Study area and experimental treatments

The study was conducted at the Laboratory of Animal Nutrition Department, Federal University of Agriculture, Abeokuta, Ogun State, Nigeria (7°13′N, 3°26′E 145 m a.s.l.). C. fistula leaves were freshly harvested at the premises of the University. The leaves were air-dried under a shade for 7 days to a constant moisture content level after that it was milled and made to pass through a 1 mm mesh sieve to form CFLP. Five concentrate diets were formulated to contain CFLP at 0 (CF0), 15 (CF15), 30 (CF30), 45 (CF45) and 60 (CF60) mg/g dry matter (DM) as presented in Table 1. Concentrate diets and guinea grass hay were combined at the ratio 4 : 6 and served as the substrate for the in vitro study.

Table 1. Ingredient composition (g/kg DM) of concentrate diet

CF0, 0 mg/g DM CFLP (−); CF15, 15 mg/g DM CFLP (+); CF30, 30 mg/g DM CFLP (++); CF45, 45 mg/g DM.

In vitro gas production study

The in vitro gas production study was carried out according to the procedure of Menke and Steingass (Reference Menke and Steingass1988). Rumen fluid was collected from six West African dwarf goats through the use of a suction tube as described by Babayemi and Bamikole (Reference Babayemi and Bamikole2006) before morning feeding (ethics number COLANIM/ACURC/022/010). The animals were fed with 0.40 concentrate feed and 0.60 guinea grass the previous day. The fluid was mixed, strained through four layers of muslin under a continuous flushing with carbon dioxide (CO₂). This served as a source of inoculum. Substrates (200 mg/g DM) which consisted of concentrate diets (CF0, CF15, CF30, CF45 and CF60) and guinea grass hay in the ratio 4 : 6 were weighed into 100 ml capacity glass syringes fitted with silicon tubes. Thereafter, 30 ml of incubation medium (consisting of buffer solution and rumen liquid in the ratio 2 : 1) was added. The syringes were tapped and pushed upwards by a piston to eliminate air in the inoculum. Controls (blanks) containing 30 ml buffered rumen fluid only were included in triplicates for correction of gas produced from rumen fluid due to the presence of small particles in the fluid. Each treatment was replicated ten times in a completely randomized design and gas produced was measured at 3 h intervals for 48 h. Total gas values were corrected for blank incubation by deducting the mean gas volume produced in the blank syringes from the volume of gas produced in the samples. However, gas volumes at 24 and 48 h of incubation periods were reported and considered very important in the current study as organic matter digestibility, metabolizable energy and short-chain fatty acids (SCFAs) of substrate incubated were calculated using the volume of gas produced at 24 h of incubation period according to Menke and Steingass (Reference Menke and Steingass1988) and Getachew et al. (Reference Getachew, Makka and Becker2002). Methane produced was determined from the final gas volume which was obtained at 48 h of incubation period based on the design of the study.

Estimation of methane gas from substrate incubated

At the end of incubation period (48 h), 4 ml of 10 m NaOH was introduced into three of the incubated syringes per treatment using a 5 ml syringe via the silicon tube just above the metal clip for methane production estimation. A heard of pop sound immediately the NaOH was introduced indicated the absorption of CO₂ and the remaining gas in the syringes was read as methane level (Fievez et al., Reference Fievez, Babayemi and Demeyer2005).

Chemical analysis

Proximate composition of C. fistula leaf, guinea grass hay, concentrate diet and incubated residues were analysed according to the procedure of AOAC (2000). Briefly, DM was determined by drying samples to a constant weight at 65°C for 48 h followed by equilibration in a desiccator. Nitrogen content of the samples was measured using the Kjeldahl procedure and the crude protein content was calculated by multiplying the nitrogen content by 6.25. Ash was determined by combustion using a muffle furnace at 550°C for 5 h until all carbon were removed. Ether extract was analysed using the soxhlet extraction method. Neutral and acid detergent fibres were determined according to Van Soest et al. (Reference Van Soest, Robertson and Lewis1991).

The total tannin content in C. fistula leaf was determined using the Folin–Ciocalteu method as reported by Makkar (Reference Makkar2003). Briefly, 0.25 ml Folin–Ciocalteu reagent (2 N) and 1.25 ml sodium carbonate solution (200 g Na₂CO₃/l) was added to an aliquot of the supernatant of the plant extract. Absorbance was read at 760 nm and a calibration curve was drawn for the tannic acid standard. Then, the concentration of total tannin was expressed as tannic acid equivalent (eq) in milligram per gram (mg/g) of dry plant materials weight.

The total phenol content was determined using the Folin–Ciocalteu colorimetric method according to the previously reported protocol (Do et al., Reference Do, Angkawijaya, Tran-Nguyen, Huynh, Soetaredjo, Ismadji and Ju-Hsu2014). The total phenolic content was expressed as gallic acid equivalent in milligram per gram (mg/g) of dry sample.

Flavonoid content was analysed following a modified aluminium chloride method as reported by Nasseri et al. (Reference Nasseri, Behravesh, Allahresani and Kazemnejadi2019). The flavonoid content was expressed as gallic acid equivalent (GAE) in mg/g of dry sample.

A method reported by Mir et al. (Reference Mir, Parihar, Tabasum and Kumari2016) was used for the saponin content determination. In this, 20 ml of diethyl ether was added to the extracted sample in a 250 ml separating funnel and was shaken vigorously. Then, 60 ml of n-butanol was added to the aqueous layer and was washed twice with 10 ml of 5% aqueous NaCl. The remaining solution was allowed to evaporate by heating in a water bath and later oven dried. The saponin content was calculated in percentage.

Alkaloid content was determined by the gravimetric method as outlined by Adeniyi et al. (Reference Adeniyi, Orjiekwe and Ehiagbonare2009). Here, few drops of concentrated ammonium hydroxide solution were added to the sample extract to precipitate the alkaloids. Then, the precipitate was recovered through a weighed filter paper and was then washed with 1% ammonium hydroxide solution. The filter paper containing the precipitate was oven dried at 60°C to a constant weight. Thereafter, the percentage of alkaloids was calculated.

In vitro DM and crude protein degradation of substrate

The fermentation residue was oven dried at 105°C overnight and digestibility coefficient of DM and crude protein is calculated thus:

$${\rm Digestibility}\,{\rm coefficient}\,{\rm of}\,{\rm dry}\,{\rm matter}\,( {{\rm D}{\rm M}_{\rm d}} ) = \displaystyle{{[ {{\rm D}{\rm M}_{\rm s}-( {{\rm D}{\rm M}_{\rm r}-{\rm D}{\rm M}_{\rm b}} ) } ] } \over {{\rm D}{\rm M}_{\rm s}}}$$

where DM_s = dry matter content of the substrate, DM_r = dry matter content of the residue and DM_b = dry matter content of the blank:

$${\rm Digestibiity}\,{\rm coefficient}\,{\rm of}\,{\rm crude}\,{\rm protein}\,( {{\rm C}{\rm P}_{\rm d}} ) = \displaystyle{{[ {{\rm C}{\rm P}_{\rm s}-( {{\rm C}{\rm P}_{\rm r}-{\rm C}{\rm P}_{\rm b}} ) } ] } \over {{\rm C}{\rm P}_{\rm s}}}$$

where CP_s = crude protein content of the substrate, CP_r = crude protein content of the residue and CP_b = crude protein content of the blank.

Metabolizable energy, organic matter digestibility and SCFAs of the substrate incubated

Volume of gas produced at 24 h of incubation period was used as an index to calculate the metabolizable energy, organic matter digestibility and SCFAs of the substrate as follows:

$$\eqalign{& {\rm ME}\,( {{\rm MJ}/{\rm kg}} ) = 2.20 + 0.136{\rm GV} + 0.057{\rm CP} + 0.0029( {{\rm CF}} ) ^2\,\, \cr & \qquad\qquad\qquad \,\, ( {{\rm Menke}\,{\rm and}\,{\rm Steingass}, \;\,1988} ) \cr & {\rm OMD}\,( \% ) = 14.88 + 0.889{\rm GV} + 0.45{\rm CP} + 0.651{\rm A}\,\, \cr & \qquad\qquad\quad \,\,( {{\rm Menke}\,{\rm and}\,{\rm Steingass}, \;\,1988} ) \cr & {\rm SCFA}\,( {{\rm \mu mol}/{\rm g}\,{\rm DM}} ) = 0.0239{\rm GV}\ndash 0.0601\,\, \cr & \qquad\qquad\qquad\qquad \,\,\,\,\,\,\,\, ( {{\rm Getachew}\,et\,al., \;\,2002} ) } $$

where GV = gas volume at 24 h of incubation period; CP = crude protein of the substrate (g/kg DM), CF = crude fibre (g/kg DM) and A = Ash content of the substrate (g/kg DM).

Determination of pH, ammonia-nitrogen and total volatile fatty acid (TVFA) concentrations of the incubated fluid

At the end of the incubation period, the pH of the incubation fluid was immediately determined using a pH meter (PH-200 model). Ammonia-nitrogen (NH₃-N) concentration of the fluid was determined using the steam distillation procedure (Ogubai and Sereke, Reference Ogubai and Sereke1997). A 10 ml conc. NaOH was added to 10 ml rumen fluid under a Kjeldahl distillation system. The released ammonia was collected in boric acid solution and the distillate was titrated against a standard acid (0.1 N HCl). Concentration of ammonia-nitrogen in the fluid was then calculated. TVFA concentration was determined using Markham apparatus as described by Barnett and Reid (Reference Barnett and Reid1956). The procedure involved addition of 2 ml rumen fluid to 1 ml of 10% potassium oxalate buffer and 1 ml oxalic acid injected into the Markham apparatus and a 100 ml distillate was collected which was subsequently titrated against a standard 0.01 N NaOH with two drops of phenolphthalein as an indicator:

$${\rm N}{\rm H}_3 \hbox{-}{\rm N}\,( {{\rm mg}/{\rm dl}} ) = \displaystyle{{{\rm HCl}\,{\rm normality} \times {\rm HCl}\,{\rm volume} \times 100} \over {{\rm rumen}\,{\rm fluid}\,{\rm volume}}}$$

$${\rm TVFA}\,\,\;( {{\rm mM}} ) = \displaystyle{{[ {{\rm NaOH}\,{\rm volume} \times {\rm NaOH}\,{\rm normality}} ] } \over {{\rm rumen}\,{\rm inoculum}\,{\rm volume}}} \times 1000$$

Statistical analysis and model

All data obtained were subjected to one-way analysis of variance in a completely randomized design using the generalized linear model of SAS (2014). Orthogonal polynomial contrasts were used to examine the linear and quadratic effects of the increasing level of CFLP with the same statistical procedure. The significance level was set at P < 0.05. The mathematical model for the study is as follows:

$$Y_{ij} = \mu + T_i + \Sigma _{ij}$$

where Y_ij = observed values of dependent variables, μ = population mean, T_i = effect of different levels of CFLP and Σ_ij = random residual error, P < 0.05.