC and LH sows had significantly higher odds of lateral recumbency versus standing than GH sows. The odd for lateral recumbency versus standing of an FC or LH sow increased by a factor of 1.87 and 1.82 (P < 0.001 each), respectively, compared to the odd of a GH sow. According to this, it was more probable that an FC or LH sow was lying in lateral recumbency than standing compared to GH sows. Additionally, the examination day showed a significant negative influence on the odds of lateral recumbency versus standing. Therefore, on examination day 25, it was much more likely that the sows preferred to stand than to lie in lateral recumbency compared to day 18 (odds 0.743, P < 0.001). For day 32, it was even more extreme compared to day 18 (odds 0.617, P < 0.001).

Neither the farrowing system nor the examination day showed a significant influence on the odds of sternal recumbency versus standing.

The farrowing system had a significant impact on the odds of sitting versus standing. The odds of sitting versus standing when changing the farrowing system from GH to FC or LH increased by a factor of 2.59 (P < 0.001) and 1.69 (P = 0.034), respectively. Thus, FC and LH sows sat significantly more than standing compared to GH sows although it could not be shown that the examination point had an effect on the probability of sitting.

A significant impact of the parity was not found for any of the compared body postures.

Space utilisation in the group housing system

The pens were the preferred location of the sows on day 3 (pens: 69.2%, common area: 30.8%). The utilisation of pens and the common area was nearly equal on day 18 (pens: 50.2%, common area: 49.8%) and shifted towards the common area on day 25 (pens: 48.0%, common area: 52.0%). The difference increased close to weaning on day 32 (pens: 42.7%, common area: 57.3%).

The results of the estimated logistic mixed effect model for the preferred location are shown in Supplementary Table S3. The odds of preferred location “common area” versus “pen” increased by a factor of 2.552 (P < 0.001) from day 1 to 18, by a factor of 2.818 (P < 0.001) from day 1 to 25, and by a factor of 3.648 (P < 0.001) from day 1 to 32. Thus, the sows increasingly preferred the common area while the time of examination progressed.

No significant impact of the parity on the probability of a sow staying in the common area could be detected.

Suckling behaviour and cross-suckling

In total, 393 suckling bouts were observed in four batches. The majority of the suckling bouts were successful (90.1%, n = 354), only 9.9% (n = 39) failed. Cross-suckling was observed in 35.0% (n = 124) of all successful suckling bouts. The average number of cross-suckling piglets per successful suckling bout was 0.56. In total, 68.6% of all detected cross-suckling events were caused by single piglets. The highest recorded number of cross-suckling piglets in a single cross-suckling event was five (3.2%, n = 4). In total, more suckling bouts took place in the common area (52.4%; n = 205) than in the pens (47.6%; n = 186), but large differences existed between the different weeks of lactation. In the second week of lactation, the majority of suckling bouts were kept in the pens (pens: 58.1%, n = 90; common area: 41.9%, n = 65). The number of suckling bouts in pens and in the common area shifted towards the common area in the third week of lactation (pens: 45.4%, n = 54; common area 54.6%, n = 65), and this gap became larger in the fourth week of lactation (pens: 35.9%, n = 42; common area 64.1%, n = 75). The synchronisation of suckling bouts was high. A complete overview of the level of synchronisation is given in Table 3.

Table 3 Mean number and percentage of sows’ suckling bouts in different grades of synchronisation

Discussion

Skin injuries

As expected, CRI declined in the two single housing systems over the course of time, because agonistic behaviour between sows could not occur anymore and the skin healed. No differences were found between the two single housing systems at any point in time. Although there is evidence that a crate itself can cause skin injuries (Anil et al., Reference Anil, Anil and Deen2002), no such indication was found in this study.

In contrast to FC and LH, no significant decline was found in GH between day 1 and day 14. Probably, the socialisation of the unacquainted sows prior to birth led to repeated agonistic behaviour among the sows and to new skin injuries. Weary et al. (Reference Weary, Pajor, Bonenfant, Fraser and Kramer2002) found the highest level of agonistic behaviour during the first 4 h after mixing lactating sows. It is known that unacquainted pigs start to fight immediately after grouping in order to form a social hierarchy that is established within 48 h (Meese and Ewbank, Reference Meese and Ewbank1973). It could not be determined, if the constant level of skin injuries on day 14 compared to day 1 was still consequence of this agonistic behaviour during socialisation or if the fighting continued in the 24 h between reopening and second examination, and subsequently led to a renewed increase in skin injuries. However, a significant decrease in CRI was found in GH sows on day 34 compared to day 14. A plausible explanation for this could be a stabilised social hierarchy among the six sows. Nevertheless, the CRI was still significantly higher compared to the sows in single housing systems at this stage. There is evidence that limited resources (e.g., food) can lead to high levels of aggression among sows even 28 days after mixing (Arey, Reference Arey1999). In this study, although feed is not likely to be a source of competition (i.e., it is provided close to ad libitum and in single pens), the relatively small common area could have been a valued resource and thus a source of dispute causing conflicts and consequently new skin injuries. Former research, in group housed sows during gestation, showed that levels of agonistic behaviour and skin injuries increased when space allowance per sow declined (Weng et al., Reference Weng, Edwards and English1998). Comparing injuries of day 1 and day 34 of GH yielded no significant difference, i.e., it was not possible to detect differences between the late period of group-housed pregnant sows and group-housed lactating sows 5 weeks later. Moreover, the moderate values of CRI in the GH sows throughout the entire lactation indicate a low but constant grade of agonistic behaviour among them. Further research is necessary to determine if these moderate skin injury levels are an inevitable consequence of agonistic behaviour that may be needed to maintain a stable hierarchy or whether the skin injury levels can be reduced by solving the assumed conflict over resources (e.g., space).

A significant influence of parity was detected indicating that sows with a higher number of parities were more injured compared to sows with a lower number of parities. However, this finding does not limit the interpretation of our results, because FC and LH sows on average had a slightly higher number of parities than GH sows.

The comparison of respective body parts showed that GH sows particularly had higher skin injury scores in the front part of their bodies (head, shoulder/neck and forelimb) than sows of both single housing systems. These results indicate that the higher amount of skin injuries of GH sows is the result of agonistic behaviour. This assumption is supported by Turner et al. (Reference Turner, Farnworth, White, Brotherstone, Mendl, Knap, Penny and Lawrence2006) who found a significantly positive correlation between the frequency of reciprocal fighting and the grade of a lesion score for the front part of the body. There is a limited validity of this conclusion for the level of skin injuries of the forelimb due to the fact that a difference between GH sows and LH sows already existed when the sows entered the systems. A possible explanation for the significantly higher values of skin injuries of flank and ham in GH sows compared to FC sows could be agonistic behaviour in the manner of inverse parallel pressing (Jensen, Reference Jensen1980).

Active and resting behaviour

The results suggest that sows changed their active and resting behaviour in all three farrowing systems in the course of lactation. The odds for lying in lateral recumbency versus standing decreased significantly with time. This means, it was more probable that sows of all farrowing systems preferred to stand than to lie in lateral recumbency on days 25 and 32 in comparison to day 18. This phenomenon was found in previous research and was explained as a “piglet voidance strategy” of the sow (Blackshaw et al., Reference Blackshaw, Blackshaw, Thomas and Newman1994; Lambertz et al., Reference Lambertz, Petig, Elkmann and Gauly2015), i.e., the sow refuses the piglets’ attempts to stimulate her udder by reducing the time spent in lateral recumbency. An explanation for the significantly higher odds for lateral recumbency versus standing and sitting versus standing in both single housing systems compared to GH could be enhanced piglet avoidance in GH sows due to an additional harassment of the sow by suckling attempts of foreign piglets. This is supported by Bohnenkamp et al. (Reference Bohnenkamp, Meyer, Müller and Krieter2013) who reported a continuous presence of foreign piglets on the sow’s udder during nursing in a GH system.

Even though no significant difference for the odds of sternal recumbency versus standing could be detected, the descriptive analysis shows that the proportion for sternal recumbency was also higher in LH compared to FC, and this indicates that additional factors could exist besides piglet avoidance.

Lateral recumbency is a state of total relaxation and inactivity, whereas sternal recumbency is a body posture in which sows are often awake, noticing and interacting with their environment (e.g., chewing on enrichment material or practising social interaction). The increased free moving space for LH and GH sows could have led to a higher level of participation in their environment compared to restricted FC sows expressed by an increased proportion of lying in sternal recumbency. However, Blackshaw et al. (Reference Blackshaw, Blackshaw, Thomas and Newman1994) and Lambertz et al. (Reference Lambertz, Petig, Elkmann and Gauly2015) found no significant differences of lying in sternal or lateral recumbency between crated sows and loose housed sows.

If the body posture “standing” is thought of as a proxy for activity in this study, the conclusion can be drawn that an unrestricted housing system (i.e., LH compared to FC) itself does not lead to a higher activity level. This is supported by Blackshaw et al. (Reference Blackshaw, Blackshaw, Thomas and Newman1994) and Lambertz et al. (Reference Lambertz, Petig, Elkmann and Gauly2015) who found no differences in standing between sows in FCs and loose housed sows. However, the GH system with its given possibilities of using different areas and interacting with five other sows could have led to an increased activity level in this study. Deviant results were found by Bohnenkamp et al. (Reference Bohnenkamp, Meyer, Müller and Krieter2013) who found no difference in the periods spent standing between group-housed sows and sows in FCs.

At the beginning of our experiment, all multiparous sows farrowed in FCs in previous gestations. Recent research showed that sow behaviour is influenced by previous farrowing experiences and that this especially becomes visible when sows enter an unknown farrowing system (King et al., Reference King, Baxter, Matheson and Edwards2019). However, no influence of parity on the active and resting behaviour was found in our study.

Space utilisation, suckling behaviour and cross-suckling

Higher levels of successful suckling bouts with milk ejection (96.7%) compared to our study (90.1%) were found in a multi-suckling system by Arey and Sancha (Reference Arey and Sancha1996). A possible reason for this difference could be a higher potential for conflict due to the smaller common area in this study. Although not systematically recorded, the authors of this study noticed many interrupted suckling bouts in the common area due to agonistic interactions between sows.

Referring to the results of the level of synchronisation, the conclusion can be drawn that the overwhelming majority of suckling bouts was synchronised with at least another sow (93.9%). There is evidence that a higher grade of synchronisation could be a successful strategy to reduce cross-suckling, thus reducing the number of piglets that do not participate in a suckling attempt at their own mother (Maletínská and Špinka, Reference Maletínská and Špinka2001).

The observed shift in the preference of space utilisation and nursing location from pens to the common area during lactation could reflect natural behaviour patterns of sows after birth. Former research showed that sows separate from their herd prior to farrowing under semi-natural conditions (Jensen, Reference Jensen1986) and that the reintegration of sows and their piglets into a herd was seen as a gradual process under semi-natural conditions that started by abandoning the farrowing nest on a mean piglet age of 10 days (Jensen and Redbo, Reference Jensen and Redbo1987). A further explanation could be that the assumed lack of space in the common area (see Discussion section about skin injuries) and an instable hierarchy in the first stage of lactation resulted in a higher potential for conflict and subsequently forced the sows to avoid the common area. Cross-suckling was a frequently observed behaviour in this study. However, the small average number of cross-suckling piglets and the fact that 68.6% of cross-suckling events were caused by single piglets are signs for the moderate extent of this behaviour. Although piglets were not marked individually, the conclusion can be drawn that only a low number of piglets was engaged in cross-suckling. A comparable level of cross-suckling to the present study was found by Schrey et al. (2018) who observed an average number of 0.8 foreign piglets on the udder during suckling bouts. Bohnenkamp et al. (Reference Bohnenkamp, Meyer, Müller and Krieter2013) found an average value of 0.3 to 0.4 foreign piglets on the udder during suckling. Despite the fact that the study by Bohnenkamp et al. (Reference Bohnenkamp, Meyer, Müller and Krieter2013) was not cross-suckling orientated, the results do indicate a lower occurrence of this phenomenon compared to our study. A high incidence of cross-suckling was found in groups of three to four lactating sows by Maletínská and Špinka (Reference Maletínská and Špinka2001): About 29% of all suckling was cross-suckling, with more than one-third of all piglets performing cross-suckling at least once.

Factors that are discussed to influence the extent of cross-suckling are milk yield of the sow, sow parity, litter size, litter age at co-mingling and farrowing conditions (van Nieuwamerongen et al., Reference van Nieuwamerongen, Bolhuis, van der Peet-Schwering and Soede2014). In this study, the litter equalisation took place within 48 h after birth. Thus, only small differences in litter size existed and this possibly prevented a higher level of cross-suckling. In this study, co-mingling occurred at a mean litter age of 7.2 days. The tight bonds between sows and their offspring develop within the first week of life (Horrell and Hodgson, Reference Horrell and Hodgson1992). Hence, it can be assumed that co-mingling management prevented a higher incidence of cross-suckling in our experiment. In this study, piglets were born in a structured multi-suckling system and spent the first days of life in a separate pen with their mothers, before they were socialised with other sows and their litters. The low levels of cross-suckling are in accordance with the results of Wattanakul et al. (Reference Wattanakul, Edwards, Stewart and English1998), who ascertained that structural complexity of a multi-suckling system and adaption to the housing environment prior to co-mingling impeded cross-suckling.

Conclusion

The examination of the active and resting behaviour showed that an unrestricted housing system itself seemed to be an environmental enrichment for lactating sows and that this positive effect was even enhanced in a structured group-housing system. Furthermore, the found skin lesions in GH were moderate and comparable to those of group-housed gestating sows living in a stable hierarchy. Thus, no negative influence of GH on sows’ welfare was detected during lactation. Cross-suckling seemed to be inevitable in a group-housing system for lactating sows, but an adequate management is able to reduce the extent of this behaviour.

Acknowledgements

The project was supported within the “Inno-Pig” project by funds of the German Government`s Special Purpose Fund held at Landwirtschaftliche Rentenbank.

Thies Nicolaisen 0000-0001-9116-2491

Declaration of interest

No conflict of interests.

Ethics statement

The authors declare that the experiment was in accordance with current German law. This study was reviewed and received approval from the animal welfare officer of the University of Veterinary Medicine, Hannover, Foundation.

Software and data repository resources

None of the data were deposited in an official repository.

Supplementary material

To view the supplementary material for this article, please visit https://doi.org/10.1017/S1751731119000661

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Figure 0

Figure 1 (a) Conventional pen with farrowing crate (FC); (b) Single loose housing (LH) pen; (c) Group-housing system for lactating sows (GH). CoA = common area. © Big Dutchman; CrA = creep area; Sw = swing gate.

Figure 1

Table 1 Skin injury scoring system for sows (modified from Parratt et al., 2006 and Schrey et al., 2018)

Figure 2

Figure 2 Mean cumulative rating score (CRI) and standard error of the mean in the three systems (pens with farrowing crate = FC (n = 34 sows), single loose housing pens = LH (n = 32 sows), group housing system = GH (n = 36 sows)) on different examination days. Different letters within one examination point mark significant differences (P<0.05). Significant differences within one farrowing system between examination points are marked by * (P<0.05) or *** (P<0.001).

Figure 3

Table 2 Mean percentage of sows’ body postures on different examination days

Figure 4

Table 3 Mean number and percentage of sows’ suckling bouts in different grades of synchronisation

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