Treatments, animals and housing

The study was conducted in a commercial piggery using a total of 92 parity 2 and 3 sows (Danish Landrace × Danish Yorkshire, DanAvl) inseminated with Duroc semen (Hatting KS, Horsens, Denmark). The animals were studied from 4 days prepartum (−4.1 ± 1.6) to 24 days postpartum (24.4 ± 1.2) when piglets were weaned. Sows were randomly allocated to one out of six dietary treatments with increasing dietary provision of SID protein (Table 1) and stratified for parity in a complete block design from day 2 postpartum. Diets were formulated to be isoenergetic on net energy basis (EvaPig^®, 2008). Sows were fed using a SpotMix feeding system (Schauer Agrotronic, Prambachkirchen, Austria), and meals for each sow were weighed and registered by the feeding system. From day 4 prepartum to day 2 postpartum all sows were fed the same commercial formulated lactation diet based on wheat, soybean meal and sugar beet pulp complying with Danish recommendations (Tybirk et al., Reference Tybirk, Sloth and Jørgensen2014). From day 2 to day 10 of lactation, sows were fed twice daily, and from day 10 onwards, sows were fed three times per day. The sows were fed 2.3 kg from day 2 postpartum, and feed allowance was gradually increased to 8.4 kg at day 17. Sows had drinking nipples in the trough and free access to water. Feed residuals were not recorded, but feed allowance was adjusted for individual sows daily, and the feed allowances mentioned above were used as maximum for the sows, so some sows would consume less.

Table 1 Dietary composition (as-fed) of diets fed to sows from day 2 postpartum to weaning

Lys=lysine; Met=methionine; Thr=threonine; Trp=tryptophan; Leu=leucine; Ile=isoleucine; His=histidine; Phe=phenylalanine; Val=valine; SID=standardized ileal digestible.

¹ Leci E Basic, Evilec ApS, Sandbjergvej 26, 6000 Kolding, Denmark.

² Provided per kilogram of the diet: 8900 IU vitamin A; 890 IU vitamin D3; 167 mg dl-alfa-tocopherol, 4.24 mg vitamin K3; 2.23 mg vitamin B1; 5.57 mg vitamin B2; 3.34 mg vitamin B6; 0.02 mg vitamin B12; 16.70 mg d-pantothenic acid; 22.26 mg niacin; 1.67 mg folic acid; 89.04 mg iron (FeSO₄); 13.00 mg copper (CuSO₄); 44.52 mg manganese (MnO); 0.22 mg iodine (Ca(IO₃)₂); 0.37 mg selenium (Na₂SeO₃).

³ Phyzyme XP provided 500 phytase activity (FTU) per kilogram of diet (Danisco Animal Nutrition DuPont, Marlborough, UK).

⁴ SID values used in diet formulation were from Pedersen and Boisen (Reference Pedersen and Boisen2002).

⁵ Feed samples were sampled regularly during the experimental period, and 12 feed samples were analysed per dietary treatment.

⁶ Calculated from the analysed composition and digestibilities used when formulating the diets.

Each week a batch of six sows was selected for the experiment, moved to the farrowing unit day 4 prepartum and placed in individual farrowing crates. Twenty-four hours postpartum (day 2) the litters of the experimental sows were standardized to 14 piglets (average piglet weight 1.76 ± 0.24 kg). Apart from the observations made in the experiment all animals were managed according to the general routines of the herd. Health was monitored by the stock personnel, and normal herd practices for management, treatments and vaccinations were followed. When dead or very weak piglets were removed, the date and weight of the excluded piglets were recorded.

Data collection, measurements and chemical analyses

Information on the collection of feed samples and analyses is given in Strathe et al. (Reference Strathe, Bruun, Geertsen, Zerrahn and Hansen2017a). On 544 sows, BW and back fat (BF) thickness were measured at day 2 postpartum and at weaning, and litter weight was recorded at litter standardization and at weaning (Strathe et al., Reference Strathe, Bruun, Geertsen, Zerrahn and Hansen2017a).

On 70 sows (10 to 12 per dietary treatment), blood, urine and milk samples were collected. Blood samples were collected in 10 ml EDTA tubes (BD Vacutainer, Plymouth, UK) from the jugular vein at days −4, 3, 10, 17, and 24 postpartum 4 h after the morning feeding. Samples were placed on ice and centrifuged for 10 min (1560×g) at room temperature, and plasma was then harvested and stored at −20°C in 1.5-ml microcentrifuge tubes (Kruuse, Langeskov, Denmark) until analysis. Plasma was analysed for concentrations of PUN, creatinine, glucose, lactate and non-esterified fatty acids (NEFA), triglycerides, cholesterol, total protein, albumin, alanine amino transferase (ALT), aspartate amino transferase (AST), gamma-glutamyl transferase (GGT) and alkaline phosphatase (Advia 1800 Chemistry System; Siemens, Denmark).

Milk samples were collected on days 3, 10 and 17 postpartum. Piglets were removed from the sow for at least 30 min, and 2 ml oxytocin (Oxytocin ‘Intervet’ Vet, 10 IE/ml; Intervet International B. V., Boxmeer, Netherlands) was injected intramuscularly to induce milk letdown. Milk was sampled from four to five teats and stored in 50-ml tubes (Sarstedt, Nümbrecht, Germany) at −20°C until analysis for DM, lactose, fat and true protein (MilcoScan FT2, Foss Electric, Denmark).

On another subsample of 60 sows (10 per treatment), body water content was measured by the deuterium oxide (D₂O) dilution technique (Theil et al., Reference Theil, Nielsen, Kristensen, Labouriau, Danielsen, Lauridsen and Jakobsen2002) on days 3 and 24 postpartum. An initial blood sample was drawn from the jugular vein into a 4-ml lithium-heparinized tube (BD Vacutainer, Plymouth, UK) just before D₂O injection, and then 5 h after injection with D₂O, a second sample was taken. A dose of 0.2 ml (10% solution of D₂O; Sigma Aldrich, Brøndby, Denmark) per kg BW was injected i.m. in the neck of the sow. The exact amount of D₂O injected was determined by weighing the syringe before and after injection. The blood samples were centrifuged for 10 min (1560×g) at room temperature, and plasma was then recovered and stored in 1.5-ml microcentrifuge tubes (Kruuse, Langeskov, Denmark) at −20°C until analysis. The total D₂O space was determined as described by Theil et al. (Reference Theil, Nielsen, Kristensen, Labouriau, Danielsen, Lauridsen and Jakobsen2002).

Calculations and statistical analysis

Calculations and statistical analyses were carried out using the statistical software R (R Core Team, Vienna, Austria) with the individual sow regarded as the experimental unit. Average daily gain (ADG) of the litter was calculated from litter size and weight at standardization and at weaning. Weights of dead piglets or piglets removed from the litter during the experiment were included in the litter gain. Milk yield was estimated from ADG of the litter and litter size (data not shown) using equations by Hansen et al. (Reference Hansen, Strathe, Kebreab, France and Theil2012). The content of body water was estimated based on the measured concentrations of D₂O in plasma. From body water, BF and BW, the body protein, fat and ash contents were estimated using equations by Rozeboom et al. (Reference Rozeboom, Pettigrew, Moser, Cornelius and el Kandelgy1994). In the analysis of the dose–response data, the dietary SID CP concentrations were used as an explanatory variable. Based on the recordings of individual daily feed intakes of the sows, chemical analysis of dietary composition, and digestibility coefficients of CP of the six diets, an average dietary SID CP concentration was calculated for the individual sow.

Data were fitted using a mixed-effects model in ANOVA form using the nlme package in R to describe the effect of the six dietary treatments. Feed intake, sow BW and BF, sow body composition and changes in body composition, and litter weight were analysed using model (1). The interaction between diet and parity was tested, but the interaction and the effect of parity were not significant and therefore eliminated in the final model:

$${Y_{ijk}} = \mu + {\alpha _i} + {\beta _j} + {\varepsilon _{ijk}}$$ (1)

where Y _ijk is the response variable measured on the k th sow (k = 1, …, n _ij ) in the jth block (j = 1, 2, …, 16) receiving the i th diet (i = 1, …, 6). Here µ is the overall mean, α _i is the fixed effect of diet, β _j is the random effect of block that was assumed to be N(0, $\sigma _B^2$ ), and ε _ijk is the random error component, which was assumed to be N(0, $\sigma _e^2$ ).

When analysing milk yield and composition, daily secretions and concentrations of plasma metabolites, a repeated-measures model was fitted to data. The three-way interaction between diet, parity and day were included in model (2), but none of the three-way or two-way interactions and the effect of parity were significant and therefore excluded from the final model:

$${Y_{ijkl}} = {\rm{ }}\mu {\rm{ }} + {\alpha _i} + {\beta _j} + {\gamma _k} + {\nu _l} + {\varepsilon _{ijkl}}$$ (2)

where Y _ijkl is the response variable measured on the lth sow (l = 1, …, n _ijk ) in the kth block (k = 1, 2, …, 16) receiving the ith diet (i = 1, …, 6) on the jth day postpartum (j = 1, …, 5). Here µ is the overall mean, α _i is the fixed effect of diet, β _j is the fixed effect of day postpartum, γ _k is the random effect of block that was assumed to be N(0, $\sigma _B^2$ ), ν _l is the random effect of sow that was assumed to be N(0, $\sigma _S^2$ ), and ε _ijkl is the random error component that was assumed to be N(0, $\sigma _e^2$ ). Plasma concentrations of lactate, NEFA, alkaline phosphatase and GGT were log-transformed, because of lacking variance homogeneity. Results are given as least squares means and SE. Log-transformed data were back-transformed and given as least squares means and 95% confidence interval (CI). Statistical significance was declared at P < 0.05 and tendency at P < 0.10.

All response variables were analysed using either a linear dose–response function or nonlinear dose–response function, being the linear broken-line and quadratic broken-line. Here dietary CP concentration was treated as a continuous variable. The nonlinear dose–response models were fitted using nonlinear mixed-effects models, where the random effect of block was incorporated into the plateau parameter of the models as described by Robbins et al. (Reference Robbins, Saxton and Southern2006). Taking the linear plateau model as an example, then the nonlinear mixed-effect model was formulated as:

$${y_{ij}} = \left\{ {\matrix{ {k*\left( {R - C{P_{ij}}} \right);C{P_{ij}} < R} \cr {{y_{{\rm{max}}}} + {b_i};C{P_{ij}} > R} \cr } } \right. + {e_{ij}}$$ (3)

where y _ij denotes response variable for the jth sow in the ith block. Population parameters are the slope k in response to dietary CP _ij below the requirement R and y _max is plateau level, where the dietary CP _ij is not limiting sow performance. The random effect b _i captures the block-to-block variation in sow performance and is assumed to be N(0, $\sigma _B^2$ ), and ε _ij is the random error component, which was assumed to be N(0, $\sigma _e^2$ )

The model output was evaluated using three criteria: (1) comparison of Akaike Information Criteria and −2 log likelihood fit statistics for nested models, (2) models with breakpoint outside the range of the tested SID CP concentrations was regarded inappropriate, and (3) evaluation of visual fit to data. The nonlinear models were compared to the linear model using the abovementioned criteria. However, only results of variables with a significant effect of dietary CP concentration are shown in the Results section. All data were used to fit the models, but in Figures 1 and 2 the least square means for the six groups are also presented together with the best model as described above.

Figure 1 Changes in the contents of body water, protein and ash from day 3 to day 24 postpartum with increased standard ilea digestible (SID) dietary protein. The content of body water was determined using the deuterium dilution technique (Theil et al., Reference Theil, Nielsen, Kristensen, Labouriau, Danielsen, Lauridsen and Jakobsen2002). Body protein and ash were estimated from body water, BW and back fat thickness. The loss is given as the percentage of tissue mass at day 3. Data were fitted using linear regression, linear broken-line and quadratic broken-line models using nonlinear mixed-effects models. The model with the best fit is presented in the figure. Data points in the figures are least square means and SE of the six dietary groups, and the linear broken-line model or the linear regression model using data of individual sows are also presented. (a) Body water loss decreased linearly (−0.3 × (SID CP – 130) × (SID ${\rm{CP}} \le 130$ ) – 2.5) until 130 g SID CP/kg at a loss of 2.5% (P<0.001), (b) body protein decreased linearly (−0.2 × (SID CP – 128) × (SID ${\rm{CP}} \le 128$ ) + 1.5) until 128 g SID CP/kg at a loss of 1.5% (P<0.001) and (c) body ash loss decreased linearly (Y = 25.5−0.23 × SID CP (g/kg); P<0.001). Negative values indicate a gain.

Figure 2 Effect of dietary standardized ileal digestible (SID) CP concentrations on the plasma concentrations of metabolites. Data were fitted using linear regression, linear broken-line and quadratic broken-line models using nonlinear mixed-effects models. The model with the best fit is presented in the figure. Data points in the figures are least square means and SE of the six dietary groups, and the linear broken-line model or the linear regression model using data of individual sows are also presented. (a) Urea N was at a stable level until a linear increase from 139 g SID CP/kg (0.09 × (SID CP – 139) × (SID CP ≥ 139) + 3.8) in early lactation (day 3 + day 10) and at a stable level until a linear increase from 133 g SID CP/kg (0.09 × (SID CP – 133) × (SID CP ≥ 133) + 4.5) in late (day 17 + day 24) lactation, respectively (P<0.001); (b) albumin increased linearly (Y = 27.7 + 0.06 × SID CP (kg/day)) at late (day 17 + day 24) lactation (P<0.05); (c) alanine amino transferase increased linearly at day 17 (Y = 72.8 – 0.23 × SID CP (g/kg); P<0.01) and day 24 (Y = 80.1 – 0.26 × SID CP (g/kg); P<0.05) of lactation and (d) gamma-glutamyl transferase (days 3 + 10 + 17 + 24) increased linearly (Y = 31.2 + 0.05 × SID CP (g/kg)) with increasing dietary SID CP (P<0.05), respectively.

When the ANOVA revealed that there was no difference between sampling days (P>0.10), data for these days were pooled. For PUN, data from days 3 and 10, and days 17 and 24, respectively, were combined. Data for plasma albumin at days 17 and 24 were united. For GGT, data from days 3, 10, 17 and 24 were pooled.