Effects of non-enzymatic browning reaction intensity on in vitro ruminal protein degradation and intestinal protein digestion of soybean and cottonseed meals

The effects of non-enzymatic browning reactions on in vitro ruminal gas production and in vitro ruminal and intestinal crude protein (CP) digestibilities of soybean (SBM) and cottonseed (CSM) meals were investigated. Non-enzymatically browned SBM and CSM samples were prepared using two xylose levels (10 or 30 g/kg dry matter), two heating lengths (30 or 60 min) and two heating temperatures (120 or 150 °C) for a total of one untreated (commercially solvent-extracted, Control) and eight treated samples for each protein source. The control SBM had higher (P<0.001) in vitro ruminal CP degradability values than the treated samples. Intestinal protein digestibility and total-tract CP digestibility of CSM and SBM were affected by the treatment (P<0.01). The results of the study indicate that not only ruminal CP degradability is reduced but also intestinal and total-tract CP digestibilities may be lowered depending on protein source and intensity of the non-enzymatic browning reaction.     

Interpretation of rumen degradability of concentrate feeds with a Gompertz model

An investigation of the kinetics and synchronicity of rumen crude protein and starch degradability was performed for maize, flaked maize, ensiled maize cob, barley, flaked barley, wheat, oat, sorghum and triticale grain, using the in situ polyester bag technique. Kinetics of rumen degradability were corrected for particle losses from the bag before degradation. Washing losses were measured by shaking feed samples in polyester bags in tap water at 20°C for 1 h and recovering the particle losses in fibre glass filter. Mean washing losses of dry matter were 442 g/kg DM (soluble fraction 17%); mean washing losses of nitrogen were 446 g/kg nitrogen, with 52% being water soluble. Starch escaped to a higher extent from the bags in the washing machine (average washing losses were 581 g/kg starch, with a soluble fraction of 7%). Degradability data for dry matter, nitrogen and starch measured at each time of incubation were corrected for the respective particle losses and fitted with both first order and Gompertz (sigmoidal) models. The difference between the estimated parameters obtained with the two models was negligible, although differences occurred for the immediately soluble fraction (a) of dry matter and starch and for total degradable fractions of dry matter, nitrogen and starch. No differences were observed between effective degradabilities, independent of rumen outflow rate (0.04 and 0.08/h), apart for the mean effective degradability of nitrogen at 0.08/h, which was higher for the first order model (577 versus 564 g/kg, P < 0.001). The advantage of using the Gompertz model to interpret the kinetics of rumen degradability of cereals was due to the possibility of studying synchronicity of nitrogen and starch released into the rumen and ranking feeds according to their degradability pattern, which required the calculation of the first derivatives of the Gompertz model for nitrogen and starch and weighted for their respective amounts in the feeds. The difference of these ratios from the optimum value of 30 mg N per 1 g starch gives the instantaneous synchronicity of the cereals. Maize, flaked maize, maize cob and sorghum had negative and almost constant values during the first 8 h of incubation. Barley, flaked barley, wheat, triticale and oat changed from an initially negative value to a positive value from about 4 h onwards; oats had a similar pattern, but a positive value was observed only after 6 h.     

Effect of moist heat treatment on in-vitro degradability and ruminal escape protein and amino acids of mustard meal

A study was conducted to determine the effects of moist heat treatment (127°C, 117 kPa steam pressure) for 10 min on protein fractions and in-vitro crude protein (CP) degradability of mustard meal. Rumen undegraded protein (RUP) and amino acid disappearance of unheated, and heated, mustard meal were measured following 12 h of rumen incubation using two ruminally fistulated cows. Intestinal availability of RUP was estimated using an enzymatic (pepsin–pancreatin) procedure. Heat treatment reduced (p<0.05) protein solubility and increased (p<0.05) neutral detergent insoluble CP without affecting acid detergent insoluble CP of mustard meal. Relative to the control, heated mustard meal had a lower (p<0.05) effective in-vitro CP degradability (445.2 vs. 746.8 g kg⁻¹ of CP) and a higher (p<0.05) ruminal escape CP (615.1 vs. 120.2 g kg⁻¹ of CP) value. Amino acid composition was not affected by heat treatment except for the concentration of arginine and lysine which was lower (p<0.05) in heated than in unheated mustard meal. Disappearance of all amino acids following 12 h of rumen incubation was lower (p<0.05) in unheated than in heated mustard meal. Heat treatment increased (p<0.05) the amount of protein available for digestion in the small intestine from 75.7 to 518.1 g kg⁻¹ of CP. It was concluded that moist heating of mustard meal for 10 min will reduce ruminal CP and amino acid degradability without compromising the intestinal availability of ruminal undegraded protein.     

In vitro evaluation of the fermentation characteristics of the carbohydrate fractions of hulless barley and other cereals in the gastrointestinal tract of pigs

An in vitro model was used to study the fermentation characteristics of carbohydrate fractions of hulless barley (hB), in comparison to hulled barley (HB), hulled oat and oat groats (OG) in the pig intestine. For this purpose, 6 hulless barley cultivars (hB), varying in β-glucan content (36–99 g/kg DM), were compared to 3 HB cultivars, 2 oat groat samples (OG), 3 oat varieties and a reference sample of wheat. The residue of a pepsin–pancreatin hydrolysis was incubated in a buffered mineral solution inoculated with pig faeces. Gas production, proportional to the amount of fermented carbohydrates, was measured for 48 h and kinetics modelled. The fermented solution was subsequently analyzed for microbial production of short-chain fatty acids (SCFA) and ammonia. In vitro dry matter degradability varied according to ingredient (P<0.001). Higher values were observed for OG, ranging from 0.88 to 0.99 as compared to oat, hB and HB, for which degradability ranged from 0.63 to 0.73, 0.68 to 0.80 and 0.69 to 0.71, respectively. A “cereal type” effect (P<0.05) was observed on fermentation kinetics parameters. Total gas production was higher (P<0.05) with hB (224 ml/g DM incubated) than with HB and oat (188 and 55 ml/g DM incubated, respectively). No difference was observed between hB cultivars (P>0.05) for total gas production but differences (P<0.001) were found for lag time and the fractional rate of degradation. Hulless barley cultivar CDC Fibar (waxy starch) and CDC McGwire (normal starch) started to ferment sooner (lag time of 0.7 and 0.9 h, respectively) than SH99250 (high amylose starch; 1.7 h). The fractional rate of degradation was similar in both hB and OG (0.15/h on average), which was higher than that of HB (0.12/h). The production of SCFA was also higher (P<0.05) with hB (6.1 mmol/g DM incubated, on average) than with HB and oat (4.9 and 2.9 mmol/g DM incubated, respectively). Similar trends were found for SCFA production expressed per g fermented carbohydrates, with higher butyrate and lower acetate ratio. In contrast, oat fermentation generated higher (P<0.05) ammonia concentration (1.4 mmol/g DM incubated, on average) than hB (1.0 mmol/g DM incubated). In summary, hulless barleys, irrespective of cultivar type had higher in vitro fermentability and produced more SCFA and less ammonia than hulled barley and oat. Thus, hulless barleys have a better potential to be used in pig nutrition to manipulate the fermentation activity in the intestine of pigs.     

Intake and digestion by lambs of dwarf elephant grass (Pennisetum purpureum Schum. cv. Mott) hay or hay supplemented with urea and different levels of cracked corn grain

This study was carried out to evaluate intake, digestibility, ruminal fermentation, nitrogen (N) retention and ruminal microbial protein synthesis in lambs fed dwarf elephant grass (Pennisetum purpureum Schum. cv. Mott) hay or hay supplemented with urea and 0, 5, 10 or 15 g/kg of live weight (LW) of cracked corn grain. Ten lambs (mean LW of 28 ± 0.9 kg), housed in metabolic cages, were used in a double 5 × 5 Latin Square experiment. Except fibre intake and digestibility, which was higher, the intake and digestibility of the others feed components, as well as ruminal microbial protein synthesis and N retention were lower in non-supplemented lambs. Corn supplementation increased total dry matter (DM) (P<0.05), organic matter (OM), non-structural carbohydrate (NSC) and energy intake (P<0.01) but decreased total neutral detergent fibre (aNDFom) (P<0.01) intake, as well as OM and aNDFom intake from the hay (P<0.01). Apparent DM, OM and energy digestibility, as well as OM true digestibility (OMTD) increased (P<0.01), and aNDFom digestibility decreased linearly (P<0.01) as corn supplementation increased. Total N intake was not influenced but, apparent and true N digestibility, as well as urinary N excretion decreased (P<0.01), and ruminal microbial N entering the small intestine increased linearly (P<0.01) as corn supplementation increased. However, the efficiency of ruminal microbial protein synthesis was similar for all treatments. Mean ruminal pH values and ammonia N concentrations decreased linearly (P<0.01) with level of corn supplementation. Ammonia N and amino acid, as well as peptide concentrations in ruminal fluid were quadratically related (P<0.01) with the time after feeding. Corn supplementation had a linear additive effect on total dry matter and digestible energy intake, as well as on N retention, but a linear negative effect on hay intake and on fibre digestibility. However, decreased forage digestibility by animals was probably neither related to lower ruminal pH, which values were always higher than 7.0, nor related to ruminal sugar concentrations, which were similar for all treatments.     

Effects of type of ionophore and carrier on in vitro ruminal dry matter disappearance,gas production,and fermentation end products of a concentrate substrate

Effects of ionophore type and carrier on in vitro ruminal digestion and fermentation patterns of a concentrate substrate were evaluated at various incubation times. Treatments were: control (no ionophore); lasalocid sodium commercial premix (Bov); lasalocid sodium mycelium cake (LasBio); laidlomycin sodium salt (LaidNa); laidlomycin propionate commercial premix (LaidPro); monensin sodium salt (Mon); and monensin sodium commercial premix (Rum). The Bov, LasBio, Mon, and Rum treatments supplied 4 μg of ionophore/mL of culture volume, whereas the LaidNa and LaidPro treatments supplied 1.33 μg of ionophore/mL. Total gas and methane production did not differ among treatments at any of the incubation times (P>0.09). Similarly, in vitro dry matter disappearance (IVDMD) was not affected by treatment (P>0.28) at 6, 18, and 24 h of incubation; however, IVDMD (P=0.03) was greater for ionophores than for the control at 12 h of incubation. Molar proportions of acetate (P<0.01), acetate:propionate (P<0.01), and total volatile fatty acid (VFA) concentrations (P<0.01) were decreased and propionate was increased (P<0.001) for the average of all ionophore-containing substrates compared with the control. Total VFA were decreased by Bov, LaidNa, and Rum, contrasted with their specific counterparts (LasBio, LaidPro, and Mon, respectively; P<0.05). Differences were detected among ionophore types for acetate (lasalocid vs. laidlomycin; P<0.05), propionate (lasalocid vs. monensin; P<0.05), and butyrate (monensin vs. lasalocid or laidlomycin; P<0.05). Capture of metabolic hydrogen in end products of fermentation was greater for ionophore-containing treatments (P<0.01) than for the control. These data suggest limited unique effects of ionophore type or carrier on IVDMD, total gas production, and methane; however, VFA proportions varied among ionophore types and carriers, which deserves further study.     

Utility of buckwheat (Fagopyrum esculentum Moench) as feed: Effects of forage and grain on in vitro ruminal fermentation and performance of dairy cows

Buckwheat is of high value in crop rotations and overall agricultural ecology because of strong rooting and intensive flowering properties, but it is rarely cultivated and information on its nutritional value to ruminants is scarce. The contents of net energy for lactation (NEL), as estimated with the Hohenheim Gas Test (n = 3), were 4.3, 4.9 and 7.5 MJ NEL/kg dry matter (DM) for fresh and ensiled whole buckwheat plants and buckwheat grain, respectively. In two experiments with the Rumen Simulation Technique (Rusitec), ruminal fermentation characteristics of buckwheat forages and buckwheat grain (n = 4/diet) were evaluated. In the first experiment, 0, 300 or 600 g/kg of a pure hay diet were replaced by either fresh or ensiled buckwheat to create five diets. Neither form of buckwheat forages had effects on in vitro ruminal degradability and short chain fatty acid (SCFA) concentrations and composition. The use of fresh buckwheat reduced ruminal ammonia concentrations and enhanced estimated microbial N growth efficiency. These differences did not occur with silage, indicating a change in nutritional value by ensiling. Fresh buckwheat reduced the number of bacteria in the incubated fluid, while ensiled buckwheat reduced that of holotrich protozoa. Methane formation was not influenced by the buckwheat forages. In the second experiment, wheat meal (400 g/kg dietary DM), was replaced stepwise (0.5 and 1.0) by buckwheat grain meal. This did not cause differences in parameters of nutrient degradability, relative N efficiency and total amount and composition of SCFA. Holotrich protozoa counts increased, but total gas formation decreased with increasing dietary level of buckwheat grain. In a final experiment, cows yielding about 40 kg milk/day were fed mixed silage-concentrate diets (n = 4). A control diet contained no buckwheat. In a second diet, maize silage was partly substituted by buckwheat silage (98 g/kg dietary DM). In a third group, part of the energy concentrate was substituted by buckwheat grain meal (94 g/kg). There were no effects on feed intake, milk yield and milk composition. Buckwheat proved to be a plant that offers different feeds of a quality sufficient to be considered suitable in ruminant nutrition.     

Nutritional characterization of Mucuna pruriens: 3. Effect of replacing soybean meal with Mucuna on intake,digestibility, N balance and microbial protein synthesis in sheep

Mucuna pruriens seeds have relatively high crude protein (CP) concentrations, but little is known about their potential to replace commonly used CP supplements in ruminant rations. The aim of this experiment was to determine effects of replacing soybean meal (SB) with Mucuna on the performance of lambs. Forty Rambouillet lambs (33.2 ± 5.73 kg) fed a basal diet of maize grain, cottonseed hulls and urea were randomly assigned to one of four supplements formulated by substituting 0 (SB), 330 (Lo), 670 (Med) or 1000 g/kg (Hi) of soybean meal with rolled Mucuna seeds. Lambs were housed individually in metabolic crates and allowed ad libitum access to isocaloric (metabolizable energy=11.7 MJ/kg dry matter, DM) and isonitrogenous (CP = 146 g/kg, DM) diets for 14 d of adaptation and 7 d of total fecal collection. Fecal egg counts and coccidian oocyst scores were determined on d 14. Dry matter intake (1.7 kg/d versus 1.5 kg/d; P<0.05), CP digestibility (774 g/kg versus 714 g/kg DM; P<0.05) and N retention (28.0 g/d versus 20.4 g/d; P<0.01) were higher and amylase-pretreated neutral detergent fiber digestibility (617 g/kg versus 686 g/kg DM) was lower (P<0.05) in sheep fed SB versus Mucuna diets. However, supplementary protein source did not affect rumen pH, blood urea N or glucose concentration, or fecal egg counts. Increasing the level of Mucuna supplementation increased (P<0.05) level and efficiency of microbial protein synthesis, ruminal fluid acidity, total volatile fatty acid concentration, decreased (P<0.05) coccidian oocyst scores, and tended (P<0.10) to increase N retention. Therefore, SB is a better supplement than Mucuna to support performance of lambs. Nevertheless, Mucuna seeds are a promising CP supplement for situations where cost or availability precludes use of SB in ruminant rations.     

In vitro estimations of the rate and extent of ruminal digestion of starch-rich feed fractions compared to in vivo data

An experiment was conducted to study the rumen digestion characteristics of whole feeds (WF) and the neutral detergent fibre (aNDF) and neutral detergent soluble (NDS) fractions of a range of starch-rich feeds using an automated in vitro gas production (GP) technique. In addition, the ruminal digestibility values predicted from the GP data were compared to previously acquired in vivo data. Nine feeds with starch concentrations ranging from 389 to 712 g/kg dry matter and with known in vivo digestibilities were subjected to neutral detergent extraction. The GP for each WF and the corresponding aNDF fractions were measured in duplicate in buffered rumen fluid during 72 h on two occasions. The fermentation residues were collected and analyzed for aNDF concentration to estimate their true organic matter (OM) and NDF digestibility. The GP from the NDS fraction was calculated by subtracting the GP from the aNDF fraction from the GP of the WF. A three-pool Gompertz model was fitted to the GP profiles (R² = 0.99) and a two compartment, mechanistic and dynamic rumen model was used to predict the digestibility of the potentially digestible feed fraction and the effective digestion rate (k_d). The true OM and NDF digestibility determined for the WF ranged from 0.804 to 1.011 and from 0.362 to 1.107, respectively. The NDF digestibility determined for the aNDF fraction ranged from 0.410 to 0.985. The effective k_d values estimated using GP data varied from 0.118 to 0.282/h for the WF and from 0.123 to 0.301/h for the NDS fraction, and were less (P<0.05) for maize compared to small grains (SG) but did not differ between barley and wheat (P>0.05). The effective k_d values for the aNDF fraction ranged from 0.039 to 0.082/h and did not differ (P>0.05) either between maize and SG or between barley and wheat. The predicted ruminal NDS digestibility determined using GP data closely matched the in vivo data describing starch digestion (R² = 0.81). The effective k_d values for the WF were strongly related (R² = 0.94) to those for the NDS fractions. The results indicate that when measured with the GP technique, the differences in the digestion characteristics of maize and small grains are less than those previously reported in studies using the in situ method. It is concluded that the predicted NDS digestibility determined using GP data corresponded well to the in vivo starch digestibility. Our results also suggest that the first order digestion rates of NDS (starch) in starch-rich feeds can be accurately determined by incubating WF samples in the GP system and using the GP kinetic data in a dynamic, mechanistic rumen model.     

Effects of exogenous enzymes on in vitro gas production kinetics and ruminal fermentation of four fibrous feeds

This study was conducted to investigate effects of increasing doses: 0 (control), 6 (low), 12 (medium) and 24 (high) mg/g DM of ZADO^® enzyme preparation mixture (ENZ) on in vitro gas production (GP) and some ruminal fermentation parameters of the fibrous feeds Saccharum officinarum (leaves), Andropogon gayanus (leaves), Pennisetum purpureum (leaves) and Sorghum vulgare (straw). Rumen liquor was obtained from two Brown Swiss cows fitted with permanent rumen cannulae fed a total mixed ration of a 500:500 commercial concentrate and alfalfa hay ad libitum. The GP was recorded at 2, 4, 6, 8, 10, 12, 24, 48, 72 and 96 h of incubation. After 96 h, the incubation was stopped and the pH of the mixture was determined and filtrate used to determine dry matter degradability (DMD), partitioning factor (PF₉₆), gas yield (GY₂₄), in vitro organic matter digestibility (OMD), metabolizable energy (ME), short chain fatty acids (SCFA), and microbial crude protien production (MCP). In general, the crude protein (CP) content of the fibrous feeds was low and ranged from 23 g/kg DM (S. officinarum) to 44 (A. gayanus). The fibre contents (i.e., NDFom and ADFom) were highest (P<0.05) in S. officinarum. Increasing ENZ dose linearly increased (P<0.05) GP of all fibrous feeds and had a quadratically increased (P<0.05) asymptotic gas production in P. purpureum and S. vulgare and rate of gas production in S. officinarum and S. vulgare. Addition of ENZ also quadratically increased (P<0.05) GP at all incubation times in S. officinarum and S. vulgare, and A. gayanus, but only at 72 h in A. gayanus. The parameters of ruminal fermentation of OMD, ME, GY₂₄ and SCFA linearly increased (P<0.05) and MCP linearly decreased (P<0.05) with the ENZ addition. Addition of enzyme affected ruminal fermentation of our feeds differently, mainly dependent on their fibre content, although dosage of enzyme was also important as impacts generally increased at higher dosages of ENZ.     

Effects of supplemental urea sources and feeding frequency on ruminal fermentation,fiber digestion,and nitrogen balance in beef steers

The objective of two experiments was to evaluate non-protein N supplementation with protected urea sources in terms of rumen fermentation products, nutrient digestibility, and N balance in ruminally fistulated beef steers (initial bodyweight 239 ± 18 kg) fed switchgrass hay. Experiment 1 compared urea with Optigen II^®, and Experiment 2 compared urea with RumaPro^®. In both experiments, supplements (400 g/kg of daily dietary dry matter) were fed once daily or every 2 h in a balanced design. Supplements contained soybean hulls, corn grain, vitamins, and minerals as well as non-protein N sources. Non-protein N provided 0.18 g/g of dietary N. Switchgrass hay was fed once daily, at the same time as the supplement in the once-daily treatments. Dry matter intake (4.1 kg/d in Experiment 1, 4.5 kg/d in Experiment 2), dry matter digestibility (P<0.25, 0.58 ± 0.014 g/g in Experiment 1, 0.58 ± 0.010 g/g in Experiment 2), N balance (P<0.83, 11.3 ± 1.9 g/d in Experiment 1, 11.8 ± 3.6 g/d in Experiment 2), ruminal ammonia concentrations (P<0.29, 15.2 ± 1.4 mM in Experiment 1, 11.8 ± 0.6 mM in Experiment 2), and ruminal short-chain fatty acid concentrations (P<0.13, 77.7 ± 3.0 mM in Experiment 1, 75.4 ± 3.0 mM in Experiment 2) were not affected by feeding protected urea sources. Providing a steady supply of ruminally degradable N by feeding supplement every 2 h vs once daily decreased ruminal ammonia concentrations by approximately one-half by 4 h after feeding hay (P<0.01 in both experiments) and increased (P<0.02 in Experiment 1, P<0.08) in Experiment 2) apparent digestibility of dry matter (0.58–0.62 in Experiment 1, 0.56–0.61 in Experiment 2) and dietary fiber components.     

Impact of variability in fishmeal physicochemical properties on the extrusion process,starch gelatinization and pellet durability and hardness

The purpose of this study was to identify physicochemical properties of fishmeal (FM) with impact on specific mechanical energy, starch gelatinization, pellet durability and pellet hardness. The effects of variation in 18 physicochemical properties were assessed based on standardized extrusion, drying and coating conditions. Multivariate models (R² = 0.907–0.970) were established based on partial least squares regression. Increased level of specific mechanical energy was associated with decreased water-holding capacity (P=0.008), decreased cumulative mean particle size (P=0.020), increased value of flow-figure (P<0.001), increased degree of protein hydrolysis (P<0.001) and increased level of the water soluble protein fraction with molecular weight less than 0.2 kDa (P=0.022). Improved degree of starch gelatinization was associated with decreased water-holding capacity (P<0.001) and increased degree of protein hydrolysis (P<0.001). The variation in FM physicochemical properties resulted in a large span in pellet hardness (4.9–133.4 N) covering the range from poor to high physical quality. Improved hardness was associated with decreased water-holding capacity (P=0.069), decreased pH (P=0.001), decreased level of non-soluble protein (P<0.001), increased level of salt (P=0.002), and increased level of the water soluble protein fractions with molecular weight 5–6 kDa (P<0.001), 20–35 kDa (P<0.001) and above 60 kDa (P=0.006). The underlying physical and chemical mechanisms are discussed. The study documents the complexity of FM as a protein ingredient with significant impact on the extrusion process, starch gelatinization and physical pellet quality. The FM specifications normally used on the world commodity market inadequately describe the technical quality of a FM.     

Ruminal large and small particle kinetics in dairy cows fed red clover and grass silages harvested at two stages of growth

Passage, comminution and digestion rates of large and small particles were estimated using a rumen evacuation technique and total faecal collection with five lactating dairy cows in a 5 × 5 Latin square experiment. Two grass and two red clover silages harvested at early and late primary growth stages and a 1:1 mixture of late harvest grass and early harvest red clover were the dietary treatments. Cows received 9.0 kg supplementary concentrate per day. Ruminal contents and faeces were divided into large (>1.25 mm) and small (1.25–0.038 mm) particles by wet sieving. Indigestible neutral detergent fibre (iNDF) was determined by 12 days ruminal in situ incubation followed by neutral detergent extraction. Plant species did not affect ruminal particle size distribution, whereas advancing forage maturity decreased the proportion of large particles for both grass and red clover silage diets. Ruminal pool size of iNDF was higher (P<0.001) with red clover compared to grass silage diets. Ruminal passage rates of iNDF and potentially digestible NDF (pdNDF) increased with decreasing particle size (P<0.01). Passage rate of iNDF for small particles was slower (P<0.01) when red clover compared to grass silage diets were fed. Particle comminution rate in the rumen was slower (P<0.001) with red clover compared to grass silage diets and it increased (P<0.01) with advancing forage maturity. The contribution of particle comminution to ruminal mean retention time of iNDF in the ruminal large particle pool was smaller (P<0.01) in red clover compared to grass silage diets and it increased (P<0.05) with the mixed silage compared to the separate silages. Passage rate of pdNDF for both large and small particles was not affected by dietary treatments. Digestion rate of pdNDF for large particles was faster (P<0.001) with red clover compared to grass silage diets. Differences in ruminal passage and digestion rates of the large and small particles, in addition to differences in the passage and digestion rates of red clover compared to grass silage diets, emphasize the need to consider particle size and forage type in metabolic models predicting feed intake and fibre digestibility in ruminants.     

Assessment of the efficacy of varying experimental exogenous fibrolytic enzymes using in vitro fermentation characteristics

This study evaluated a series of recombinant, single activity experimental enzyme products including 13 endoglucanases (END) and 10 xylanases (XY), for their potential to improve in vitro ruminal degradation of alfalfa hay in two experiments. Based on the endoglucanase or xylanase enzymatic activities measured using complex substrates at the optimal conditions (pH 5.4, 37 °C) for the enzymes, a dose level (1 unit/g dry matter [DM]) was chosen for addition of enzymes to substrate. Enzyme products, re-suspended with water, were added to alfalfa hay (0.5 or 1.0 g DM) in culture vials in six replications. Anaerobic buffer medium (20 or 40 ml) adjusted to pH 6.0 and strained ruminal fluid (5 or 10 ml) were sequentially added to the vials and incubated for 18 h. Headspace gas production (GP) was measured throughout the incubation, and degradability of organic matter (OMD) and fibre and volatile fatty acid (VFA) concentrations were determined after 18 h of incubation. The enzyme products had a wide range of added endoglucanase or xylanase activities when determined using pure substrates and physiological conditions typical of the rumen (pH 6.0, 39 °C). In experiment 1, many END, and some XY, products increased GP and OMD. The correlation between added endoglucanase activity determined at ruminal conditions and OMD improvement was high (r = 0.71; P<0.01), whereas added activity of xylanase was not associated with OMD improvement. Two END and two XY products selected from experiment 1 were further assessed because they substantially improved GP and OMD. In experiment 2, all enzyme treatments, alone or in combination, increased total GP and DM and fibre degradabilities (P<0.05). However, the combinations of END and XY did not increase degradation of alfalfa beyond that of the component enzymes. Total VFA production was not affected by enzyme treatments although some products changed the acetate to propionate ratio. Experimental exogenous enzyme products with either endoglucanase or xylanase activity substantially improved in vitro ruminal degradation of alfalfa hay, but further improvement by combining these activities did not occur.     

Effect of peppermint (Mentha piperita) oil on in vitro methanogenesis and fermentation of feed with buffalo rumen liquor

The effect of inclusion of peppermint (Mentha piperita) oil (at 0, 0.33, 1.0 and 2.0 μl/ml of incubation medium) on gas and methane production, fermentation of feed and microbial profile was studied in in vitro gas production test, using 200 mg of wheat straw and concentrate mixture in equal proportion as substrate in a 100 ml graduated syringe. The buffalo rumen liquor was used as inoculum and the observations were recorded at 24 h of incubation. Methane emission was reduced (P<0.001) by 19.9%, 46.0% and 75.6% at 0.33, 1.0 and 2.0 μl levels, respectively. The concentration (mM/100 ml) of total volatile fatty acids was reduced (P<0.01) by inclusion of peppermint oil at higher levels (1.0 and 2.0 μl) whereas at 0.33 μl level there was no effect. The proportion of acetate increased (P<0.05) and that of propionate decreased (P<0.001) at 1.0 and 2.0 μl levels of peppermint oil. There was a fall (P<0.001) in carboxymethylcellulase and xylanase activities and the inhibition increased with the increasing level of peppermint oil which resulted in a dose dependent decrease (P<0.05) in in vitro true digestibility of feed. At 0.33 μl level of peppermint oil, the population density of total bacteria was similar to that of control but fungi, Ruminococcus flavefaciens and methanogens increased by 4-, 6- and 2-folds, respectively, as determined with real-time PCR. At 1.0 and 2.0 μl levels the population density of total bacteria, fungi, Fibrobacter succinogens and methanogens decreased drastically and fell below the control values. The numbers of holotrichs and spirotrichs were reduced (P<0.001) by increasing dose of peppermint oil. The higher doses of peppermint oil were toxic for the rumen microbes but the lower levels could be further explored in in vivo experiments as rumen modifier to reduce methanogenesis.     

Effect of elemental nano-selenium on feed digestibility,rumen fermentation,and purine derivatives in sheep

The objective of this experiment was to study the effect of elemental nano-selenium (NS) on feed digestibility, rumen fermentation, and urinary purine derivatives in sheep. Eight male ruminally cannulated sheep (42.5 ± 3.2 kg of body weight, BW) were used in a replicated 4×4 Latin square experiment in four 20 day periods. Depending on treatment designation, sheep were fed the basal diet supplemented with 0 (control), 0.3, 3 and 6 g of nano-Se/kg dry matter (DM). Ruminal pH (range of 6.68–6.80) and ammonia N concentration (range of 9.95–12.49 mg/100 mL) was decreased (P<0.01), and total VFA concentration (range of 73.63–77.72 mM) was increased linearly (P<0.01) and quadratically (P<0.01) with increasing nano-Se supplementation. The ratio of acetate to propionate was linearly (P<0.01) and quadratically (P<0.01) decreased due to the increasing of propionate concentration. In situ ruminal neutral detergent fiber (aNDF) degradation of Leymus chinensis and crude protein (CP) of soybean meal were linearly (P<0.01) and quadratically (P<0.01) improved by feeding nano-Se. Similarly, nutrients digestibility in the total tract and urinary excretion of purine derivatives were also quadratically (P<0.01) changed by increasing nano-Se supplementation. The present results indicated that nano-Se supplementation in basal diet improved rumen fermentation and feed utilization. Nano-Se could also stimulate rumen microbial activity, digestive microorganisms or enzyme activity. The optimum dose of nano-Se was about 3.0 g/kg dietary DM in sheep.     

The effect of variety on maize grain and crop residue yield and nutritive value of the stover

Eight varieties of maize, namely Awassa 511 (A511), Birkata, composite of best families (CBF), Dendane, drought tolerant population (DTP1), Guto, Katumani and Keroshet planted in 1995 cropping season were compared for grain and crop residue yield and nutritive value of the stover. Significant differences (p < 0.05) were observed in grain and crop residue yields of the varieties. Grain yield was highest (6.99 t ha⁻¹) in DTP1 and lowest (2.21 t ha⁻¹) in Keroshet. Stover and total crop residue yields were significantly higher (p < 0.05) in A511 than in CBF and Dendane. The stem was the largest portion in the stover varying from 31% in Dendane to 50% in A511. The stover of Birkata showed a high crude protein (CP) and low ash and fibre contents compared to the other varieties. The CP content varied from 28 g kg DM⁻¹ (Guto) to 61 g kg DM⁻¹ (Birkata). Crop residue yield and quality parameters, except CP content of the stover, were not negatively correlated with grain yield. The potential utility index varied from 61% (Keroshet) to 74% (CBF). The varieties with higher potential utility indices, except Guto, also had relatively higher solubility, 48 h DM degradability and effective degradability compared to the other varieties. The overall results showed evidence of varietal differences in grain and stover yield and stover quality and indicated the possibility of selecting for maize varieties that combine high grain yield and desirable stover characteristics.     

The effect of stage of maturity on yield and quality of maize grain and stover

Stage of maturity at the time of harvest is considered as one of the factors influencing the nutritive value of crop residues. Thus this study was carried out to assess the effect of harvesting maize at different stages of grain maturity on yield and quality of maize grain and stover. The maize crop was harvested at grain moisture content of 28–30, 20–23 and 10–12%, which were designated as Stages I, II and III, respectively. Grain yield, standardised to 12.5% moisture content, showed an increasing trend, whereas cob, stover, total crop residue and total biomass dry matter (DM) yield showed a decreasing trend with increasing stage of maturity (p>0.05). The declining trend in stover yield with increased stage of maturity was due mainly to leaf loss. There was a significant decrease (p<0.05) in crop residue–grain ratio and leaf–stem ratio and a significant increase in the harvest index and hectolitre weight of the grain as the grain moisture content decreased from about 30 to 10%. Maize stover harvested at Stage I had significantly higher (p<0.05) ash content than those harvested at Stages II and III. The crude protein (CP) content was significantly lower, whereas the neutral detergent fibre and cellulose contents were higher (p<0.05) in Stage III than in Stages I and II. There was a decreasing trend in in sacco DM degradability with increasing stage of maturity. The washing loss, potential degradability and effective DM degradability at 0.03 h⁻¹ rumen outflow rate were higher (p<0.05) in Stage I than in Stages II and III. The volume of gas produced after 3, 6, 12, 24, 48 and 72 h of incubation was higher (p<0.05) in Stage I than in Stages II and III. The a value (the intercept of the gas production curve) and the gas production potential (a+b) were higher (p<0.05) in Stage I than in Stage III. Reduction in the nutritive value of stover with increasing stage of maturity was characterised by reduction in CP contents and increasing concentration of fibrous constituents. These were reflections of changes in the morphological composition of stover and losses of nutrients within the morphological fractions with increasing stage of maturity.     

Effect of inoculum and pepsin–pancreatin hydrolysis on fibre fermentation measured by the gas production technique in pigs

Two experiments were undertaken to adapt the in vitro gas production technique in syringes, used for ruminants, to fibre fermentation studies in the large intestine of pigs.In a first experiment, two inocula (faeces and large intestine content) were compared at four dilution levels in a buffer solution (0.025, 0.05, 0.1 and 0.2 g ml⁻¹) with two substrates: wheat bran and sugar–beet pulp. The accumulated gas produced over 72 h was modelled and the kinetics parameters compared. The time to half asymptote was lower for the intestinal inoculum (5.5 versus 8.0 h, P<0.02), but the 2 inocula yielded similar fractional rates of degradation (0.16 h⁻¹) and gave equal final gas production (252 ml g⁻¹ substrate). No interaction (P>0.05) was observed between inocula and substrates. The dilution of the samples in the buffer solution increased (P<0.001) the lag time (from 0.9 to 2.1 h for dilution rates ranging from 0.2 to 0.025 g ml⁻¹, respectively) and decreased (P<0.001) the rates of substrate degradation (from 0.18 to 0.13 h⁻¹).A second experiment aimed to study the effect of an in vitro pepsin–pancreatin hydrolysis of the sample prior to the gas test. Six substrates were tested: maize, wheat bran, sugar–beet pulp, lupins, peas and soybean meal. The enzymatic hydrolysis affected (P<0.001) the kinetics parameters and the ranking order of the fermented substrates. The lag times also increased for all ingredients. The rate of degradation decreased when peas, lupins, maize and wheat bran were hydrolysed (P<0.001) but it increased with soybean meal (P=0.014) and sugar–beet pulp (P<0.001). Final gas production increased with peas and soybean meal (P<0.001), remained unchanged for lupins and decreased for the other substrates (P<0.001).In conclusion, the method using faeces as a source of microbial inoculum is reliable to characterise the fermentation kinetics of ingredients in the large intestine of pigs. However, it is important to hydrolyse the substrates with pepsin and pancreatin before the gas tests.     

Ruminal starch digestion characteristics in vitro of barley cultivars with varying amylose content

Three experiments were conducted to study effects of amylose/amylopectin ratios and starch particle size on ruminal digestion characteristics of barley starch using an automated in vitro gas production system. In Experiment 1, starch digestion characteristics were measured in 12 barley cultivars with different amylose/amylopectin ratios, both as milled grain and as purified starch isolated from the original grain samples. The same 12 cultivars, harvested 1 year later from the same locations, were used in Experiment 2. Gas production was measured in milled samples, and in neutral detergent fibre (NDF) extracted from the same samples. The objective of this approach was to estimate gas production from neutral detergent solubles (NDS) as an approximation of starch. This was done by subtracting the NDF gas curve from the total gas production curve. In Experiment 3, starch digestion characteristics were measured for large and small starch granules from nine of the original cultivars used in Experiment 1. The gas curves obtained were fitted to a three-pool Gompertz model, and the effective rate of digestion (kd) was estimated with a two-compartmental rumen model. In Experiment 1, the effective starch kd for milled barley and purified starch were 0.122 and 0.118/h, respectively. Barley cultivars with low amylose (LA) had a higher effective kd (0.148/h) compared with cultivars with normal amylose (NA) (0.115/h) and high amylose (HA) (0.102/h) (P=0.010). Results obtained with milled barley were supported by the purified barley starch sample results, but differences were smaller and only numerically different. In Experiment 2, the ranking of the amylose groups was consistent with those in Experiment 1 (i.e., LA > NA > HA) (P=0.096). However, these differences were not reflected in the effective kd for the NDS fraction (P=0.366). Thus, factors other than those related to starch per se, or other structural features, are apparently important. Barley cultivars in the LA group had a higher effective kd for aNDF (0.098/h) than did NA and HA barley (0.060 and 0.055/h, respectively). Thus, the effect of the amylose group on the effective kd for aNDF corresponded well with the milled barley results. The NDF fraction, directly or indirectly, has a clear impact on the ruminal digestion rate of barley starch. There was no difference in the effective kd for starch between the small (0.126/h) and large (0.129/h) starch granules.