INTRODUCTION
In modern pig production, low weaning weight pigs present a chronic problem due to the use of hyperprolific sows [
1]. Low weight pigs at weaning have immature digestive systems, are slower growers, tend to have higher mortality, and poorer carcass value than their heavier counterparts [
2,
3]. There is limited literature on rearing strategies for low weight pigs both pre- and post-weaning [
4,
5]. Extended suckling has the potential to improve gut maturity at weaning [
6], but research on using nurse sows has mainly focused on sow and piglet welfare [
7,
8] rather than on piglet performance. Increased amounts of starter diets have been found to improve the performance of low weaning weight pigs [
9–
11]. The present study is the first, known to the authors, investigating the effect of different management systems on life-time performance of low WW pigs (<6 kg at 28 d). Therefore, the objective of the study was to evaluate the implementation of nurse sows and different starter diet allowances post-weaning and their impact on the growth of disadvantaged pigs.
MATERIALS AND METHODS
The trial was conducted at Agri-Food and Biosciences Institute (AFBI), Hillsborough, Northern Ireland. All experimental procedures were conducted under an experimental licence (no. 2751) granted by the Department of Health, Social Services and Public Safety for Northern Ireland in accordance with the Animals (Scientific Procedures) Act 1986. A total of 270 piglets (PIC 337×[Large White×Landrace]) from 24 sows were selected at 28 d of age (end of lactation).
Animals and housing
At d 109 of gestation, sows were moved to a climate controlled (21.0°C) farrowing room and allocated to individual farrowing crates (0.5×2.2 m), each one placed at the centre of a farrowing pen (2.3×1.5 m). Sows had access to a wet and dry feeder and were fed a commercial lactation diet (13.5 MJ digestible energy (DE)/kg, 94.4% dry matter, 17% crude protein (CP), 3.6% crude fibre (CF), and 1% total Lys). On the farrowing day, sows were offered 2.5 kg of the lactation diet, and the amount offered increased by 0.5 kg daily until 10 kg/d was reached. The target average feed intake over 28 d lactation was 8 kg/d. Attached to the front of each pen, there was a shelter box (1.5×0.6 m) for piglets equipped with a heated floor pad (heated forward creep area). Temperature in the farrowing rooms and creep areas was electronically controlled. Within 12 hours of birth all piglets had their teeth clipped, tails docked and received 2 mL of an iron supplement (Uniferon; Virbac Ltd., Suffolk, UK). Piglets were also tagged to allow recording of individual animals. No creep feed was offered to the piglets, and sow troughs were 45 cm high preventing piglets from easy access to sow feed. At d 28 piglets were vaccinated for M. Hyo and PCV2 with Ingelvac MycoFLEX and Ingelvac CircoFLEX (Boehringer Ingelheim Ld., Bracknell, UK), respectively. Cross-fostering of piglets between litters was performed within the first 24 h after birth to ensure even litter sizes (av. 12.5 piglets/sow). Piglets were weaned at 28±2 d of age.
At weaning, pigs were transferred to nursery accommodation (stage 1 and stage 2 combined) with plastic slatted floors (0.38 m2/pig). Temperature was 28°C on day one and was reduced by 0.5°C/d to a minimum of 18°C. Pigs were offered feed via a small circular hopper (Rotecna S.A, Agramunt, Spain) for the first week post weaning. Thereafter, pigs were offered feed in a ‘dry multi-space feeder’ (Etra Feeders Ltd., Dungannon, UK) with a feeder space allowance of 6.6 cm/pig. At 70 d of age, pigs were transferred to finishing accommodation with fully slatted concrete floors (0.61 m2/pig). In the finishing accommodation pigs were offered feed and water via a ‘wet and dry’ single space shelf feeder (Etra Feeders Ltd., UK) and 1 bowl drinker. One feeder was placed per pen (10 pigs/pen).
Treatments and dietary regime
A total of 180 low weight pigs (5.12±0.780 kg) and 90 normal weight pigs (NORM, 8.92±0.415 kg) were used in the experiment. The trial was carried out over nine time periods or production batches. In each batch, 30 piglets were selected at weaning and allocated to one of the five treatments. Low weight and NORM pigs were distributed to treatments balancing for gender and parity of origin. Low weight pigs were either weaned (WEAN, n = 90) and offered a special dietary regime recommended for low wean weight pigs (1 kg/pig of special starter diet [18.0 MJ DE/kg, 20.8% CP, 13.5% oils and fats, 2.0% CF, and 1.8% total Lys; Devenish Nutrition Ltd., Belfast, UK], 4 kg/pig of starter 1 diet [6.5 MJ DE/kg, 22.5% CP, 8.5% oils and fats, 2.5% CF, and 1.7% total Lys; Devenish Nutrition Ltd., UK] and 8 kg/pig of Starter 2 diet [16.0 MJ DE/kg, 22.0% CP, 8.3% oils and fats, 3.5% CF, and 1.6% total Lys; Devenish Nutrition Ltd., UK]) or placed on a nurse sow (NURSE, n = 90) and weaned at 49 d of age (weaned with the following production batch). No creep feed was offered during the extended suckling period to avoid further confounding of treatment. At weaning, NURSE pigs were offered either ‘high’ (4 kg/pig of starter 1 diet followed by 8 kg/pig of starter 2 diet; NURSE ‘high’, n = 45) or ‘low’ (8 kg/pig of starter 2 diet; NURSE ‘low’, n = 45) starter diet allowances. NORM pigs were weaned at 28 d of age and offered either ‘high’ (n = 45) or ‘low’ (n = 45) starter diet allowances as described above. Sows with a body condition score of at least 2.5 (on a 5-point scale where: 1 = very thin to 5 = overfat) and an average feed intake of 7.5 kg/d over a 28 d lactation, and with a litter size of at least 10 piglets at weaning were selected as nurse sows. Any sow that nursed experimental pigs during the conventional lactation was discarded as a nurse sow.
After pigs had consumed their respective starter allowances (average time: WEAN 4 wk, NORM ‘high’ 3.5 wk, NORM ‘low’ and NURSE ‘high’ 3 wk, NURSE ‘low’ 2.5 wk), they were offered ad libitum access to grower diets (13.9 MJ DE/kg, 18.8% CP, 4.2% oils and fats, 2.6% CF, and 1.2% total Lys) until they reached 84 d of age. Pigs were then offered a finishing diet (13.4 MJ DE/kg, 17.1% CP, 3.3% oils and fats, 3.6% CF, and 1.0% total Lys) until the end of the trial (147 d of age). On transfer to the finishing house, NURSE ‘low’ and ‘high’ groups were combined into one pen of 10 pigs and the NORM ‘low’ and ‘high’ groups were also combined into one pen of 10 pigs due to housing limitations. Due to the extended lactation, NURSE pigs (both ‘high’ and ‘low’) were 21 d older than their counterparts when transferred to the finishing accommodation and offered the finishing diet (105 d of age instead of 84 d).
Measurements
Pigs were individually weighed and pen feed intakes recorded at weaning (28 d), 49, 70, 84, 105, 126, and 147 d of age (irrespective of the treatment). Average daily gain (ADG) was calculated on an individual basis, while average daily feed intake (ADFI) was calculated on a pen basis as: feed consumed divided by the number of pigs per pen. Food conversion ratio (FCR) was also calculated on a pen basis as: food consumed per pen divided by the weight gained within the pen. Mortality was calculated as the percentage of pigs that died or were euthanized in each pen. Blood samples were taken from the jugular vein of a subset of pigs (n = 10/treatment over two time periods) at 1 day pre-weaning (NURSE pigs were 48 d old, and WEAN and NORM were 27 d old, respectively), and again at 14 and 28 d post-weaning (NURSE pigs were 63 d and 77 d old and WEAN and NORM pigs were 42 d and 56 d old, respectively). Serum was extracted by centrifugation (1509.3G force for 15 minutes at 18°C) and frozen (−20°C) until analysis was performed. Analysis was carried out using a commercially available ELIZA Quantitation Set (Cat. No. E100-104, Bethly Laboratories Inc., Montgomery, TX, USA) to test for immunoglobulin G (Ig G) concentration in porcine serum.
Statistical analysis
Individual pig performance data (body weight, ADG, feed intake, FCR, and mortality) was analysed using the linear mixed model methodology (with pen as the statistical unit) with time period fitted as a random effect using the model: Y = μ+sow+diet+sow×diet+e (sow = NORM, NURSE; diet = high, low). A post-hoc t-test was used to assess the effect of NURSE vs WEAN. Production batch was introduced as fixed effect. Data recorded during the finishing period (feed intake and FCR) was analysed on a pen basis using a one-way analysis of variance with three treatments: WEAN, NURSE, and NORM. No covariates were applied. Serum IgG concentrations were analysed using a general linear model with Treatment introduced as a main effect, and production batch introduced as a fixed effect. IgG concentration at 1 d pre-weaning was introduced as a co-variate in the models for IgG concentration at 14 and 28 d post-weaning. All analyses were carried out using Genstat 16th Edition (Lawes Agriculutral Trust, Rothamsted Experimental Station). Pig growth for each treatment was plotted with a simple linear regression with groups using the model y(wt) = ax+b to predict days to a standard weight of 100 kg.
DISCUSSION
On commercial farms pigs are being weaned as light as 3 kg at 28 d and a wean weight of 7.5 kg is a common average wean weight at 28 d of age [
12]. To better investigate the performance of disadvantaged pigs (5.12±0.780 kg of body weight) through to the end of the finishing period (147 d of age), NORM pigs (8.9±0.41 kg) were included in the study to set a standard against which any improvements could be compared.
At weaning, the resultant weight of pigs on the WEAN treatment was higher than those on the NURSE ‘low’ treatment. Initially, low weight pig treatments (WEAN, NURSE ‘high’ and ‘low’) were analysed separately from the NORM treatments and weaning weight was introduced as covariate in the models to correct for the initial difference. The growth pattern and treatment differences observed were the same as with the inclusion of NORM pigs in the analysis. Therefore, although the initial difference in weaning weight has been considered in the discussion, it was not considered to invalidate the interpretation of the statistic outcome. It is also recognised that combining both NURSE treatments into one pen, and both NORM treatments into one pen at the start of the finishing period, may have potential for bias in terms of feed intake and FCR. Therefore, the effect of ‘high’ and ‘low’ starter diet on the finishing period have not been discussed. Nonetheless, the results are considered relevant to the scientific and commercial audience and the work has been completed to ensure treatments were properly compared.
Impact on growth performance
At 70 d of age, pigs on the WEAN treatment had a 12.7% weight advantage compared to NURSE pigs (23.9 vs 21.0 kg). However, NURSE pigs were still suckling during the first half of this period, with no access to creep feed, while WEAN pigs were being offered solid diets (more nutrient dense than milk). Therefore, it would be recommended to offer creep feed to piglets suckling nurse sows to enhance their feed intake post-weaning and subsequent growth [
9,
11].
In the WEAN treatment, pig ADG was reduced by 164 g/d between 84 to 105 d of age which coincided with the change from grower to finisher diet. This suggests that these pigs, weighing 34 kg on average, were not ready for the finisher diet. Previous research [
13] also found that a similar finisher diet (18.6 MJ gross energy, 0.8 g/kg available lysine) was inadequate for pigs less than 40 kg. However, in treatments NORM (45 kg) and NURSE (40 kg) ADG was also reduced by 72 g/d and 102 g/d in the 21 d period after the finisher diet was introduced. This suggests that even pigs of 40 kg where not ready for the finisher diet. It has been suggested previously that it is economically viable to offer a grower diet up to 60 kg of live weight to optimise performance [
14]. Indeed evidence from this trial suggests that introducing the finisher diet based on live weight (perhaps up to 60 kg) would be more beneficial than based on age.
As expected, the live weight of the NORM pigs was greater than the low weight pig treatments throughout the growing and finishing periods. Weaning weight plays a critical role in growth [
15] and has been suggested as a better predictor of future growth than birth weight [
16].
Feed conversion ratio and feed intake
The NURSE piglets had improved FCR compared to both the NORM and WEAN pigs throughout their post-weaning life. This may be explained by the fact NURSE pigs had lower intake (average of 1.6 kg/d) from 70 to 147 d of age compared to WEAN and NORM groups (overall av. of 1.9 kg/d). NURSE pigs were offered higher specification diets for their age due to older weaning age. It is known that diets with higher nutrient densities improve FCR [
17]. When NORM and NURSE treatments were both offered the finisher diet at the same time (from 105 to 147 d of age), FCR did not differ statistically. It is also possible that the extended suckling period may have improved gut function [
6] and contributed to the reduced post-weaning growth check.
In other studies, offering a high allowance of starter diet improved pig growth, especially for low wean weight pigs [
10,
11,
18]. However, in contrast to these studies there was no increase in feed intake to compensate for low nutrient specification in the low allowance in this study. It could be because the difference between high and low allocations were more severe and therefore less palatable for piglets offered the Starter 2 diet immediately post-weaning. The rationale behind this design was that the older piglets coming off a nurse sow at 49 d may have been able to tolerate the lower specification Starter 2 diet. Indeed, the difference in performance between the high and low treatments in NURSE pigs was less, although not significant, than the high and low treatments for NORM pigs both at 70 d (2.4 kg vs 4.4 kg) and 147 d weeks (4.6 kg vs 9.2 kg); therefore if NORM weight pigs had been NURSE treated their growth and efficiency could be hypothesised to be greater. It has been noted historically that suckling pigs of normal weight, when offered an
ad libitum milk diet can reach ADG of over 0.5 kg/d [
19]. With modern genetics, NORM pigs should have even greater growth potential than has been realised, but their growth quickly outstrips the sow’s milk yield.
Mortality and serum IgG concentrations
NURSE treatments had greater mortality in the nursery period (up to 70 d of age) than in the finishing period. However, for WEAN and NORM ‘high’ treatments there was very little mortality in the nursery, while over 7.5% of pigs died in the finishing house. Poor thrift was the main cause of death, although all pigs were vaccinated for PCV 2. The pattern of mortality had an impact on economics. Economically, the NORM treatments had the highest margin over feed cost. This is expected as 8.9 kg pigs at 28 d are likely to achieve better 147 d weights and be more efficient than small pigs [
15]. Despite the added cost of feeding a sow for 21 d, feed costs for NURSE treatment was lower than for WEAN pigs (per 10 pigs). WEAN pigs had higher mortality later in the finishing house, which likely contributed to their lower economic value as the expensive starter diets had been eaten by pigs who did not reach slaughter. Calculating the age at which the treatments would reach a target of 100 kg live weight from their individual treatment growth curves, NURSE High would have finished 3 d before WEAN pigs, but 14 d quicker than NURSE low. In comparison, NORM high and low pigs would have finished 29 and 12 d before NURSE high. Therefore, from an economic perspective and also from a pig throughput perspective, light weaning weight pigs allowed to suckle a sow for a further 21 d, and then offered a High allocation of starter diets perform better than pigs weaned and offered a three starter diet regime.
As expected, NURSE pigs (both ‘high’ and ‘low’) had higher concentrations of serum IgG than the other groups in the 3 measuring points, indicating improved humoral immunity [
20], mainly due to being of older age at each measuring point. Surprisingly, NORM ‘high’ pigs had significantly lower IgG concentration than NORM ‘low’ at 28 d post-weaning, and did not differ from WEAN pigs at any sampling point. In contrast, a different study [
21] found lower IgG concentration in low (≈ 5 kg) wean weight pigs compared to normal (≈ 7 kg) wean weight pigs. Our findings might suggest that, at the same age, small pigs might benefit from a higher quality diet post-weaning, whereas in normal weight pigs a ‘high’ starter diet allowance does not enhance their immunological maturity compared to a ‘low’ allowance. More research is needed to understand the impact of starter diet and its allowance on piglets’ active immune capacity based on their weaning weight.