Animals and diets

A total of four non-pregnant, non-lactating adult Rasa Aragonesa ewes, fitted with rigid ruminal (5 cm internal diameter) and T-shaped duodenal cannulae, and with an average initial live weight of 54·0 (sem 2·88) kg, were used. They were allocated, following a latin square design, to four treatment groups consisting of different proportions of lucerne (Medicago sativa) hay and ryegrass (L. rigidum) hay, both chopped to 5 cm (1·00 lucerne (D1), 0·67 lucerne and 0·33 ryegrass (D2), 0·33 lucerne and 0·67 ryegrass (D3) and 1·00 ryegrass (D4)). At 1 month before the experiment, the sheep were treated with Albendazol (10 ml) to control internal parasites. Water and mineral blocks were available at all times throughout the experimental period. Animals were handled according to criteria from the European Union for the care and use of laboratory animals in research, and the experimental protocol was approved by the Ethical Committee for Animal Research of the University of Zaragoza. The chemical composition and alkane concentration of lucerne and ryegrass are shown in Table 1.

Table 1 Chemical composition (g/kg DM) and mean concentration of n-alkanes (mg/kg DM) in lucerne and ryegrass

Experimental management

After implantation of the duodenal and ruminal cannulae in the animals, a recovery period of 3 weeks was allowed. Then, the first run of the latin square was started, which lasted for 26 d, of which the first 14 d were for adaptation to the diets. During the adaptation period, sheep were housed in individual pens (110 cm × 90 cm) with slatted floors. The experimental diets were offered once daily (at 09.00 hours, for 24-h clock) at a restricted level (95 % of ad libitum intake), which was set for each animal during the adaptation period, in order to minimise refusals. Lucerne and ryegrass were offered in separate troughs. During the last 4 d of the adaptation period, samples of lucerne and ryegrass were ruminally incubated in polyester bags (45-μm pore size) for up to 96 h. After the adaptation period, animals were placed in metabolism crates (118 cm long, 46 cm wide and 73 cm high) and a 7-d digestibility balance was performed after a 3-d adaptation period. Animals in metabolism crates were fed at every 4 h (at 09.00, 13.00, 17.00, 21.00, 01.00 and 05.00 hours, for 24-h clock) by means of automatic feeders. From 1 week before and until the end of the balance period, a once-daily dose of 1·5 g of paper pellets containing equal amounts of dotriacontane (C₃₂; 79·3 (sem 4·22) mg/pellet) and hexatriacontane (C₃₆; 77·2 (sem 4·60) mg/pellet) was given to the animals with a dosing gun, just before the morning feeding (09.00 hours).

During the second day of the adaptation period to metabolism crates, 1000 ml of rumen contents were obtained at 09.00 hours (before feeding) to isolate background samples of liquid- (LAB) and solid-adherent bacteria (SAB). Another sample of duodenal digesta was also obtained as background reference for the analyses of flow markers (Cr for liquid and Yb for solid phase). In the second day of the balance trial, infusion of 4 ml/h of a Cr-EDTA solution (1 g/l) and 4 ml/h of a YbCl₃ solution (1 g/l) was started, using a peristaltic pump (Gilson Minipuls 2) with separate lines, to provide 2 mg/kg live weight per d of both Cr and Yb. After 3 d, a 5-d dose of labelled ammonium sulphate (10 % atoms ¹⁵N; Isotec, Inc.) was incorporated into the Cr-EDTA solution to provide 1·5 mg of ¹⁵N/g N intake (NI) as microbial marker. The infusion of all three markers was maintained until the end of the experimental period. This meant that flow markers (Cr-EDTA and YbCl₃) were infused for 6 d before duodenal sampling and labelled ammonium sulphate for 3 d.

During the digestibility balance period, daily samples of lucerne and ryegrass (and refusals when they occurred) were taken and pooled for the whole period. Half of each sample was dried at 60°C for 48 h for DM determination, and the other half was kept for chemical composition (organic matter (OM), CP, neutral-detergent fibre (NDF), acid-detergent fibre (ADF; except refusals) and acid-detergent lignin (ADL; except refusals)) and alkane analysis, after grinding through a 1-mm screen. Faeces were collected daily and a sub-sample (5 % on weight basis) was taken and kept frozen ( − 20°C) until the end of the collection period. The sub-samples from the 7 d were pooled to a single sample per animal and then freeze-dried for analysis of chemical composition (OM, CP, NDF and n-alkanes). Sub-samples of daily faeces were also taken for oven drying at 60°C for 48 h to estimate faecal DM output.

The last 2 d after the digestibility balance were assigned to sampling of duodenal digesta, which was performed at 6-h intervals. Individual samples were kept at 4°C until the end of the sampling period, then pooled on an animal basis and frozen at − 20°C. Those samples were thawed and three sub-samples were taken: whole digesta, and its solid and liquid phases (after straining through polyester bags with 45-μm pore size). The sub-samples were again frozen at − 20°C and then freeze-dried and ground through a 1-mm screen for chemical composition (whole digesta and its solid fraction only) and Cr and Yb analysis. Immediately after the last duodenal sample was taken, rumen emptying was carried out, the weight of rumen contents was recorded and samples of LAB and SAB were isolated for ¹⁵N-enrichment determination. Samples for chemical composition studies (DM, OM, CP and NDF) were also taken, dried at 60°C for 48 h and ground through a 1-mm screen. The pH of rumen liquor was recorded, and samples for analysis of volatile fatty acids (VFA) and NH₃ concentrations were also taken. The sampling process was as quick as possible, and at the end the remaining rumen contents were immediately returned to the corresponding sheep. The average time each sheep remained ‘empty’ was about half an hour.

The experimental management was the same for the other three periods of the latin square, and live weight was recorded for all animals at the same time, at the beginning and the end of each period.

Samples for VFA analysis were prepared by adding 1 ml of deproteinising solution (0·2 % (w/v) of mercuric chloride, 2 % (v/v) of orthophosphoric acid and 0·2 % (w/v) of 4-methyl valeric acid) to 4 ml of rumen contents strained through four layers of cheesecloth and preserved frozen ( − 20°C) until analysis. For the determination of NH₃ analysis, 5 ml of 0·1 m-HCl were added to 5 ml of filtered rumen digesta and preserved frozen ( − 20°C) until analysis.

Isolation of bacterial fractions (LAB and SAB) from both blank and ¹⁵N-labelled ruminal samples was carried out as described by Martin et al. ⁽Reference Martin, Williams and Michalet-Doreau¹⁶⁾. Both LAB and SAB were frozen at − 20°C and then freeze-dried to determine their chemical composition (OM and N) and ¹⁵N abundance. The concentration of n-alkanes in LAB samples was also determined.

Marker techniques

Cr-EDTA was prepared by the methods of Downes & McDonald⁽Reference Downes and McDonald¹⁷⁾, and 360 ml of the Cr-EDTA solution were mixed with 640 ml of distilled water before infusion. Ytterbium chloride (YbCl₃.6H₂O) solution was prepared by dissolving 24 g in 5 litres of distilled water.

The analysis of Cr and Yb was carried out as described by de Vega & Poppi⁽Reference de Vega and Poppi¹⁸⁾. Standards were made by spiking blank duodenal samples with different amounts of Cr and Yb solutions of known concentrations and treating them in the same way as the experimental samples. Marker concentrations were determined by inductively coupled plasma atomic emission spectroscopy.

Paper pellets containing C₃₂ and C₃₆ were prepared following the technique described by Keli et al. ⁽Reference Keli, Andueza and de Vega¹⁹⁾. About 5 % of the pellets were sampled and analysed for alkane concentration, as described by Valiente et al. ⁽Reference Valiente, Delgado and de Vega²⁰⁾.

Ground samples of lucerne, ryegrass, refusals, LAB, whole duodenal digesta, solid phase of duodenal digesta and faeces were analysed for n-alkane concentrations following the procedures described by Keli et al. ⁽Reference Keli, Andueza and de Vega¹⁹⁾ for analysis of faecal samples.

The isotope abundance (¹⁵N) of microbial N (LAB and SAB fractions) and non-NH₃ N (NAN) in the solid and liquid phases of duodenal samples was determined by MS (VG PRISM II; IRMS) connected in series to a Dumas-style N analyser (EA 1108 Carlo Erba) by the Interdepartmental Service for Research of the Universidad Autónoma de Madrid (SidI).

Other analytical procedures

The OM in feeds, refusals, faeces, rumen contents, whole duodenal digesta, solid phase of duodenal digesta and bacterial fractions was determined by ashing at 550°C for 8 h. Total N was determined following the Kjeldahl method using Se as a catalyst and a 2300 Kjeltec Analyzer Unit (Foss Tecator). The NDF in feeds, refusals, rumen contents, whole duodenal digesta, solid phase of duodenal digesta and faeces was measured with an ANKOM 220 Fiber Analyser (Ankom Technology) on dried samples (60°C for 48 h), as described by Mertens⁽Reference Mertens²¹⁾. The ADF and ADL in feeds were measured as described by Association of Official Analytical Chemists⁽²²⁾ (Association of Official Analytical Chemists Official Method 973.18) and Robertson & Van Soest⁽Reference Robertson, Van Soest, James and Theander²³⁾ for ADF and ADL, respectively. Both NDF and ADF were expressed as ash-free residues.

Concentration of VFA in rumen fluid was determined by GC following the method described by Jouany⁽Reference Jouany²⁴⁾. Deproteinised samples were centrifuged at 1800 g for 10 min, using 4-methylvaleric acid as an internal standard.

The NH₃ concentration in rumen fluid was determined by the colorimetric method developed by Chaney & Marbach⁽Reference Chaney and Marbach²⁵⁾.

The NAN in freeze-dried samples of whole digesta and the solid phase of the duodenal digesta was also analysed by the Kjeldahl method after evaporation of NH₃ following 1 M-NaOH addition. Samples were subsequently dried at 60°C for 48 h.

Calculation procedures

Degradation parameters of DM, CP and NDF of lucerne and ryegrass during rumen incubation were calculated following the model proposed by Ørskov & McDonald⁽Reference Ørskov and McDonald²⁶⁾, and using the non-linear regression procedure (PROC NLIN) of the SAS statistical package (version 8.1; SAS Institute).

Duodenal flow of DM and its fractions (including n-alkanes) was estimated from the concentration of Cr and Yb in the whole duodenal digesta and its solid fraction, following the procedures described by Faichney⁽Reference Faichney, McDonald and Warner²⁷⁾.

Faecal recovery of individual n-alkanes was calculated as the proportion of n-alkane consumed in the diet, which was excreted in the faeces. The concentration of a determined n-alkane in the ingesta was calculated as:

$$\begin{eqnarray} C _{I_{ i }} = \frac {(DMO_{L}\times C _{L_{ i }} + DMO_{RG}\times C _{RG_{ i }}) - (DMR\times C _{R_{ i }})}{DMO_{L} + DMO_{RG} - DMR}, \end{eqnarray}$$ $$

where DMO_L and DMO_RG are the amounts of lucerne and ryegrass (DM) offered, C _Li and C _RGi their concentrations in alkane i and DMR and C _Ri the amount of DM refused and its concentration in alkane i.

Duodenal recovery (DR) of n-alkanes was estimated as:

$$\begin{eqnarray} DR_{ i } = \frac { C _{TD_{ i }}\times F _{DM}}{ D _{ i } + ( I \times C _{I_{ i }})}, \end{eqnarray}$$ $$

where C _TDi represents the concentration of alkane i in the DM of duodenal true digesta, F _DM the duodenal flow of DM, D _i the amount of dosed alkane (if applicable), I the DM intake (DMI) and C _Ii the concentration of the alkane in the ingesta.

The diet composition was estimated by minimisation of the sum of the squared discrepancies between the measured faecal proportions of individual alkanes (recovery-corrected and expressed relative to the total faecal alkane; R) and diet alkane proportions (of the total alkane) calculated from alkane profiles of dietary components (E), as follows⁽Reference Mayes, Beresford and Lamb²⁸⁾:

$$\begin{eqnarray} \sum \left [ R - E \right ] _{alk:\,1\ldots n }^{2} = \sum \left [\frac { H _{ i }}{ H _{t}} - \frac { xA _{ i } + yB _{ i }}{ xA _{t} + yB _{t}}\right ] _{alk: \,1\ldots n }^{2}, \end{eqnarray}$$ $$

where x and y (1 − x) represent the proportions of components A and B in the diet; H _i, A _i and B _i the concentrations of alkane i in faeces (recovery-corrected) and components A and B; and H _t, A _t and B _t total alkane concentrations. The ‘Solver’ routine of the ‘Excel’ program (Microsoft) was used without non-negative restrictions⁽Reference Mayes, Beresford and Lamb²⁸⁾. Although all odd-chain alkanes were used in the first instance, the results presented in the present experiment only took account of the concentrations of C₃₁ and C₃₃, as those were the hydrocarbons that gave the best estimates, probably because they were found in higher concentrations in sheep faeces. The recovery correction factor of each alkane was estimated as the average from all animals for the balance trial faecal sampling.

The intake was calculated from the pair of alkanes C₃₁ (naturally present in the diet) and C₃₂ (dosed) as follows⁽Reference Mayes, Lamb and Colgrove⁶⁾:

$$\begin{eqnarray} I = \frac { D _{32}}{( F _{32}/ F _{31})\times I _{31} - I _{32}}, \end{eqnarray}$$ $$

where I is daily DMI (kg); D ₃₂ is amount of C₃₂ dosed daily (mg); and F ₃₁, F ₃₂, I ₃₁ and I ₃₂ are the concentrations of C₃₁ and C₃₂ in faeces and intake, respectively (mg/kg DM). The two latter were estimated from the calculated proportions of lucerne and ryegrass in the diet.

Digestibility of DM (DMD) was calculated using C₃₁ as the internal marker as follows:

$$\begin{eqnarray} DMD = 1 - \frac { I _{31}\times FR_{31}}{ F _{31}}, \end{eqnarray}$$ $$

where FR₃₁ represents the faecal recovery of the alkane, calculated as shown earlier.

Isotopic enrichment was calculated in all cases by difference in the tracer:tracee ratio (¹⁵N:¹⁴N) of labelled and background samples. Then, microbial contribution (Nmic) to duodenal flow of NAN (NAN_digesta) was calculated according to the following equation:

$$\begin{eqnarray} Nmic/NAN_{digesta} = E _{digesta}/ E _{bacteria}, \end{eqnarray}$$ $$

where E _digesta is the ¹⁵N enrichment of NAN in true digesta, and E _bacteria that of bacterial N, using LAB or SAB fraction as reference bacterial sample.

The efficiency of microbial protein synthesis (MPS) was calculated according to the equation:

$$\begin{eqnarray} Efficiency\ of\ MPS = \frac { F _{Nmic}}{OMADR}, \end{eqnarray}$$ $$

where F _Nmic is the microbial N flow (calculated as the flow of NAN multiplied per Nmic (mic-N/NAN_digesta)) and OMADR is the OM apparently digested in the rumen, calculated as the difference between OM intake (OMI) and OM flow at the duodenum. OM truly digested in rumen (OMTDR) was calculated as the sum of OMADR and the microbial OM flow, assuming a ratio N:OM in both SAB and LAB of 0·10⁽Reference Dove and Milne²⁹⁾).

The proportion of n-alkanes of bacterial origin (n-alkanes_bacteria) reaching the duodenum (only LAB fraction) was calculated as

$$\begin{eqnarray} n \hyphen alkanes_{bacteria} = \frac {\left (\frac { C _{ i }}{ N }\right )_{LAB}\times F _{NmicLAB}}{ F _{ i }}, \end{eqnarray}$$ $$

where C _i and N are the concentrations of alkane i (mg/kg DM) and N (g/kg DM) in LAB; F _NmicLAB is the duodenal flow of microbial N estimated from LAB (g/d); and F _i the flow of alkane i reaching the duodenum (mg/d).

The rate of disappearance of DM, OM, CP and NDF from the rumen (K) was calculated from hourly known intake of each fraction (F) and the corresponding rumen pool (V) as

$$\begin{eqnarray} K = \frac { F }{ V }. \end{eqnarray}$$ $$

Statistical analysis

All the results, except rumen degradation parameters, were subjected to ANOVA using the SAS statistical package (version 8.01; SAS Institute), according to the model:

$$\begin{eqnarray} y = \mu + D _{ i } + A _{ j } + P _{ k } + \varepsilon _{ l ( ijk )}, \end{eqnarray}$$ $$

where D _i (3 df) represents the diet effect, A _j (3 df) the animal effect, P _k (3 df) the effect due to the different periods of the latin square and ɛ_l(ijk) (6 df) the experimental error.

For rumen degradation, the model used was:

$$\begin{eqnarray} y = \mu + D _{ i } + A _{ j } + P _{ k } + H _{ l } + DH_{ il } + \varepsilon _{ m ( ijkl )}, \end{eqnarray}$$ $$

where D _i, A _j and P _k were as given earlier, H _l represented the effect due to the hay incubated (lucerne or ryegrass, 1 df), DH_il the interaction between diet and hay type (3 df) and ɛ_m(ijkl) (18 df) the experimental error. The diet effect was tested against P× A (D)_kj(i).

For comparisons between observed and n-alkanes' estimated values of intake and digestibility, the following split-plot model was used:

$$\begin{eqnarray} y = \mu + D _{ i } + A _{ j } + P _{ k } + AP_{ jk } + M _{ l } + DM_{ il } + \varepsilon _{ m ( ijkl )}, \end{eqnarray}$$ $$

where D _i, A _j and P _k were tested against the interaction AP_jk (6 df), whereas the method (M _l; observed or n-alkane estimated; 1 df) and the interaction between diet and method (DM_il; 3 df) were tested against the experimental error (ɛ_m(ijkl); 12 df)_.

The actual and alkane-estimated values of diet composition, intake and digestibility were further compared by means of paired t test for each diet type.

The PROC MIXED procedure was used for the aforementioned analysis, following the recommendations provided by Kaps & Lamberson⁽Reference Kaps and Lamberson³⁰⁾. As sheep for fistulation were chosen according to their weight and strength, animal was not modelled as a random effect. Where an effect was significant, polynomial contrasts were applied to check for linear, quadratic or cubic response to lucerne proportion in the diet. As the cubic component of the regression was not significant in any case, it will not be included in the tables. Differences between treatment means were evaluated by the Scheffe test, due to the appearance of missing values. The standard errors of means given in tables are weighted for the same reason. Comparison of rumen bacterial fractions (LAB and SAB) was made by a paired t test.

Relationships between digesta flows and intake and between the various components of digesta flow, were examined using either simple or multiple regressions. When both dependent and independent variables were flows, the regression was constrained through the origin. The PROC REG procedure of the SAS statistical package was used for this purpose.