Ruminal degradability and intestinal digestibility of protein and amino acids in treated soybean meal products

Four lactating dairy cows equipped with ruminal and duodenal cannulas were used to determine the impact of different methods of treating soybean meal (SBM) on the ruminal degradability and intestinal digestibility of crude protein and AA. Solvent-extracted SBM (SE), expeller SBM (EP), lignosulfonate SBM (LS), and heat and soyhulls SBM (HS) were incubated in the rumen in nylon bags for 48, 24, 16, 8, 4, 2, and 0 h according to National Research Council (2001) guidelines. Additional samples of each SBM product were also incubated for 16 h in the rumen; the residues from these bags were transferred to mobile bags, soaked in pepsin HCl, and then used for determination of intestinal digestibility in situ or in vitro. Treatment of SBM (EP, LS, HS) protected the crude protein and AA from ruminal degradation, increasing rumen undegradable protein from 42% in SE to 68% in EP. Kinetic analysis of crude protein and AA degradation in the rumen revealed that, compared with LS and HS, EP exhibited slower rates of degradation but a shorter lag phase and a higher proportion of soluble protein. For all SBM products, the pattern of ruminal degradation, at 16 h of incubation, was characterized by extensive degradation of Lys and His, whereas Met and the branched-chain AA were degraded to the least extent. Estimates of intestinal digestibility of AA and crude protein were lower when measured in vitro than in situ; the magnitude of the difference between the 2 methods was greater (25%) with treated SBM products than with SE (10%). The availability of essential and nonessential AA was consistently greater (30%) with treated SBM than with SE. Among the treated SBM products, 4 essential AA (Ile, Leu, Phe, and Val) showed differences in availability, with values consistently lower for HS than for LS. This study showed that, based on in situ measures, heat and chemical treatment of SBM enhanced AA availability, and that compared with HS, EP and LS had a higher potential to enhance the AA supply to the small intestine of high-producing dairy cows.     

In situ evaluation of the ruminal and intestinal digestibility of heat-treated whole cottonseeds

The effect of heating whole cottonseeds on the degradability of DM and CP in the rumen and the small intestine of lactating cows was determined in situ. Whole cottonseeds were heated for 1 or 2 h at 140, 160, or 180 degrees C prior to digestion. The degradation of DM and CP was determined in dacron bags suspended in the rumen for 3, 6, 9, 24, and 48 h. Bags incubated in the rumen for 24 h were introduced into the small intestine through a duodenal cannula and subsequently recovered in feces. The effective ruminal degradabilities of DM and of CP were evaluated, assuming a ruminal outflow rate of .08/h. Heating of whole cottonseeds decreased the degradability of DM and CP in the rumen with a corresponding increase in the amounts digested in the small intestine. The calculated temperature at which this effect was first observed was 130 degrees C. Following optimal heating amount of digestible CP reaching the small intestine more than doubled. The agreement between these findings and the results of previous in vivo experiments suggest that the dacron bag technique may reliably be used for determination of nutrient availability in the intestine.     

Influence of Jet-Sploding and extrusion on ruminal and intestinal disappearance of canola and soybeans

In situ rumen degradation and intestinal digestibility of DM and CP of Jet-Sploded and extruded protein sources were estimated, using two ruminally and duodenally cannulated lactating Holstein cows, in two experiments. One-gram samples of ground (1 mm) whole canola seed, canola meal, extruded canola meal, Jet-Sploded whole canola seed, Protec, soybean meal and extruded soybean meal (Experiment 1), and whole canola seed Jet-Sploded at temperatures ranging from 116 to 177 degrees C (Experiment 2) were heat sealed into small nylon bags for incubation in the rumen and insertion into the duodenum. Extrusion had no effect on DM or CP disappearance in the rumen nor on effective degradability. Jet-Sploding of whole canola seed dramatically reduced effective degradability (%) of DM (80.5 vs 35.9 at .08 h-1 rumen outflow rate) and CP (83.5 vs. 43.2 at .08 h-1). Total tract disappearance of DM and CP exceeded 90% for all protein sources, except Protec and Jet-Sploded material. Jet-Sploding appears to have potential for decreasing ruminal degradation of canola protein or DM without markedly decreasing intestinal digestibility.     

Evaluation of Laboratory Techniques for Predicting Ruminal Protein Degradation

Five methods of measuring protein solubility, an in situ method, and an in vitro method for measuring protein degradability were evaluated to determine which procedure most accurately predicted quantity of feed protein escaping ruminal fermentation. Feeds evaluated were soybean meal, blood meal, meat meal, corn gluten meal, distillers dried grains, brewers dried grains, distillers grains plus solubles, dehydrated alfalfa, and soybean meal treated with sodium bentonite. Solubility was measured in .15 M sodium chloride, 10% Burroughs solution, .02 N sodium hydroxide, hot water, and bicarbonate-phosphate buffer. In situ procedure was the incubation of feeds in dacron bags suspended in the rumen of cattle. In vitro procedure was incubation of feeds with five proteolytic enzymes. Results from these methods were correlated with protein degradability determined in vivo or calculated from growth trials. Protein solubility in hot water, 10% Burroughs solution, and bicarbonate-phosphate buffer was closely correlated with in vivo protein degradability, .86, .69, and .87. Highest correlation for dacron bag incubations with in vivo degradability were at 12 and 24 h, .88 and .84. All proteolytic enzymes yielded highly significant correlations with protein degradability with incubations of 1 and 4 h and offer procedural advantages over the dacron bag technique.     

Prediction of duodenal nitrogen supply from degradation or organic and nitrogenous matter in situ

The contribution of different feedstuffs to nitrogen reaching the duodenum was evaluated in situ. Dacron bags containing barley grain, corn grain, wheat silage, corn silage, alfalfa hay, rye grass, whole cottonseeds, or soybean meal were suspended in the rumens of three dairy cows fed roughage and concentrate diets. The effective degradability of the nitrogenous and organic matter of feedstuffs was calculated from their residues after incubation in the rumen for 3, 6, 9, 12, 24, 36, or 48 h. The duodenal nitrogen content at ruminal outflows of 2, 5, or 8%/h was calculated as the sum of undegradable dietary nitrogen and potential microbial nitrogen (assuming 32 g N/kg ruminally degradable organic matter). Comparison of the in situ estimates with previously reported in vivo measurements of duodenal nitrogen in cattle fed diets with similar ingredients to the tested feedstuffs yielded a linear relationship (r2 = .887). The dacron bag technique appears to hold promise for the prediction of nitrogen flow to the duodenum.     

Estimation of the digestible energy of ruminant feedstuffs by the combined bag technique

The combined bag technique was used to estimate digestible energy of ruminant feedstuffs. Samples of corn, barley, and sorghum grains; soybean and sunflower meals; corn and wheat silages; and vetch and wheat hays were incubated in dacron bags in the rumens of dairy cattle for 3 to 72 h. Bags containing residues after 12 h of ruminal incubation were introduced into the duodenum and recovered from feces. Feeds and ruminal and intestinal residues were analyzed for dry matter (DM), organic matter (OM), crude protein (CP), neutral detergent fiber, and nonstructural carbohydrates. The effective ruminal degradability of OM was higher in grains (639 g/kg of DM) and in protein supplements (609 g/kg of DM) than in forages (373 g/kg of DM). For grains and forages, carbohydrates contributed most of the degradable OM in the rumen, but, in protein supplements, about 50% of the ruminally degradable OM originated from carbohydrate. For protein supplements, 54% of the OM that disappeared postruminally was CP, but, in the grains and forage ingredients, CP contributed less than 20% of the postruminal OM that disappeared. In grains and forages, 83% of total tract disappearance of OM was from carbohydrates. For protein supplements, CP contributed 50% to overall OM disappearance. The calculated energy equivalent of digested matter averaged among feeds was 4.71 kcal/g. A high correlation was found between digestible energy estimated by the combined bag technique and the respective National Research Council values. The combined bag technique is a useful tool for the estimation of digestible energy in feedstuffs.     

Ruminal digestion by dairy cows grazing winter oats pasture supplemented with different levels and sources of protein.

Six Holstein cows fitted with ruminal cannulae were used in two simultaneous 3 x 3 Latin squares to study the effects of protein supplements on ruminal fermentation and in situ crude protein degradability. Cows rotationally grazed a winter oats (Avena sativa L.) pasture and were supplemented with one of three concentrate supplements: 1) low protein sunflower meal (L-SM); 2) high protein sunflower meal (H-SM); or 3) high protein feather meal (H-FM). Concentrates (6.5 kg/d) were offered in equal portions twice daily during milking. Ruminal pH and total volatile fatty acids concentration were unaffected by treatments. Supplementation with L-SM and H-FM decreased ruminal NH3-N concentration compared with H-SM. The concentrate with feather meal had lower effective rumen degradability of crude protein than concentrates containing sunflower meal. Effective rumen degradability of crude protein of pasture averaged 82.7%. Thirty-six multiparous Holstein cows (71 d in milk) were used in a complementary experiment to study the effect of treatments on intake, milk yield, and milk composition. Pasture (13.2 kg/d) and total (19.6 kg/d) dry matter intake (estimated using Cr2O3 as fecal marker) and milk yield (20.5 kg/d) were unaffected by level or source of protein supplemented. Intake of rumen undegradable protein in grazing dairy cows was higher when the amount of sunflower meal was increased or when feather meal was used in the supplement. However, higher rumen undegradable protein intake did not increase milk production, suggesting that rumen undegradable protein was not limiting for cows on pasture producing less than 22 kg of milk.     

The nutritive values of feed proteins and feed protein residues resistant to degradation by rumen microorganisms

Fishmeal (FM), meat and bone meal (MBM) and rapeseed meal (RSM) were incubated for 8h (RSM) or 24 h (FM, MBM) in nylon bags in the rumens of cattle, in order to prepare from each meal sufficient residues resistant to rumen degradation for evaluation of their nutritive value. The nitrogen (N) and organic matter (OM) contents of FM and MBM were significantly (P<0.05) reduced by rumen incubation. The modified acid detergent fibre content of RSM was increased, and only traces of glucosinolates remained after rumen incubation. The amino acid profiles of FM and RSM were observed to change as a result of rumen incubation, whereas that of MBM was unchanged. The true N digestibilities of all three protein meals when fed to rats as the sole protein source were significantly (P<0.05) reduced by prior rumen incubation (FM, 0.90 to 0.86; MBM, 0.81 to 0.55 and RSM, 0.76 to 0.67). When measured using a rat bioassay, the biological values of FM (65.0 to 79.2) and RSM (53.3 to 83.1) protein were significantly (P<0.05) increased as a result of rumen incubation but that of MBM was unchanged (47.7 vs 41.1). The N digestibility of the protein meals and of their residues resistant to rumen degradation were also estimated in cattle. Samples of the feedstuffs were placed in small polyester bags, inserted into the proximal duodenum of cattle, recovered in faeces and N disappearance from the bags measured. This technique ranked the N digestibilities of the feedstuffs in the same order as in the rat.     

霉变对豆粕营养价值的影响

本试验应用鸡真代谢能法和瘤胃尼龙袋法研究霉变豆粕的干物质、粗蛋白质、氨基酸利用率、代谢能 ,以此评定霉变对豆粕营养价值的影响。结果表明 :豆粕中霉菌含量由 2千个 /g增加到 30千个 /g ,豆粕的干物质、粗蛋白质利用率变化不大 (p >0 .0 5 ) ;霉菌数含量增加到 80千个 /g时 ,干物质、粗蛋白质利用率下降 ,但差异不显著 (p >0 .0 5 ) ;霉菌数含量增加到 14 0千个 /g时 ,干物质、粗蛋白质利用率显著下降 (p <0 .0 5 )。总氨基酸的平均利用率、必需氨基酸平均利用率随霉菌含量的增加而下降 ,当含量增加到 80千个 /g ,氨基酸平均利用率才极显著下降 (p <0 .0 1) ;代谢能受霉菌的影响较小 ,霉菌数超过 80千个 /g时代谢能下降但是各组平均数差异不显著 (p >0 .0 5 )。豆粕中霉菌含量由 2千个 /g增加到 80千个 /g ,豆粕的干物质、粗蛋白质瘤胃 2 4h降解率总体表现为下降 ,但差异不显著 (p >0 .0 5 ) ;豆粕中霉菌含量增加到 14 0千个 /g ,豆粕的干物质、粗蛋白质瘤胃 2 4h降解率明显下降 (p <0 .0 5 )。     

Ruminal degradability of dry matter,crude protein,and amino acids in soybean meal,canola meal,corn, and wheat dried distillers grains

Different protein sources, such as canola meal (CM) or dried distillers grains (DDG), are currently used in dairy rations to replace soybean meal (SBM). However, little data exists comparing their rumen degradation in a single study. Therefore, the objective of this study was to compare the ruminal degradation of dry matter (DM), crude protein (CP), and AA of SBM, CM, high-protein corn DDG (HPDDG), and wheat DDG plus solubles (WDDGS). In situ studies were conducted with 4 rumen-fistulated lactating Holstein cows fed a diet containing 38% grass hay and 62% corn-based concentrate. Each protein source was incubated in the rumen of each cow in nylon bags for 0, 2, 4, 8, 16, 24, and 48 h to determine DM and CP rumen degradation kinetics, whereas additional bags were also incubated for 16 h to evaluate AA ruminal disappearance. Rumen DM and CP degradability was calculated from rumen-undegraded residues corrected or not for small particle loss. Data were fitted to an exponential model to estimate degradation parameters and effective degradability (ED) was calculated with a passage rate of 0.074 h⁻¹. The WDDGS and SBM had higher uncorrected ED (DM = 75.0 and 72.6%; CP = 84.8 and 66.0%, respectively) than CM and HPDDG (DM = 57.2 and 55.5%; CP = 59.3 and 48.2%, respectively), due to higher soluble fraction in WDDGS and a combination of higher potentially degradable fraction and rate of degradation in SBM. Correction for small particle loss from bags, higher for WDDGS than for the other protein sources, decreased estimated ED but did not alter feed ranking. The ruminal disappearance of AA after 16 h of incubation reflected the overall pattern of CP degradation between protein supplements, but the ruminal disappearance of individual AA differed between protein supplements. Overall, these results indicate that, in the current study, (1) SBM and WDDGS were more degradable in the rumen than CM and HPDDG, and (2) that small particle loss correction is relevant but does not alter this ranking.     

Estimation of the proportion of feed protein digested in the small intestine of cattle consuming wet corn gluten feed

The objectives of this study were to expand the database and determine the intestinal digestibility of rumen undegradable protein (dRUP) of common dairy feeds and to determine the effects of feeding 37.9% wet corn gluten feed on these estimates. Two ruminally and duodenally fistulated steers were assigned randomly to a crossover design with 4-wk periods. The mobile bag technique was used to determine rumen undegradable protein (RUP), dRUP, total tract digestible protein, and total tract digestible dry matter of alfalfa hay, brome hay, alfalfa haylage, corn silage, whole cottonseed, soybean meal, soyhulls, ground corn, nonenzymatically browned soybean meal, and dried distillers grains. There was no consistent effect of diet on RUP, dRUP, total tract digestible protein, and total tract digestible dry matter. The RUP (% of crude protein) ranged from 5.97% for alfalfa haylage to 75.6% for nonenzymatically browned soybean meal. The dRUP ranged from 15.3% for alfalfa haylage to 96.5% for nonenzymatically browned soybean meal. The dRUP for alfalfa hay (33.9%), brome hay (39.1%), alfalfa haylage (15.5%), and corn silage (19.9%) were lower than National Research Council reported values. The higher dRUP of the nonenzymatically browned soybean meal is reflective of more total protein reaching the small intestine. The large range in dRUP was not reflected in total tract digestible protein (% of crude protein), with corn silage being the lowest at 85.2% and nonenzymatically browned soybean meal the highest at 97.9%. In this study, diet had little effect on intestinal digestibility of protein or dry matter.     

Influence of Intake of Rumen Undegradable Protein on Milk Production of Late Lactation Holstein Cows

Twenty Holstein cows, in late lactation, were assigned to five equal groups in an orthogonal design to determine effects of a rapidly rumen degraded protein source (canola meal) low in estimated rumen undegradable protein substituted for a slowly rumen degraded protein source (corn gluten meal) high in rumen undegradable protein on feed intake, milk production, and milk composition. Cows were fed total mixed rations based upon barley silage, haycrop silage, barley grain, and supplemental protein in three 4-wk periods, subsequent to a 4-wk covariate period. In situ rumen incubation of extreme diets and estimation of intermediate diets indicated that all diets exceeded Agricultural Research Council (United Kingdom) recommendations for rumen degradable and undegradable protein as well as NRC recommendations for rumen degradable protein. However, two to four diets, dependent upon assumed ruminal turnover rates, did not meet NRC recommendations for undegradable protein. Dry matter intake and milk yield were not influenced by substitution of canola meal with corn gluten meal to increase dietary undegradable protein content. Daily yield and milk percent of lactose, fat, and protein were not influenced by substitution. Results do not support NRC recommendations to supplement diets based upon these ensiled forages and barley grain for late lactation cows with protein sources resistent to rumen degradation. Results broadly support lower amounts of rumen undegraded protein recommended by the Agricultural Research Council.     

Estimation of ruminal and intestinal digestion profiles,hourly effective degradation ratio and potential N to energy synchronization of co‐products from bioethanol processing

BACKGROUND: Little research has been conducted to determine the magnitude of the differences in nutritive value among wheat dried distillers' grains with solubles (DDGS), corn DDGS and blend DDGS, or between different bioethanol plants. The objectives of this study were to compare different types of DDGS and different bioethanol plants in terms of: (1) rumen degradation kinetics profile of each DDGS component and rumen availability; (2) intestinal digestion profile of rumen undegraded protein; (3) hourly effective rumen degradation ratio and potential N‐to‐energy synchronization; (4) the role of acid detergent insoluble nitrogen in the determination of nutrient availability of DDGS. In addition, these parameters were compared in DDGS as opposed to parental grain. RESULTS: (1) The effective degradability of dry matter in DDGS samples increased as the content of feedstock wheat increased. DDGS are a good source of rumen‐undegradable protein. The protein content of DDGS derived from wheat is higher relative to that derived from corn; however, the undegradability of the protein fraction increases as the proportion of corn in the feedstock augments. (2) In addition, DDGS provide significant amounts of rumen‐degradable protein, which increased as the content of wheat in the feedstock increased. This indicates a potential loss of N when high levels of DDGS are included in the diet. (3) Acid detergent insoluble crude protein (ADICP) levels were low across DDGS samples, revealing no effect on ruminal and intestinal disappearance of protein. However, consideration should be given to the numerical differences in digestibility of rumen‐undegradable protein and the relation to ADICP content. (4) Further research with a higher number of samples and higher variability in the ADICP content should be undertaken to investigate the effect of ADICP on rumen and intestinal disappearance of DDGS protein. CONCLUSION: The digestive characteristics of each DDGS component (dry matter, organic matter, crude protein and neutral detergent fiber), the hourly effective degradation ratio between N and organic matter, and the intestinal availability of rumen‐undegradable protein differed significantly (P < 0.05) among wheat DDGS, blend DDGS and corn DDGS, and to a lesser extent between the different bioethanol plants. These results indicate that it is inappropriate to assume fixed rumen and intestinal degradation characteristics for DDGS without considering factors such as DDGS type and bioethanol plant origin. Copyright © 2010 Society of Chemical Industry     

Comparison of the in situ and in vivo intestinal disappearance of ruminally protected methionine

We designed a switchback expriment to compare the intestinal disappearance of ruminally protected Met determined in situ or in vivo over three consecutive periods. Four nonlactating Holstein heifers (477+/-36 kg) with cannulae in the rumen, duodenum, and ileum were fed a diet based on timothy silage to meet requirements for maintenance (dry matter intake = 8.72+/-0.15 kg). A total of 16 bags, containing 1.5 g of ruminally protected Met, were incubated in the rumen (4.5 h) of each cow and transferred to an acid-pepsin solution to simulate the abomasum (2.5 h). Following each incubation, bags were recovered and three bags were dried at 55 degrees C and analyzed for Met. Remaining bags were introduced directly into the duodenal or ileal cannula for the in situ method, while for the in vivo method, the content of remaining bags was transferred into gelatin capsules before their introduction in the duodenal or ileal cannula. Spot samples of digesta were collected during a 96-h period, with Co-EDTA and Cr-mordanted fiber used as indigestible markers to estimate in vivo digestibility. The disappearance of Met in the small intestine determined in vivo tended to be higher than in situ (74.45 vs. 43.65+/-1.79%). Our results indicate that when used to assess intestinal availability of ruminally protected Met, the mobile nylon bag technique can underestimate the true bioavailability of Met.     

Assessment of an in-situ technique to estimate the degradation of lipids in the rumen

In-situ disappearance of alfalfa hay, soybean, soybean meal and maize grain lipids and fatty acids were measured using two dairy cows. Bags were removed after 1, 2, 4 and 8 h incubation. Bacterial colonisation was estimated by labelling bacteria by a ¹⁵N infusion into the rumen. Results were then subtracted from calculations. Bacterial dry matter, lipids and fatty acids were highest for alfalfa hay and lowest for soybean. Disappearance of lipids and fatty acids was significantly higher for maize than for the other feeds. Stearic and octadecenoic acids appeared in hay and soybean as products of hydrogenation but no distinction could be made between fatty acids leaving the bags and fatty acids appearing or disappearing due to hydrogenation. Complete linolenic acid hydrogenation seems to be limited by the rate of hydrogenation of stearic acid into octadecenoic acids. Nylon bags seem to be a valuable tool to estimate hydrogenation or protection against hydrogenation in high linolenic content feeds.     

Degradation of Crude Protein in Forages Determined by In Vitro and In Situ Procedures

Objectives were to determine in selected forages fiber and protein fractions, in vitro and in situ CP degradability, and to compare in vitro methods of estimating rumen CP degradability with the in situ bag technique. Forages analyzed (five samples per treatment except alfalfa hays, which had four) included alfalfa as baled hay, alfalfa ensiled in conventional upright silos, alfalfa ensiled in oxygen-limiting silos, ammonia-treated corn silage, untreated corn silage, and orchardgrass hay. Untreated corn silages had the greatest protease insoluble CP at 48 h, indicating protein in corn silage is not degraded well by protease enzyme. In situ CP degradability was greater than 80% for all ensiled forages. Ensiled forages had the greatest estimated A fraction (rapidly degraded in the rumen), alfalfa hays had the greatest B fraction (intermediate rate of degradation), and orchardgrass hays had the greatest C fraction (not degraded in rumen).High correlations between in situ degradability and some in vitro measurements suggest laboratory techniques of estimating CP degradability of forages are possible. For silages, buffer-soluble CP had the greatest correlation (.58) with in situ degradability; for hays, NDIN had the greatest correlation (−.83).     

Intestinal digestibility of amino acids in rumen-undegraded protein estimated using a precision-fed cecectomized rooster bioassay: II. Distillers dried grains with solubles and fish meal

The objectives of this experiment were to measure intestinal digestibility of AA in the rumen-undegraded protein fraction (RUP-AA) of distillers dried grains with solubles (DDGS) and fish meal (FM) samples and to determine whether these feeds contain a constant protein fraction that is undegradable in the rumen and indigestible in the small intestine, as assumed in the French Institut National de la Recherche Agronomique (Paris, France) and Scandinavian AAT-PBV (AAT = AA absorbed from small intestine; PBV = protein balance in the rumen) models. Five sources of DDGS and 5 sources of FM were obtained from Feed Analysis Consortium, Inc. (Champaign, IL). To obtain the rumen-undegradable protein fraction, samples were ruminally incubated in situ for 16 h in 4 lactating cows, and the collected rumen-undegraded residues (RUR) were pooled by sample. Subsamples of the intact feeds and RUR were crop-intubated to 4 cecectomized roosters, and total excreta were collected for 48 h. Intact feeds, RUR, and excreta were analyzed for AA. Basal endogenous AA loss estimates were obtained from fasted birds and were used to calculate standardized digestibility of RUP-AA and AA in the intact feeds. Indigestibility coefficients of the intact feeds were calculated as (100 − % standardized AA digestibility), and indigestibility of the RUR was calculated as [(100 − % ruminal degradation of AA) × (100 − % standardized RUP-AA digestibility)/100]. Results indicate that standardized digestibility of feed-AA differs from RUP-AA for DDGS samples but not for FM samples, and that standardized digestibility of individual AA differs within samples. For the DDGS samples, standardized feed-AA and RUP-AA digestibility values were most often lowest for His and Lys and highest for Met and Trp. For FM samples, standardized feed-AA and RUP-AA digestibility values were most often lowest for His and highest for Trp. Results also indicate that DDGS and most FM samples do not contain a constant protein fraction that is both undegradable in the rumen and indigestible in the small intestine. Indigestibility values of RUR were lower than in intact feeds, suggesting that the feed ingredients used in this experiment contain a protein fraction that is indigestible in the intestine but partly degradable in the rumen or digestible in the intestine after rumen incubation, or both.     

Evaluation of the effect of formic acid and level of formaldehyde application before ensiling on silage protein degradability

The effect of the application, before ensiling, of formic acid alone, and together with increasing levels of formaldehyde, on the degradability of the protein of ryegrass and red clover silages has been assessed on the basis of nitrogen solubility in mineral buffer; susceptibility of N to degradation during in-vitro incubation with either rumen microorganisms, acid pepsin or neutral protease; and N disappearance when the silages were incubated in situ in Dacron bags in the rumen of sheep receiving dried grass. The relative effects of the additives were generally consistent for both crops and with all procedures: formic acid either had no effect or reduced degradability by only a small amount, whereas a mixture of formic acid and formaldehyde was more effective than formic acid alone in protecting protein from degradation, and degradability decreased in a curvilinear manner with increasing levels of formaldehyde application. Absolute values for protein degradability based on buffer solubility and in-vitro degradation by rumen microorganisms were very similar but lower than those based on digestion with proteolytic enzymes which in turn were lower than those obtained with the rumen in situ procedure. Buffer solubility and in-vitro incubation with rumen microorganisms also showed much bigger differences between the formic acid-treated and the formaldehyde-treated silages than the other methods.     

Effect of sodium bicarbonate on rate of passage and degradation of soybean meal in postpartum dairy cows

Effects of sodium bicarbonate on rate of passage and disappearance of soybean meal from the rumen were determined in a change-over experiment with eight cows. Experimental diets containing 50 or 60% roughage were fed over five 21-day periods with four cows per diet. Sodium bicarbonate at 1.0 and 2.5% (diet dry matter) were changed over in periods 2 and 4, whereas periods 1, 3, and 5 served as control. Rate of passage of soybean meal was measured with chromium-mordanted soybean meal and rate of disappearance by nylon bag technique. Effects of diet were similar for all responses. Response to the two percents of buffer was similar for dry matter intake, milk yield, milk fat, and protein. Percent buffer fed was associated positively with ruminal pH and with disappearance of nitrogen from nylon bags. The 0, 1, and 2.5% of buffer resulted in turnover rates of mordanted soybean meal of 8.22, 9.80, and 10.52%/h, but degradation of protein remained relatively constant at 36.0, 38.4, and 38.2%. The influence of rate of passage on ruminal degradability is discussed.     

Protein fractionation byproduct from canola meal for dairy cattle

Fiber-protein is a byproduct arising from a process for fractionating high-quality protein from canola meal. The objective of this study was to evaluate the fiber-protein fraction by examining the chemical profiles, rumen degradation, and intestinal digestive characteristics and determining the nutritive value of the fiber-protein fraction as dietary components for dairy cattle in comparison with commercial canola meal and soybean meal. Available energy values were estimated based on National Research Council guidelines, whereas total true protein content potentially absorbable in the small intestine (DVE) were predicted using the predicted DVE/degraded protein balance (OEB) model. The results show that fiber-protein was a highly fibrous material [neutral detergent fiber (NDF): 556; acid detergent fiber (ADF): 463; acid detergent lignin: 241 g/kg of dry matter (DM)] compared with canola meal (NDF: 254; ADF: 212; acid detergent lignin: 90 g/kg of DM) due to the presence of a higher level of seed hulls in fiber-protein. Compared with canola meal, fiber-protein contained 90 g/kg of DM less crude protein (CP), 25% of which consisted of undegradable acid detergent-insoluble CP. Most of the ruminally undegradable nutrient components present in canola meal appeared to be concentrated into fiber-protein during the manufacturing process and, as a result, fiber-protein showed a consistently lower effective degradability of DM, organic matter, CP, NDF, and ADF compared with both canola meal and soybean meal. Available energy content in fiber-protein contained two-thirds of that of canola meal. The DVE was one-third that of soybean meal and one-fifth that of canola meal [DVE value: 58 vs. 180 (soybean) and 291 g/kg of DM (canola meal)]. The OEB value of fiber protein was positive and about half of that of soybean and canola meal [OEB value: 74 vs. 162 (soybean) and 137 g/kg of DM (canola meal)]. Fiber-protein can be considered as a secondary source of protein in ruminant feed.