Animals and diets

Ten male growing pigs (Large White × Land Race × Pietrain), three-month-old and an initial average body weight (BW) of 35·6 kg (± 2·0), were used. Pigs were acclimatised for 7 d in individual pens with slatted floors. The room temperature was maintained between 21 and 24 °C (thermoneutral zone), with a 12 h light/dark cycle. One week before starting the experiment, the pigs were surgically fitted, under general anesthesia, with a T-shaped cannula (silicone rubber) in the ileum (8 cm insert into the lumen of the digestive tract)^{(Reference Wubben, Smiricky and Albin14)} and a catheter (polyvinyl chloride; 1·02 mm internal diameter, 2·16 mm outer diameter) in the jugular vein (about 20 cm inside the blood vessel)^{(Reference Fudge, Coleman and Parker15)}. To avoid any risk of infection after the operation, the animals received one dose of antibiotic on the day of the operation and then five doses until the third day after the operation (Septotryl at a dose of 2 ml/30 kg BW intravenously).

Four diets were formulated for the study: a basal diet, two experimental diets containing either WRP or GGRP as protein ingredient and a protein-free diet (Table 1). During the acclimatisation and recovery period following the surgical procedure, pigs were fed a basal diet. The experimental diets were formulated in accordance with FAO recommendations, with a target of 10 % dietary proteins on a DM basis^{(4,Reference Hodgkinson, Stein and De Vries16)} . The tested proteins were dehydrated beef proteins, GGRP and WRP, both derived from bovine co-products and supplied by a local factory (CORNILLE sas, France). The GGRP is obtained during the fat rendering process of beef. The WRP is derived from water recovery during the fat rendering process of beef and during the bone degreasing process^{(Reference Le Foll, Lechevalier and Hamon11,Reference Denis17)} . The characterisation of these two protein ingredients was determined in a previous article^{(Reference Le Foll, Lechevalier and Hamon11)}. Each protein ingredient was included in one experimental diet as the sole source of crude protein (CP), so that the diets were isonitrogenous. A protein-free diet was used to estimate basal endogenous losses of nitrogen (N) and AA. Titanium dioxide (TiO₂, 3 g/kg) was included as an indigestible solid phase marker for the calculation of the ileal digestibility of AA^{(Reference Jagger, Wiseman and Cole18)}. Vitamins and minerals were included in all diets to meet current requirement estimates for growing pigs⁽¹⁹⁾. As the WRP ingredient contained more NaCl than the GGRP ingredient (6·44 % and 0·58 %, respectively), an adjustment in NaCl content was required in the GGRP and protein-free diets. Thus, to obtain the same NaCl content as the WRP diet (9·43 g/kg), 8·74 g/kg NaCl was added to the GGRP diet to supplement the NaCl provided by the GGRP ingredient (0·69 g/kg); 9·43 g/kg NaCl was added to the protein-free diet.

Table 1.

Ingredient composition of the diets

WRP, water recovered proteins; GGRP, greasy greaves recovered proteins; TiO₂, titanium dioxide.

* Diets were formulated to contain approximately 10 % crude protein on an as-fed basis

† The vitamin–micromineral premix provided the following quantities of vitamins and minerals per kg of complete diet: Vit. A: 1 000 000 U.I; Vit. D3: 200 000 U.I; Vit. E: 4000 mg; Vit. K3 (MNB): 870 mg; Vit. B1-Thiamin: 400 mg; Vit. B2-Riboflavin: 800 mg; Vit. PP-Niacin: 3000 mg; Vit. B5-Pantothenate Ca: 2000 mg; Vit. B6-Pyridoxine: 200 mg; Vit. H-B8-Biotin: 40 mg; Vit. B9-Folic acid: 200 mg; Vit. B12-Cyanocobalamin: 4 mg; Choline chloride: 133 333 mg; Fe (sulfate monohydrate): 16 000 mg; Cu (sulfate pentahydrate): 2000 mg; Zn (oxide): 14 000 mg; Mn (oxide): 8000 mg; Se (selenite): 30 mg; I (calcium): 40 mg.

Experimental design

The experiment took place in two blocks of five animals each (online Supplementary Fig. S1). Each pig was fed the two experimental diets (WRP and GGRP) for 4·5 d each in a crossover design. The protein-free diet was then fed after the two experimental diets, also for 4·5 d. The first block consisted of three pigs fed first the WRP diet, then the GGRP diet, and finally the protein-free diet, and two pigs fed first the GGRP diet, then the WRP diet, and finally the protein-free diet. In the opposite way, the second block consisted of two pigs receiving the WRP diet first, then the GGRP diet, and finally the protein-free diet, and three pigs receiving the GGRP diet first, then the WRP diet, and finally the protein-free diet. In order to facilitate diet consumption on the sampling day, a period of adaptation to each of the diets tested was carried out during the 3·5 d preceding the sampling day, giving an increasing proportion of the diet to be tested (diet 2) and a decreasing proportion of the diet previously tested (diet 1) as follows: 75:25; 50:50; 25:75; 0:100 (diet 1:diet 2, % w:w).

The diets were mixed with water (0·5:1, diet:water, w:w) to facilitate ingestion. The pigs had free access to water and were fed twice daily at 8 a.m. and 4 p.m., except on sampling days at 5 p.m. The daily dietary ration for each pig was 0·08 × BW^0·75 (kg), calculated on a DM basis. Pigs were weighed at each diet change, and the daily ration of each pig was adjusted according to the BW of the pig. In total, the experimental period lasted 13·5 d for each animal, comprising, for each diet (WRP, GGRP or protein-free diet), 3·5 d of adaptation to the diet and 1 sampling day (digesta and blood sampling) over a 9-h postprandial period. Adding the 12·5 d of acclimatisation and postoperative recovery, the study therefore lasted a total of 26 d for each animal.

On each sampling day (one per diet), the pigs received the experimental diet at 8 a.m. Feed was available for 15 min, so as not to affect the kinetics of AA transfer into the plasma. Feed refusals were collected and weighed where appropriate. The sampling of ileal digesta started directly after the ingestion of the test diet and lasted for the 9 following hours. Digesta were collected continuously in pre-weighed plastic bags (Whirl-Pak, 540 ml) attached to the ileal cannula. The bags contained 1·5 ml sodium benzoate (2·3 mol/l) in order to avoid bacterial growth. The mixing of sodium benzoate in the ileal digesta was carried out manually. Full bags were replaced with empty ones when necessary (at least after the 1st hour, then every 2 h). Content was immediately transferred to a plastic box (previously weighed) and stored at −20 °C before being freeze-dried. The freeze-dried samples were then grouped into five pools corresponding to the collection periods between 0 and 1 h postprandial, 1–3 h, 3–5 h, 5–7 h and 7–9 h. Finally, an overall sample, representative of the entire postprandial period, was prepared by mixing these five pools in proportion to the quantity of DM in each of them. On the same day as the digesta sampling, blood samples (2·5 ml per time point) were collected in heparin-lithium tubes at 30 min before and 20, 40, 60, 90, 120, 180, 300, 420 and 540 min after the diet ingestion. Plasma was immediately separated by centrifugation at 4 °C for 10 min at 2500 g and stored at −80 °C until AA analysis was performed.

Chemical analysis

Ingredients WRP and GGRP were analysed in triplicate for DM, total AA and total N. Diets were analysed in triplicate and ileal digesta in duplicate for DM, total AA, total N and TiO₂. Plasma samples were analysed in single for free AA content, urea and insulin.

The DM content was determined gravimetrically at 102 ± 2 °C for 5 h.

The total AA content was determined according to Davies and Thomas^{(Reference Davies and Thomas20)}. Samples were hydrolysed for 24 h in 6 mol/l hydrochloric acid at 110 °C in N-sealed glass tubes. For Cys and Met, performic acid oxidation was carried out before acid hydrolysis. The AA were separated by ion exchange chromatography (Biochrom30+ automatic AA Analyzer) using a lithium citrate buffer (2·5 % final) as eluent^{(Reference Moore, Spackman and Stein21)} and quantified photometrically after ninhydrin derivatisation (EZ NIN Kit, Biochrom). Absorbance was measured at 570 nm, except for Pro and HyPro (hydroxyproline) detection (440 nm), and AA were quantified using an external calibration curve previously established with standards (A6407 and A6282, Sigma). The Trp was analysed after sample hydrolysis with Ba(OH)₂ for 16 h at 110 °C in Teflon tubes with screw cap^{(Reference Charton, Bourgeois and Bellanger22)}. The Trp was determined using an RP-HPLC system (Waters™ e2695 Separations Modul) and quantified by fluorimetry (excitation at 280 nm and emission at 346 nm). The L-Trp standard (0–10 mg/l), corrected by the internal 5-methyl-Trp standard, was used for Trp quantification.

The concentration of free AA in plasma was determined after deproteinisation of the samples^{(Reference Mondino, Bongiovanni and Fumero23)}, using the same ion exchange chromatography, the same ninhydrin derivatisation and the same absorbance measurement as used for total AA. For deproteinisation, plasma samples were incubated with sulfosalicylic acid solution (5 % SSA, including N-Leu internal standard) at 0 °C for 1 h and then centrifuged (10 000 g, 10 min) before filtration on a 0·45 µm membrane. Free AA were quantified using an external calibration curve previously established with standards (A6407, A6282, Gln, urea, 2·5% SSA and N-Leu, Sigma) in lithium citrate buffer. Urea content was determined concomitantly with the free AA analysis. Insulin concentration in plasma was measured using a RIA kit (Insulin-CT, CisBio Bioassays) and an AIA-1800 device (Automated Immunoassay Analyzer; TOSOH Bioscience)^{(Reference Eugenio, van Milgen and Duperray24)}.

Total N in diet and digesta samples was analysed by the Dumas method on a LECO FP 828 analyser after calibration using EDTA. The N to protein conversion factor of 6·25 was used to determine their CP content⁽²⁵⁾.

The TiO₂ content was determined based on a method adapted from Mudunkotuwa et al. ^{(Reference Mudunkotuwa, Anthony and Grassian26)}. Mineralisation by microwave-assisted acid digestion was first carried out (ETHOS UP, Thermo Fisher Scientific). For this, 0·25 g of samples were heated to 210 °C in the presence of acid (2 ml HNO₃ 98 % + 4 ml H₂SO₄ 69 %) in Teflon digestion vessels, with a ramp time of 25 min and a holding time of 15 min. Then 30 ml of ultrapure H₂O were added after sample cooling. The TiO₂ content was then measured using inductively coupled optical emission spectrometry (ICP-OES, Thermo Fisher Scientific) using an external calibration curve (0–10 mg/l TiO₂). All samples were diluted in HNO₃ 5 % before analysis.

Data analysis

Total N flow was calculated, according to Hodgkinson et al. ^{(Reference Hodgkinson, Stein and De Vries16)}, as follows (in mg/g dry matter intake, DMI):

(1) $${\rm{Total}}\;{\rm{N}}\;{\rm{flow}} = \;{\left[ {{\rm{Total}}\;{\rm{N}}} \right]_{digesta}}\; \times \;{{{{\left[ {{\rm{Ti}}{{\rm{O}}_2}} \right]}_{diet}}} \over {\;{{\left[ {{\rm{Ti}}{{\rm{O}}_2}} \right]}_{digesta}}}}$$

where [Total N] _digesta and [TiO ₂ ] _digesta were expressed in mg/g of DM of digesta and [TiO ₂ ] _diet expressed in mg/g of DM of diet.

The AA flow was calculated in the same way, replacing [Total N]_digesta with [AA]_digesta in Eq. 1.

The TID of N was calculated in the pooled digesta, according to Hodgkinson et al. ^{(Reference Hodgkinson, Stein and De Vries16)}, as follows (in %):

(2) $$\scriptsize{{\rm{TID}}\;{\rm{of}}\;{\rm{N}}\;\left( \% \right) = {{{{\left[ {{\rm{Total}}\;{\rm{N}}} \right]}_{{\rm{diet}}}}\;\; - \;\left( {{\rm{Total}}\;{\rm{N}}\;{\rm{flow}}\; - \;{\rm{Endogenous}}\;{\rm{Total}}\;{\rm{N}}\;{\rm{flow}}} \right)} \over {{{\left[ {{\rm{Total}}\;{\rm{N}}} \right]}_{{\rm{diet}}}}}}\; \times \;100}$$

where variables were expressed in mg/g DMI.

The TID of AA was calculated in the same way, replacing [Total N]_diet with [AA]_diet, ‘Total N flow’ with ‘AA flow’ and ‘Endogenous Total N flow’ with ‘Endogenous AA flow’, in Eq. 2.

Digestible indispensable amino acid (DIAA) reference ratio was calculated for each essential AA (EAA), according to Hodgkinson et al. ^{(Reference Hodgkinson, Stein and De Vries16)}, using the AA scoring pattern of the reference protein for three different populations, namely undernourished children (0·5–5 years old)⁽²⁷⁾, healthy children (0·5–3 years old), and >3 years old children, adolescents and adults⁽⁷⁾:

(3) $$\eqalign{\scriptsize{{\rm{DIAA}}\;{\rm{reference}}\;{\rm{ratio}}\;\left( \% \right)} =\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\cr {\scriptsize{100\; \times} {\scriptsize{{\;{\rm{mg}}\;{\rm{of}}\;{\rm{the}}\;{\rm{EAA}}\;{\rm{in}}\;1\;{\rm{g}}\;{\rm{of}}\;{\rm{the}}\;{\rm{dietary}}\;{\rm{protein}}\;{\rm{x}}\;{\rm{TID}}\;{\rm{of}}\;{\rm{the}}\;{\rm{EAA}}} \over {{\rm{mg}}\;{\rm{of}}\;{\rm{the}}\;{\rm{EAA}}\;{\rm{in}}\;1\;{\rm{g}}\;{\rm{of}}\;{\rm{the}}\;{\rm{reference}}\;{\rm{protein}}}}}}\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,}\;$$

where 1 g of the dietary protein corresponded to 1 g of CP (total N × 6.25).

DIAAS was defined as the lowest value of DIAA reference ratio⁽⁷⁾.

Semi-dynamic digestion and analysis of digesta

The in vitro semi-dynamic model (INFOGEST) was used to simulate gastric digestion of both WRP and GGRP diets. The semi-dynamic digestions were carried out according to a method adapted from Mulet-Cabero et al. ^{(Reference Mulet-Cabero, Egger and Portmann28)} using the pH-stat device with a pH probe (Porotrode, Ref 60235200, 842 Titrando, Metrohm) and tiamo™ software (Metrohm). The model included a progressive five-step addition of gastric secretions (HCl, pepsin and simulated gastric fluid), according to Musse et al. ^{(Reference Musse, Le Feunteun and Collewet29)}. The progressive gastric emptying was not considered in the present experiment. In this study, only the oral and gastric phases of digestion were performed, and for the oral phase only a dilution of the diets was carried out with simulated salivary fluid without enzyme. Samples (5 ml) were collected at 40, 80 and 120 min of the gastric phase to evaluate their microstructure based on confocal microscopy and particle size distribution as well as their viscosity.

Microstructures of the reconstituted diets in water (0·5:1, diet:water, w:w) and gastric digesta were observed using a laser scanning confocal microscope (ZEISS LSM880, Carl Zeiss AG) at 20× magnification, at 37 °C, as described by Chauvet et al. ^{(Reference Chauvet, Ménard and Le Gouar30)}. The particle size distribution of these samples was determined using laser light scattering with a Malvern Mastersizer 2000 (Malvern Instrument Ltd). The refractive index of protein was set at 1·52 and that of water at 1·33. The particle diameter was expressed as the median diameter d_0·5 and the volume-weighted average diameter d_4,3 as follows:

(4) $${d_{4,3}} = {{\sum {{n_i}} d_i^4} \over {\sum {{n_i}} d_i^3}}$$

with n _i the number of droplets of diameter d _i .

The rheology of the reconstituted diets in water (0·5:1, diet:water, w:w) and of the gastric digesta was measured using a rheometer (AR2000, EX TA Instrument) at 37 °C, as described by Wu et al. ^{(Reference Wu, Deng and Wu31)} with a slight modification. The scanning range of the steady shear rate was 0·1–500/s. The viscosity value considered for result analysis was that measured at 10/s.

Statistical analyses

Statistical analyses were performed using the R software (version 3.6.2)⁽³²⁾.

A linear mixed model (lmerTest package) was used to test the ‘diet’ effect and ‘block’ effect on the TID of total N and of each AA, with pig as a random factor. If there was no statistically significant ‘block’ effect, it was removed from the model.

The plasma AA, urea and insulin concentrations were statistically analysed by a linear mixed model (lmerTest package) considering the factors ‘diet’ (WRP and GGRP), ‘time’ (–30, 20, 40, 60, 90, 120, 180, 300, 420 and 540) and their interaction, with pig as a random factor. When the interaction was statistically significant, a post hoc test was performed to establish the pairwise comparisons (Emmeans, Tuckey adjustment).

Before carrying out the analyses, normality (Shapiro–Wilk test) and homoscedasticity (Levene’s tests) of the model residuals were verified (P > 0·05). The covariance was unstructured. Statistical significance was considered at P < 0·05.

Data are presented as mean ± s em, unless otherwise mentioned.