Ruminal fermentation of Nellore steers fed crude glycerine replacing starch vs. fibre-based energy ingredient in low or high concentrate diets

Lage, Josiane Fonseca; Vito, Elias San; Reis, Ricardo de Andrade; Delevatti, Lutti Maneck; Pierre, Norman Saint; Berchielli, Telma Teresinha

doi:10.4025/actascianimsci.v39i1.32895

ABSTRACT.

Twelve ruminally cannulated steers (401.0 ± 41.5 kg) and 24 mo were used in a replicated arrangement truncated Latin Square with six animals in six treatments and four periods to evaluate the effect of crude glycerine (CG; 80.3% of glycerol) with starch or fiber-based energy ingredients in the concentrate on DMI, DM (DMD) and NDF digestibility (NDFD) and ruminal parameters. Experimental periods were 19 days (14 days for adaptation and 5 days to sampling). Diets were: CO - without CG and corn as ingredient of concentrate; CGC - inclusion of CG (10% of DM) with corn in the concentrate; and CGSH - inclusion of CG (10% of DM) with soybean hulls (SH) in the concentrate. All three diets were offered at low (LC) or high (HC) concentrate level, CL (40 or 60%). Animals fed LC or HC diets had similar DMI, DMD and NDFD. Animals fed diets with CG associated with corn or SH had higher propionate concentrations and lower A:P ratio. Diets with HC increase the propionate but do not affect the NDFD. CG (10% of DM) can be used to replace corn or SH in diets with 40 or 60% of concentrate, without affect NDFD.

Keywords:
acetate; glycerol; propionate; pH; soybean hulls

RESUMO.

Doze novilhos canulados no rúmen (401,0 ± 41,5 kg) e 24 meses de idade foram usados em delineamento de quadrado latino truncado replicado com seis animais, seis tratamentos e quatro períodos, para avaliar o efeito da glicerina bruta (GB; 80,3% de glicerol) com amido ou ingredientes energéticos a base de fibra no concentrado sobre o CMS, digestibilidade da MS (DMS) e FDN (DFDN) e parâmetros ruminais. O período experimental foi 19 dias (14 dias de adaptação e 5 dias de coleta). As dietas foram: CO - sem glicerina bruta e milho como ingrediente do concentrado; GBM - GB (10% da MS) com milho no concentrado; GBCS - GB (10% da MS) com casca de soja no concentrado. As três dietas foram ofertadas em baixo (BC) ou alto (AC) teor de concentrado (TC; 40 ou 60%). Animais alimentados com BC ou AC apresentaram similar CMS, DMS e DFDN. Animais alimentados com GB com milho ou CS apresentaram maior concentração de propionato e menor relação A:P. Dietas com AC aumentou a concentração de propionato mas não afetou a DFDN. GB (10% da MS) pode ser usada para substituir o milho ou CS em dietas com 40 ou 60% de concentrado, sem afetar a DFDN.

Palavras-chave:
acetato; glicerol; propionato; pH; casca de soja

Introduction

Glycerol is a byproduct from the biodiesel agroindustry and has been used as an energy source in diets of ruminants (Donkin, Koser, White, Doane, & Cecava, 2009Donkin, S. S., Koser, S. L., White, H. M., Doane, P. H., & Cecava, M. J. (2009). Feeding value of glycerol as a replacement for corn grain in rations fed to lactating dairy cows. Journal of Dairy Science, 92(10), 5111-5119. ; Eiras et al., 2013Eiras, C. E., Marques, J. A., Torrecilhas, J. A., Zawadzki, F., Moletta, J. L., & Prado, I. N. (2013). Glycerin levels in the diets of crossbred bulls finished in feedlot: ingestion behavior, feeding intake and ruminal efficiency. Acta Scientiarum. Animal Sciences, 35(4), 411-416. ; Hales et al., 2013Hales, K. E., Kraich, K. J., Bondurant, R. G., Meyer, B. E., Luebbe, M. K., Brown, M. S., ... McDonald, J. C. (2013). Effects of glycerin on receiving performance and health status of beef steers and nutrient digestibility and rumen fermentation characteristics of growing steers. Journal of Animal Science, 91(9), 4277-4289. ; Meale, Chaves, Ding, Bush, & McAllister, 2013Meale, S. J., Chaves, A. V., Ding, S., Bush, R. D., & McAllister, T. A. (2013). Effects of crude glycerin supplementation on wool production, feeding behavior, and body condition of Merino ewes. Journal of Animal Science, 91(2), 878-885. ; Cruz et al., 2014Cruz, O. T. B., Valero, M. V., Zawadzki, F., Rivaroli, D. C., Prado, R. M., Lima, B. S., & Prado, I. N. (2014). Effect of glycerine and essential oils (Anacardium occidentale and Ricinus communis) on animal performance, feed efficiency and carcass characteristics of crossbred bulls finished in a feedlot system. Italian Journal of Animal Science, 13, 790-797. ; Eiras et al., 2014). A reduction in NDF digestibility has frequently been reported from the inclusion of glycerine in ruminant diets (Donkin et al., 2009Donkin, S. S., Koser, S. L., White, H. M., Doane, P. H., & Cecava, M. J. (2009). Feeding value of glycerol as a replacement for corn grain in rations fed to lactating dairy cows. Journal of Dairy Science, 92(10), 5111-5119. ) apparently from a growth inhibition of cellulolytic bacteria. However, dietary glycerine appears to have a differential effect on fiber digestion depending on the level of dietary starch. Concerns about reduction of fiber digestibility associated with feeding glycerine are limited in feedlot cattle fed high-concentrate finishing diets because fiber concentrations are normally low (Hales et al., 2013Hales, K. E., Kraich, K. J., Bondurant, R. G., Meyer, B. E., Luebbe, M. K., Brown, M. S., ... McDonald, J. C. (2013). Effects of glycerin on receiving performance and health status of beef steers and nutrient digestibility and rumen fermentation characteristics of growing steers. Journal of Animal Science, 91(9), 4277-4289. ).

Propiogenesis has been shown to substantially increase when glycerol is added to high-fiber diets in contrast to when added to high-starch diets incubated in vitro (Rémond, Souday, & Jouany, 1993Rémond, B., Souday, E., & Jouany, J. P. (1993). In vitro and in vivo fermentation of glycerol by rumen microbes. Animal Feed Science and Technology, 41(2), 121-132. ). Thus, the addition of glycerol could improve the energetic efficiency of growing ruminants fed high forage diets more so than for those fed with a greater proportion of concentrate in the diets (Farias et al., 2012Farias, M. S., Prado, I. N., Valero, M. V., Zawadzki, F., Silva, R. R., Eiras, C. E., ... Lima, B. S. (2012). Níveis de glicerina para novilhas suplementadas em pastagens: desempenho, ingestão, eficiência alimentar e digestibilidade. Semina: Ciências Agrárias, 33(3), 1177-1188. ; Eiras et al., 2014Eiras, C. E., Barbosa, L. P., Marques, J. A., Lima, B. S., Zawadzki, F., Perotto, D., & Prado, I. N. (2014 ). Glycerine levels in the diets of crossbred bulls finished in feedlot: apparent digestibility, feed intake and animal performance. Animal Feed Science and Technology, 197, 222-226. ). The objective of this study was to evaluate the effects of crude glycerine on diet digestibility and ruminal fermentation when fed at two levels of concentrate to Nellore steers.

Material and methods

The trial was realized at the animal facilities of the Department of Animal Science, Universidade Estadual Paulista, Jaboticabal, São Paulo, Brazil, and followed the humane animal care and handling procedures set at the institution. Twelve ruminally cannulated Nellore steers with an average BW of 401.0 ± 41.5 kg and 24 months of age were used in a replicated, truncated Latin square design. Each truncated square consisted of six animals, six treatments and four periods, set to evaluate treatment effects on intake, apparent total tract digestibility, ruminal pH, ammonia-N concentration and VFA of steers fed in finishing phase. Animals were treated for internal and external parasites at the beginning of the experiment and kept in individual pens of approximately 21 m² with protected feeders and waterers throughout the adaptation and sampling periods. Experimental periods were 19 days in total, with the first 14 days for adaptation to the diet and the last 5 days used for sampling. Dry matter intake was measured over the 5 days of sampling, while feces were sampled for 3 days and liquid and ruminal contents over a single day.

The treatment design was a 3 x 2 factorial with the first factor consisting of 3 combinations of level of glycerine and main substrate in the concentrate, while the second factor consisted of 2 proportions of concentrate in the total diet. The 3 glycerine/substrate diets were as follow: CO - 0% crude glycerine with corn as the main ingredient in the concentrate; CGC - crude glycerine at 10% of DM with corn as the main ingredient in the concentrate; and CGSH - crude glycerine at 10% of DM with soybean hulls as the main ingredient in the concentrate. These three diets were offered at two levels of concentrate: 40 and 60% of DM.

Crude glycerine was sourced from a soybean oil-based biodiesel production company, (ADM, Rondonópolis, Brazil) and contained 80.3 glycerol, 1.6 ether extracts, 5.0 ash and 12.0% water. Corn silage was used as the only source of roughage. Concentrates were made of ground corn, soybean hulls, soybean meal, urea/ammonium sulfate and a mineral mixture (Table 1). Soybean meal was used as the primary source of protein in all diets. A mixture of urea and ammonium sulfate was used to make the diets nearly isonitrogenous at approximately 14.4 ± 0. 2% CP (Valadares Filho, 2006Valadares Filho, S. C. (2006). Tabelas brasileiras de composição de alimentos para bovinos. Viçosa, MG: UFV.). Concentrate recipes and their chemical compositions are reported in Table 1.

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Table 1
Diet composition (DM basis)¹.

Diets were fed as a total mixed ration in which corn silage and concentrate (previously mixed) were weighed and thoroughly mixed before each feeding. Cattle were fed once daily at 0700 hour, and feed refusals were sampled and weighed daily for each individual pen. Amounts of feed offered daily to animals were calculated according to previous DMI and adjustments were made daily to ensure ad libitum intake (5-10% refusal). Steers had free access to water throughout the trial. Samples of diets (forage and concentrate) and orts from each animal were collected throughout the 5 days of the sampling period (days 15 to 19), then composited by animal and period for subsequent analyses. Dry matter intake and NDF intake were calculated as the difference between the amounts offered and refused based on the chemical analysis of the composited sample for each steer within each period. Feed samples and orts were frozen at -18°C until analyzed for DM [method 934.01; AOAC (2005Association Official Analytical Chemist [AOAC]. (2005). Official methods of analysis (18th ed.). Gaitherburg, MD: AOAC.)], ether extract Association Official Analytical Chemist (AOAC, 2005Association Official Analytical Chemist [AOAC]. (2005). Official methods of analysis (18th ed.). Gaitherburg, MD: AOAC.), N Leco Instruments Inc., method 976.06, AOAC (2005Association Official Analytical Chemist [AOAC]. (2005). Official methods of analysis (18th ed.). Gaitherburg, MD: AOAC.] and multiplied by 6.25 to obtain CP, ash [method 924.05; AOAC (2005Association Official Analytical Chemist [AOAC]. (2005). Official methods of analysis (18th ed.). Gaitherburg, MD: AOAC.)], while NDF was determined by the method of Van Soest, Robertson, and Lewis (1991Van Soest, P. J., Robertson, J. B., & Lewis, B. A. (1991). Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science , 74(10), 3583-3597. ) using Ankon bags (Ankon Technology Corp., Fairport, NY, USA).

Total fecal collections were done over 3 days between days 15 and 17 of each period. Feces were collected immediately after each spontaneous defecation, and stored in 20 L buckets. At the end of each 24 hours collection, feces from each bucket were weighed, manually mixed, and daily aliquots (approximately 300 g) were collected, ground in a Wiley mill (1 mm screen; model MA680, Marconi, Piracicaba, SP) and dried in a forced-air oven at 60°C for 72 to 96 hours. At the end of each period, 10 g of each of the 3 dried samples from each animal were used to prepare a composite sample for each animal-period. All composite samples were stored in sealed plastic flasks for subsequent analysis of DM and NDF.

Rumen pH, ammonia-N, and VFA were measured on samples taken over a 12 hour span on day 18 of each experimental period. Ruminal content was obtained at 0, 2, 4, 6, 8, 10 and 12 hour after the 0700 hour feeding. Samples of rumen samples content were obtained from several sites within the rumen and were subsequently strained through 2 layers of cheesecloth. Ruminal pH was immediately measured on the separated liquid using an electric pH meter (Nova Técnica, PHM, Piracicaba, State São Paulo). Immediately the pH measurements, samples were poured into 50 mL plastic flasks containing 1 mL of 9.3 M H₂SO₄ and frozen at -20°C until subsequent. Ruminal fluid NH₃ concentration was determined by distillation with 2 MKOH in a micro-Kjeldahl system according to the original procedures of Fenner (1965Fenner, H. (1965). Method for determining total volatile bases in rumen fluid by steam distillation. Journal of Dairy Science, 48(2), 249-251. ). Sub-samples of rumen fluids were centrifuged at 13000 x g (4°C) for 30 min and VFA was quantified by gas chromatography (GC Shimatzu model 20-10, automatic injection) using capilar column (SP-2560, 100 m × 0.25 mm of diameter and 0.02 mm of thickness, Supelco, Bellefonte, PA) according to the method of Palmquist and Conrad (1971Palmquist, D. L., & Conrad, H. R. (1971). Origin of plasma fatty acids in lactating cows fed high grain or high fat diets. Journal of Dairy Science, 54(7), 1025-1033. ).

Data were analyzed as linear mixed models using the MIXED procedure of SAS V9.2 (SAS Inst. Inc., Cary, NC). For variables measured only once on each animal-period, the model included the fixed effects of diet type (2 df), concentrate level (1 df) and their interaction (2 df), and the random effects of animals (5 df), periods (3 df) and a residual error (i.e., the animal x period x diet interaction, 10 df). Variables with repeated measurements on each animal-period (i.e, pH, ammonia-N and VFA) were analyzed using a model with the same effects previously stated with the additional fixed effects of hourly times (6 df), time x diet type (12 df), time x concentrate level (6 df), time x diet x concentrate level (12 df) and a random residual effect (i.e., the animal x period x diet x time, 108 df). Several covariance structures were tested to account for the correlation of errors due to the repeated measures. The structure resulting in the smallest Schwarz Bayesian criteria (BIC) was considered the most appropriate in the final model used for testing fixed effects. Differences between least-squares means were tested (p < 0.05) using Tukey’s test.

Results and discussion

Level of concentrate in the diet had no effect on DMI (p = 0.64), DM digestibility (p = 0.85) and NDF digestibility (p = 0.61; Table 2). The negative effect of high concentrate diets on DMI can occur due to a depression in fiber digestibility. Sarwar, Firkins, and Eastridge (1992Sarwar, M., Firkins, J. L., & Eastridge, M. L. (1992). Effects of varying forage and concentrate carbohydrates on nutrient digestibilities and milk production by dairy cows. Journal of Dairy Science, 75(6), 1533-1542. ) reported that the extent of digestion of NDF decreased as the proportion of concentrate in the diet increased. However, in the present study DM and NDF digestibility did not differ between two levels of concentrate used and negative effects on DMI were not observed, possibly because the reduced feed intake frequently reported in the literature generally occurs at concentrate levels exceeding 70 to 75% concentrate (Tremere, Merrill, & Loosli, 1968Tremere, A. W., Merrill, W. G., & Loosli, J. K. (1968). Adaptation to high concentrate feeding as related to acidosis and digestive disturbances in dairy heifers. Journal of Dairy Science , 51(7), 1065-1072. ); whereas the maximum concentrate level used in this study was 60% of diet DM.

Likewise, the effect of diet 10 vs.0% or corn vs. hulls had no significant effect on DMI, DM digestibility and NDF digestibility (p > 0.05; Table 2).

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Table 2
Effect of crude glycerine associated with corn or soybean hulls in two levels of concentrate on DMI and nutrient digestibility.

Although some studies have reported a negative effect of feeding glycerine fiber digestibility in ruminants (Abo El-Nor, AbuGhazaleh, Potu, Hastings, & Khattab, 2010Abo El-Nor, S., AbuGhazaleh, A. A., Potu, R. B., Hastings, D., & Khattab, M. S. A. (2010). Effects of differing levels of glycerol on rumen fermentation and bacteria. Animal Feed Science and Technology, 162(3), 99-105. ; Shin, Wang, Kim, Adesogan, & Staples, 2012Shin, J. H., Wang, D., Kim, S. C., Adesogan, A. T., & Staples, C. R. (2012). Effects of feeding crude glycerin on performance and ruminal kinetics of lactating Holstein cows fed corn silage or cottonseed hull-based, low-fiber diets. Journal of Dairy Science , 95(7), 4006-4016. ), results from other studies suggest that crude glycerine can be included at levels up to 10% of the DM, replacing rapidly fermentable starch in finishing beef cattle diets without affecting intake or nutrient digestibility (Ramos & Kerley, 2012Ramos, M. H., & Kerley, M. S. (2012). Effect of dietary crude glycerol level on ruminal fermentation in continuous culture and growth performance of beef calves. Journal of Animal Science, 90(3), 892-899. ; Bartoň et al., 2013Bartoň, L., Bureš, D., Homolka, P., Jančík, F., Marounek, M., & Řehák, D. (2013). Effects of long-term feeding of crude glycerine on performance, carcass traits, meat quality, and blood and rumen metabolites of finishing bulls. Livestock Science, 155(1), 53-59. ). The lack of digestibility depression from a starch-based diet with 10% glycerine in our study is in agreement with these reports.

In the present study, we hypothesized that the inclusion of crude glycerine in combination with a fiber-based energy ingredient in the concentrate would decrease NDF digestibility and, consequently DMI. Soybean hulls have 66.3% of NDF concentration in DM basis (National Research Council [NRC], 2000National Research Council [NRC]. (2000). Nutrient requirements of beef cattle (7th ed., rev.). Washington, DC: The National Academies Press.). However, the soybean hulls has a small feed particle size (Mertens, 1997Mertens, D. R. (1997). Creating a system for meeting the fiber requirements of dairy cows. Journal of Dairy Science, 80(7), 1463-1481. ) and could result in a more rapid ruminal escape and in a reduction of the ruminal fill (Iraira et al., 2013Iraira, S. P., Torre, J. L. R., Rodríguez-Prado, M., Calsamiglia, S., Manteca, X., & Ferret, A. (2013). Feed intake, ruminal fermentation, and animal behavior of beef heifers fed forage free diets containing nonforage fiber sources. Journal of Animal Science, 91(8), 3827-3835. ). Although the soybean hulls have high NDF content and the experimental diets which crude glycerine replaced soybean hulls increases NDF concentration (Table 1), the digestibility was not affected in these diets because the soybean hulls had lower time to retention in the rumen.

There was an interaction of CL by diet 10 vs. 0% on DMI (p = 0.02). As observed in our study, the intake has been variable and generally depressed in studies where crude glycerine replaced rapidly fermentable starch in diets with high level of concentrate (Parsons, Shelor, & Drouillard, 2009Parsons, G. L., Shelor, M. K., & Drouillard, J. S. (2009). Performance and carcass traits of finishing heifers fed crude glycerin. Journal of Animal Science, 87(2), 653-657. ; Avila-Stagno et al., 2013Avila-Stagno, J., Chaves, A. V., He, M. L., Harstad, O. M., Beauchemin, K. A., McGinn, S. M., & McAllister, T. A. (2013). Effects of increasing concentrations of glycerol in concentrate diets on nutrient digestibility, methane emissions, growth, fatty acid profiles, and carcass traits of lambs. Journal of Animal Science, 91(2), 829-837. ; Meale et al., 2013Meale, S. J., Chaves, A. V., Ding, S., Bush, R. D., & McAllister, T. A. (2013). Effects of crude glycerin supplementation on wool production, feeding behavior, and body condition of Merino ewes. Journal of Animal Science, 91(2), 878-885. ).

The ruminal pH was lower to animals fed high concentrate diets than ruminal pH from animals fed low concentrate diets (p < 0.01; Table 3; Figure 1). The DMI is a major determinant of rumen pH and individual animal difference in rumen pH depends on the capacity of the animal to buffer and to absorb organic acids produced in the rumen which determines the drop of rumen pH after feeding large amounts of fermentable carbohydrates (Krause & Oetzel, 2006Krause, K. M., & Oetzel, G. R. (2006). Understanding and preventing subacute ruminal acidosis in dairy herds: A review. Animal Feed Science and Technology, 126(3), 215-236. ). The DMI from animals fed with different concentrate levels (40 or 60%) was similar among these diets, but generally, increasing the grain content of the diet usually results in a decline in rumen pH as a result of an increase in the supply of rapidly fermentable carbohydrates (Van Kessel & Russell, 1996Van Kessel, J. A. S., & Russell, J. B. (1996). The effect of pH on ruminal methanogenesis. FEMS Microbiology Ecology, 20(4), 205-210. ; Lana, Russell, & Van Amburgh, 1998Lana, R. P., Russell, J. B., & Van Amburgh, M. E. (1998). The role of pH in regulating ruminal methane and ammonia production. Journal of Animal Science, 76(8), 2190-2196. ; Walsh et al., 2009Walsh, K., O’Kiely, P., Taweel, H. Z., McGee, M., Moloney, A. P., & Boland, T. M. (2009). Intake, digestibility and rumen characteristics in cattle offered whole-crop wheat or barley silages of contrasting grain to straw ratios. Animal Feed Science and Technology, 148(2-4), 192-213. ).

Figure 1
pH in the ruminal fluid of steers fed diets CO = corn, without crude glycerine; CGC = crude glycerine associated with corn; CGSH = crude glycerine associated with soybean hulls at two levels of concentrate. Significant effects of concentrate level (p < 0.01) were detected.

Some researchers have reported that ruminal pH decreases when crude glycerine replaces starch in diets to ruminants (Mach, Bach, & Devant, 2009Mach, N., Bach, A., & Devant, M. (2009). Effects of crude glycerin supplementation on performance and meat quality of Holstein bulls fed high-concentrate diets. Journal of Animal Science, 87(2), 632-638. ; Ramos & Kerley, 2012Ramos, M. H., & Kerley, M. S. (2012). Effect of dietary crude glycerol level on ruminal fermentation in continuous culture and growth performance of beef calves. Journal of Animal Science, 90(3), 892-899. ), because the ruminal fermentation of glycerol is faster than starch. Contrary to these experiments, no differences were detected in pH, in the present study, when crude glycerine replaced corn or soybean hulls in 10% of diet DM. Likewise, DeFrain, Hippen, Kalscheur, and Jardon (2004DeFrain, J. M., Hippen, A. R., Kalscheur, K. F., & Jardon, P. W. (2004). Feeding glycerol to transition dairy cows: effects on blood metabolites and lactation performance. Journal of Dairy Science, 87(12), 4195-4206. ) reported no differences in pH when crude glycerine replaced corn starch in diets to ruminants.

Differences in ammonia-N concentration was not observed in animals fed low or high concentrate diets (p = 0.14; Table 3); however, significant effect of diet 10 vs. 0% (p = 0.03) and diet corn vs. hulls (p = 0.01) was detected (Figure 2). Animals fed crude glycerine associated with corn or soybean hulls had lower ammonia-N concentration than animals fed diets without crude glycerine. The suppressed microbial fermentation activity can be induced by ruminal transit (Cole & Hutcheson, 1985Cole, N. A., & Hutcheson, D. (1985). Influence of prefast feed intake on recovery from feed and water deprivation by beef steers. Journal of Animal Science, 60(3), 772-780. ) and the crude glycerine is readily absorbed through the rumen wall or fermented to propionate.

Thus, due to the fast disappearance of crude glycerine from the rumen, it can contribute to decrease the ammonia-N concentration in the rumen. Likewise, Avila-Stagno et al. (2013Avila-Stagno, J., Chaves, A. V., He, M. L., Harstad, O. M., Beauchemin, K. A., McGinn, S. M., & McAllister, T. A. (2013). Effects of increasing concentrations of glycerol in concentrate diets on nutrient digestibility, methane emissions, growth, fatty acid profiles, and carcass traits of lambs. Journal of Animal Science, 91(2), 829-837. ) showed a linear decrease of ammonia-N concentration in the rumen when increase the crude glycerine concentration up to 150 g kg^-1 of the diet.

Animals fed diets with crude glycerine associated with soybean hulls had lower ammonia-N concentration than animals fed diets with crude glycerine associated with corn. The soybean hulls exhibit a greater rate of ruminal passage than corn (Ipharraguerre & Clark, 2003Ipharraguerre, I. R., & Clark, J. H. (2003). Soyhulls as an alternative feed for lactating dairy cows: a review. Journal of Dairy Science, 86(4), 1052-1073. ), remaining less time at the rumen, reducing the microbial fermentation activity and favoring the lower production of ammonia-N in the rumen.

Figure 2
Ammonia-N concentration in the ruminal fluid of steers fed diets CO = corn, without crude glycerine; CGC = crude glycerine associated with corn; CGSH = crude glycerine associated with soybean hulls at two levels of concentrate. Significant effects of diets (p < 0.05) were detected.

There was an interaction of CL by diet 10% vs. 0% (p = 0.04; Table3; Figure 3) on acetate concentrations. Acetate concentrations were higher in ruminal fluid from animals fed diets with low concentrate without crude glycerine than diets with high concentrate without crude glycerine. In diets with high proportion of roughage, the acetate concentrations are greater because increase the quantity of fiber fermented.

Figure 3
Acetate concentrations in the ruminal fluid of steers fed diets CO = corn, without crude glycerine; CGC = crude glycerine associated with corn; CGSH = crude glycerine associated with soybean hulls at two levels of concentrate. There was an interaction between concentrate level x diets (p < 0.05).

We hypothesized that animals fed diets with crude glycerine associated with corn or soybean hulls in low concentrate diets may produce lower acetate concentrations than animals fed diets with crude glycerine associated with corn or soybean hulls in high concentrate diets because crude glycerine may produce others VFA more efficiently at low-concentrate diets.

The decrease in acetate concentrations were observed in animals fed crude glycerine associated with starch- or fiber-based ingredients in low concentrate than animals fed low concentrate diets without crude glycerine. Although the acetate concentrations from animals fed crude glycerine associated with starch- or fiber-based ingredients in low concentrate were not lower than acetate concentrations from animals fed high concentrate diets, these concentrations were similar between these diets, reporting the glycogenic property of glycerol in low concentrate diets.

Starch fermentation in the rumen yields more propionate, less acetate production, unlike the soybean hulls that are low in lignin and composed of a large proportion of potentially digestible fiber (Quicke, Bentley, Scott, Johnson, & Moxon, 1959Quicke, G. V., Bentley, O. G., Scott, H. W., Johnson, R. R., & Moxon, A. L. (1959). Digestibility of soybean hulls and flakes and the in vitro digestibility of the cellulose in various milling by-products. Journal of Dairy Science, 42(1), 185-186. ; Hsu et al., 1987Hsu, J. T., Faulkner, D. B., Garleb, K. A., Barclay, R. A., Fahey Jr., G. C., & Berger, L. L. (1987). Evaluation of corn fiber, cottonseed hulls, oat hulls and soybean hulls as roughage sources for ruminants. Journal of Animal Science, 65(1), 244-255. ).

Therefore, when soybean hulls are fermented in the rumen, more acetate than propionate is produced. Evaluating diets with crude glycerine associated with corn or soybean hulls (low or high concentrate), was observed that acetate concentrations were similar in animals fed crude glycerine associated with corn or soybean hulls both in low concentrate diets, but it is not observed in high concentrate diets, which acetate concentrations were higher in diets with crude glycerine associated soybean hulls than diets with crude glycerine associated with corn.

Despite these results, can be observed that crude glycerine had a greater efficiency to reduce the acetate concentrations associated with fiber-based ingredients in low concentrate, because similar results did not achieved in high concentrate diets.

There was a significant effect of CL (p < 0.01) and diet 10 vs. 0% (p < 0.01) on propionate concentrations (Table 3; Figure 4).

Figure 4
Propionate concentration in the ruminal fluid of steers fed diets CO = corn, without crude glycerine; CGC = crude glycerine associated with corn; CGSH = crude glycerine associated with soybean hulls at two levels of concentrate. Significant effects of concentrate level (p < 0.01) and diets (p < 0.01) were detected.

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Table 3
Effect of crude glycerine associated with corn or soybean hulls in two levels of concentrate on pH, ammonia-N and VFA concentrations.

Animals fed high concentrate diets had greater propionate concentrations than animals fed low concentrate diets. When propionate concentrations increase in ruminal fluid, the pH decreases (Ørskov, 1986Ørskov, E. R. (1986). Starch digestion and utilization in ruminants. Journal of Animal Science, 63(5), 1624-1633. ). Linear decrease in the molar proportion of acetic acid and simultaneous increase in propionic acid concentration occurs in response to increasing the grain content (McGeough et al., 2010McGeough, E. J., O’Kiely, P., Hart, K. J., Moloney, A. P., Boland, T. M., & Kenny, D. A. (2010). Methane emissions, feed intake, performance, digestibility, and rumen fermentation of finishing beef cattle offered whole-crop wheat silages differing in grain content. Journal of Animal Science, 88(8), 2703-2716. ). Likewise, in the present study, the propionate concentrations increase and the pH were reduced in ruminal fluid from animals fed high concentrate diets. It has also been well established (Moe & Tyrrell, 1979Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science, 62(10), 1583-1586. ; Johnson & Johnson, 1995Johnson, K. A., & Johnson, D. E. (1995). Methane emissions from cattle. Journal of Animal Science, 73(8), 2483-2492. ) that altering the dietary forage-to-concentrate ratio, specifically the fiber to-starch ratio, affects the proportion of the individual VFA in the rumen.

The propionate concentrations (p < 0.05) and A:P ratio (p < 0.05; Table 3; Figure 6) were affected by inclusion of crude glycerine in diets replacing starch- or fiber-based energy ingredients in the concentrate. animals fed diets with crude glycerine associated with corn or soybean hulls had higher propionate concentrations and lower A:P ratio in ruminal fluid than animals fed diets without crude glycerine. The increase in molar proportion of propionate resulted in reduction of acetate:propionate ratio, according with Lee et al. (2011Lee, S. Y., Lee, S. M., Cho, Y. B., Kam, D. K., Lee, S. C., Kim, C. H., & Seo, S. (2011). Glycerol as a feed supplement for ruminants: In vitro fermentation characteristics and methane production. Animal Feed Science and Technology, 166-167, 269-274.) that reported the propionate as an mainly end product from fermentation of glycerol. The increase of propionate concentrations by feeding with glycerol has been reported when crude glycerine replaced roughage (Hales et al., 2013Hales, K. E., Kraich, K. J., Bondurant, R. G., Meyer, B. E., Luebbe, M. K., Brown, M. S., ... McDonald, J. C. (2013). Effects of glycerin on receiving performance and health status of beef steers and nutrient digestibility and rumen fermentation characteristics of growing steers. Journal of Animal Science, 91(9), 4277-4289. ) or rapidly fermentable starch in the concentrates (Avila et al., 2011Avila, J. S., Chaves, A. V., Hernandez-Calva, M., Beauchemin, K. A., McGinn, S. M., Wang, Y., ... McAllister, T. A. (2011). Effects of replacing barley grain in feedlot diets with increasing levels of glycerol on in vitro fermentation and methane production. Animal Feed Science and Technology, 166, 265-268. ; Ramos & Kerley, 2012Ramos, M. H., & Kerley, M. S. (2012). Effect of dietary crude glycerol level on ruminal fermentation in continuous culture and growth performance of beef calves. Journal of Animal Science, 90(3), 892-899. ), confirming the glycogenic properties of glycerol.

Effects of glycerol on ruminal fermentation are a shift in VFA production in favor of propionate, with an even greater increase in butyrate at the expense of acetate both in vitro and in vivo (Rémond et al., 1993Rémond, B., Souday, E., & Jouany, J. P. (1993). In vitro and in vivo fermentation of glycerol by rumen microbes. Animal Feed Science and Technology, 41(2), 121-132. ). In this work, there was an interaction of CL by diet 10 vs. 0% (p = 0.01) on butyrate concentrations.

Butyrate concentrations were greater in diets with crude glycerine associated with corn or soybean hulls than diets without crude glycerine (Table 3; Figure 5) in different levels of concentrate. Glycerol is metabolized by Megasphaera elsdenii, Streptococcus bovis, and Selenomonas ruminantium (Stewart, Flint, & Bryant, 1997Stewart, C. S., Flint, H. J., & Bryant, M. P. (1997) The rumen bacteria. In P. N. Hobson, & C. S. Stewart, (Ed.), The rumen microbial ecosystem (2nd ed., p. 10-72). London, UK: Blackie Academic and Professional.), and Megasphaera elsdenii has been associated with increases in butyric acid in ruminal fluid (Hales et al., 2013Hales, K. E., Kraich, K. J., Bondurant, R. G., Meyer, B. E., Luebbe, M. K., Brown, M. S., ... McDonald, J. C. (2013). Effects of glycerin on receiving performance and health status of beef steers and nutrient digestibility and rumen fermentation characteristics of growing steers. Journal of Animal Science, 91(9), 4277-4289. ). The increase in the molar proportion of butyrate with glycerol substitution level is consistent with the findings of others (Rémond et al., 1993Rémond, B., Souday, E., & Jouany, J. P. (1993). In vitro and in vivo fermentation of glycerol by rumen microbes. Animal Feed Science and Technology, 41(2), 121-132. ; Wang et al., 2009Wang, C., Liu, Q., Yang, W. Z., Huo, W. J., Dong, K. H., Huang, Y. X., ... He, D. C. (2009). Effects of glycerol on lactation performance, energy balance and metabolites in early lactation Holstein dairy cows. Animal Feed Science and Technology, 151(1), 12-20.; Abo El-Nor et al., 2010Abo El-Nor, S., AbuGhazaleh, A. A., Potu, R. B., Hastings, D., & Khattab, M. S. A. (2010). Effects of differing levels of glycerol on rumen fermentation and bacteria. Animal Feed Science and Technology, 162(3), 99-105. ) who reported that the molar proportion of butyrate in the VFA mixture increased when glycerol was added in the diets.

Figure 5
Butyrate concentrations in the ruminal fluid of steers fed diets CO = corn, without crude glycerine; CGC = crude glycerine associated with corn; CGSH = crude glycerine associated with soybean hulls at two levels of concentrate. There was an interaction between concentrate level x diets (p < 0.05).

Figure 6
Acetate: propionate ratio in the ruminal fluid of steers fed diets CO = corn, without crude glycerine; CGC = crude glycerine associated with corn; CGSH = crude glycerine associated with soybean hulls at two levels of concentrate. There was an interaction between concentrate level x diets (p < 0.05).

Conclusion

Increasing concentrate content (40 to 60%) reduces the pH, increases the propionate but does not affect the NDF digestibility of diets and DMI by animals. Crude glycerine can be used to replace corn or soybean hulls in 10% of diet DM in diets with 40 or 60% of concentrate, without affect NDF digestibility. Moreover, the inclusion of crude glycerine in diets associated with starch- or fiber-based energy ingredients increases butyrate concentrations and reduces the acetate:propionate ratio as a result of increases of propionate concentrations.

Acknowledgements

We thank the Sao Paulo Research Foundation (Fapesp) for funding this research, process (2009/18431-2 and 2010/11043-4) and Trouw Nutrition Brazil/ Bellman for providing feed supplies for experimental diets.

References

Abo El-Nor, S., AbuGhazaleh, A. A., Potu, R. B., Hastings, D., & Khattab, M. S. A. (2010). Effects of differing levels of glycerol on rumen fermentation and bacteria. Animal Feed Science and Technology, 162(3), 99-105.
Association Official Analytical Chemist [AOAC]. (2005). Official methods of analysis (18th ed.). Gaitherburg, MD: AOAC.
Avila, J. S., Chaves, A. V., Hernandez-Calva, M., Beauchemin, K. A., McGinn, S. M., Wang, Y., ... McAllister, T. A. (2011). Effects of replacing barley grain in feedlot diets with increasing levels of glycerol on in vitro fermentation and methane production. Animal Feed Science and Technology, 166, 265-268.
Avila-Stagno, J., Chaves, A. V., He, M. L., Harstad, O. M., Beauchemin, K. A., McGinn, S. M., & McAllister, T. A. (2013). Effects of increasing concentrations of glycerol in concentrate diets on nutrient digestibility, methane emissions, growth, fatty acid profiles, and carcass traits of lambs. Journal of Animal Science, 91(2), 829-837.
Bartoň, L., Bureš, D., Homolka, P., Jančík, F., Marounek, M., & Řehák, D. (2013). Effects of long-term feeding of crude glycerine on performance, carcass traits, meat quality, and blood and rumen metabolites of finishing bulls. Livestock Science, 155(1), 53-59.
Cole, N. A., & Hutcheson, D. (1985). Influence of prefast feed intake on recovery from feed and water deprivation by beef steers. Journal of Animal Science, 60(3), 772-780.
Cruz, O. T. B., Valero, M. V., Zawadzki, F., Rivaroli, D. C., Prado, R. M., Lima, B. S., & Prado, I. N. (2014). Effect of glycerine and essential oils (Anacardium occidentale and Ricinus communis) on animal performance, feed efficiency and carcass characteristics of crossbred bulls finished in a feedlot system. Italian Journal of Animal Science, 13, 790-797.
DeFrain, J. M., Hippen, A. R., Kalscheur, K. F., & Jardon, P. W. (2004). Feeding glycerol to transition dairy cows: effects on blood metabolites and lactation performance. Journal of Dairy Science, 87(12), 4195-4206.
Donkin, S. S., Koser, S. L., White, H. M., Doane, P. H., & Cecava, M. J. (2009). Feeding value of glycerol as a replacement for corn grain in rations fed to lactating dairy cows. Journal of Dairy Science, 92(10), 5111-5119.
Eiras, C. E., Barbosa, L. P., Marques, J. A., Lima, B. S., Zawadzki, F., Perotto, D., & Prado, I. N. (2014 ). Glycerine levels in the diets of crossbred bulls finished in feedlot: apparent digestibility, feed intake and animal performance. Animal Feed Science and Technology, 197, 222-226.
Eiras, C. E., Marques, J. A., Torrecilhas, J. A., Zawadzki, F., Moletta, J. L., & Prado, I. N. (2013). Glycerin levels in the diets of crossbred bulls finished in feedlot: ingestion behavior, feeding intake and ruminal efficiency. Acta Scientiarum. Animal Sciences, 35(4), 411-416.
Farias, M. S., Prado, I. N., Valero, M. V., Zawadzki, F., Silva, R. R., Eiras, C. E., ... Lima, B. S. (2012). Níveis de glicerina para novilhas suplementadas em pastagens: desempenho, ingestão, eficiência alimentar e digestibilidade. Semina: Ciências Agrárias, 33(3), 1177-1188.
Fenner, H. (1965). Method for determining total volatile bases in rumen fluid by steam distillation. Journal of Dairy Science, 48(2), 249-251.
Hales, K. E., Kraich, K. J., Bondurant, R. G., Meyer, B. E., Luebbe, M. K., Brown, M. S., ... McDonald, J. C. (2013). Effects of glycerin on receiving performance and health status of beef steers and nutrient digestibility and rumen fermentation characteristics of growing steers. Journal of Animal Science, 91(9), 4277-4289.
Hsu, J. T., Faulkner, D. B., Garleb, K. A., Barclay, R. A., Fahey Jr., G. C., & Berger, L. L. (1987). Evaluation of corn fiber, cottonseed hulls, oat hulls and soybean hulls as roughage sources for ruminants. Journal of Animal Science, 65(1), 244-255.
Ipharraguerre, I. R., & Clark, J. H. (2003). Soyhulls as an alternative feed for lactating dairy cows: a review. Journal of Dairy Science, 86(4), 1052-1073.
Iraira, S. P., Torre, J. L. R., Rodríguez-Prado, M., Calsamiglia, S., Manteca, X., & Ferret, A. (2013). Feed intake, ruminal fermentation, and animal behavior of beef heifers fed forage free diets containing nonforage fiber sources. Journal of Animal Science, 91(8), 3827-3835.
Johnson, K. A., & Johnson, D. E. (1995). Methane emissions from cattle. Journal of Animal Science, 73(8), 2483-2492.
Krause, K. M., & Oetzel, G. R. (2006). Understanding and preventing subacute ruminal acidosis in dairy herds: A review. Animal Feed Science and Technology, 126(3), 215-236.
Lana, R. P., Russell, J. B., & Van Amburgh, M. E. (1998). The role of pH in regulating ruminal methane and ammonia production. Journal of Animal Science, 76(8), 2190-2196.
Lee, S. Y., Lee, S. M., Cho, Y. B., Kam, D. K., Lee, S. C., Kim, C. H., & Seo, S. (2011). Glycerol as a feed supplement for ruminants: In vitro fermentation characteristics and methane production. Animal Feed Science and Technology, 166-167, 269-274.
Mach, N., Bach, A., & Devant, M. (2009). Effects of crude glycerin supplementation on performance and meat quality of Holstein bulls fed high-concentrate diets. Journal of Animal Science, 87(2), 632-638.
McGeough, E. J., O’Kiely, P., Hart, K. J., Moloney, A. P., Boland, T. M., & Kenny, D. A. (2010). Methane emissions, feed intake, performance, digestibility, and rumen fermentation of finishing beef cattle offered whole-crop wheat silages differing in grain content. Journal of Animal Science, 88(8), 2703-2716.
Meale, S. J., Chaves, A. V., Ding, S., Bush, R. D., & McAllister, T. A. (2013). Effects of crude glycerin supplementation on wool production, feeding behavior, and body condition of Merino ewes. Journal of Animal Science, 91(2), 878-885.
Mertens, D. R. (1997). Creating a system for meeting the fiber requirements of dairy cows. Journal of Dairy Science, 80(7), 1463-1481.
Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science, 62(10), 1583-1586.
National Research Council [NRC]. (2000). Nutrient requirements of beef cattle (7th ed., rev.). Washington, DC: The National Academies Press.
Ørskov, E. R. (1986). Starch digestion and utilization in ruminants. Journal of Animal Science, 63(5), 1624-1633.
Palmquist, D. L., & Conrad, H. R. (1971). Origin of plasma fatty acids in lactating cows fed high grain or high fat diets. Journal of Dairy Science, 54(7), 1025-1033.
Parsons, G. L., Shelor, M. K., & Drouillard, J. S. (2009). Performance and carcass traits of finishing heifers fed crude glycerin. Journal of Animal Science, 87(2), 653-657.
Quicke, G. V., Bentley, O. G., Scott, H. W., Johnson, R. R., & Moxon, A. L. (1959). Digestibility of soybean hulls and flakes and the in vitro digestibility of the cellulose in various milling by-products. Journal of Dairy Science, 42(1), 185-186.
Ramos, M. H., & Kerley, M. S. (2012). Effect of dietary crude glycerol level on ruminal fermentation in continuous culture and growth performance of beef calves. Journal of Animal Science, 90(3), 892-899.
Rémond, B., Souday, E., & Jouany, J. P. (1993). In vitro and in vivo fermentation of glycerol by rumen microbes. Animal Feed Science and Technology, 41(2), 121-132.
Sarwar, M., Firkins, J. L., & Eastridge, M. L. (1992). Effects of varying forage and concentrate carbohydrates on nutrient digestibilities and milk production by dairy cows. Journal of Dairy Science, 75(6), 1533-1542.
Shin, J. H., Wang, D., Kim, S. C., Adesogan, A. T., & Staples, C. R. (2012). Effects of feeding crude glycerin on performance and ruminal kinetics of lactating Holstein cows fed corn silage or cottonseed hull-based, low-fiber diets. Journal of Dairy Science , 95(7), 4006-4016.
Stewart, C. S., Flint, H. J., & Bryant, M. P. (1997) The rumen bacteria. In P. N. Hobson, & C. S. Stewart, (Ed.), The rumen microbial ecosystem (2nd ed., p. 10-72). London, UK: Blackie Academic and Professional.
Tremere, A. W., Merrill, W. G., & Loosli, J. K. (1968). Adaptation to high concentrate feeding as related to acidosis and digestive disturbances in dairy heifers. Journal of Dairy Science , 51(7), 1065-1072.
Valadares Filho, S. C. (2006). Tabelas brasileiras de composição de alimentos para bovinos Viçosa, MG: UFV.
Van Kessel, J. A. S., & Russell, J. B. (1996). The effect of pH on ruminal methanogenesis. FEMS Microbiology Ecology, 20(4), 205-210.
Van Soest, P. J., Robertson, J. B., & Lewis, B. A. (1991). Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science , 74(10), 3583-3597.
Walsh, K., O’Kiely, P., Taweel, H. Z., McGee, M., Moloney, A. P., & Boland, T. M. (2009). Intake, digestibility and rumen characteristics in cattle offered whole-crop wheat or barley silages of contrasting grain to straw ratios. Animal Feed Science and Technology, 148(2-4), 192-213.
Wang, C., Liu, Q., Yang, W. Z., Huo, W. J., Dong, K. H., Huang, Y. X., ... He, D. C. (2009). Effects of glycerol on lactation performance, energy balance and metabolites in early lactation Holstein dairy cows. Animal Feed Science and Technology, 151(1), 12-20.

Publication Dates

Publication in this collection
Mar 2017

History

Received
28 July 2016
Accepted
13 Sept 2016

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Abo El-Nor, S., AbuGhazaleh, A. A., Potu, R. B., Hastings, D., & Khattab, M. S. A. (2010). Effects of differing levels of glycerol on rumen fermentation and bacteria. Animal Feed Science and Technology, 162(3), 99-105.

[2] Association Official Analytical Chemist [AOAC]. (2005). Official methods of analysis (18th ed.). Gaitherburg, MD: AOAC.

[3] Avila, J. S., Chaves, A. V., Hernandez-Calva, M., Beauchemin, K. A., McGinn, S. M., Wang, Y., ... McAllister, T. A. (2011). Effects of replacing barley grain in feedlot diets with increasing levels of glycerol on in vitro fermentation and methane production. Animal Feed Science and Technology, 166, 265-268.

[4] Avila-Stagno, J., Chaves, A. V., He, M. L., Harstad, O. M., Beauchemin, K. A., McGinn, S. M., & McAllister, T. A. (2013). Effects of increasing concentrations of glycerol in concentrate diets on nutrient digestibility, methane emissions, growth, fatty acid profiles, and carcass traits of lambs. Journal of Animal Science, 91(2), 829-837.

[5] Bartoň, L., Bureš, D., Homolka, P., Jančík, F., Marounek, M., & Řehák, D. (2013). Effects of long-term feeding of crude glycerine on performance, carcass traits, meat quality, and blood and rumen metabolites of finishing bulls. Livestock Science, 155(1), 53-59.

[6] Cole, N. A., & Hutcheson, D. (1985). Influence of prefast feed intake on recovery from feed and water deprivation by beef steers. Journal of Animal Science, 60(3), 772-780.

[7] Cruz, O. T. B., Valero, M. V., Zawadzki, F., Rivaroli, D. C., Prado, R. M., Lima, B. S., & Prado, I. N. (2014). Effect of glycerine and essential oils (Anacardium occidentale and Ricinus communis) on animal performance, feed efficiency and carcass characteristics of crossbred bulls finished in a feedlot system. Italian Journal of Animal Science, 13, 790-797.

[8] DeFrain, J. M., Hippen, A. R., Kalscheur, K. F., & Jardon, P. W. (2004). Feeding glycerol to transition dairy cows: effects on blood metabolites and lactation performance. Journal of Dairy Science, 87(12), 4195-4206.

[9] Donkin, S. S., Koser, S. L., White, H. M., Doane, P. H., & Cecava, M. J. (2009). Feeding value of glycerol as a replacement for corn grain in rations fed to lactating dairy cows. Journal of Dairy Science, 92(10), 5111-5119.

[10] Eiras, C. E., Barbosa, L. P., Marques, J. A., Lima, B. S., Zawadzki, F., Perotto, D., & Prado, I. N. (2014 ). Glycerine levels in the diets of crossbred bulls finished in feedlot: apparent digestibility, feed intake and animal performance. Animal Feed Science and Technology, 197, 222-226.

[11] Eiras, C. E., Marques, J. A., Torrecilhas, J. A., Zawadzki, F., Moletta, J. L., & Prado, I. N. (2013). Glycerin levels in the diets of crossbred bulls finished in feedlot: ingestion behavior, feeding intake and ruminal efficiency. Acta Scientiarum. Animal Sciences, 35(4), 411-416.

[12] Farias, M. S., Prado, I. N., Valero, M. V., Zawadzki, F., Silva, R. R., Eiras, C. E., ... Lima, B. S. (2012). Níveis de glicerina para novilhas suplementadas em pastagens: desempenho, ingestão, eficiência alimentar e digestibilidade. Semina: Ciências Agrárias, 33(3), 1177-1188.

[13] Fenner, H. (1965). Method for determining total volatile bases in rumen fluid by steam distillation. Journal of Dairy Science, 48(2), 249-251.

[14] Hales, K. E., Kraich, K. J., Bondurant, R. G., Meyer, B. E., Luebbe, M. K., Brown, M. S., ... McDonald, J. C. (2013). Effects of glycerin on receiving performance and health status of beef steers and nutrient digestibility and rumen fermentation characteristics of growing steers. Journal of Animal Science, 91(9), 4277-4289.

[15] Hsu, J. T., Faulkner, D. B., Garleb, K. A., Barclay, R. A., Fahey Jr., G. C., & Berger, L. L. (1987). Evaluation of corn fiber, cottonseed hulls, oat hulls and soybean hulls as roughage sources for ruminants. Journal of Animal Science, 65(1), 244-255.

[16] Ipharraguerre, I. R., & Clark, J. H. (2003). Soyhulls as an alternative feed for lactating dairy cows: a review. Journal of Dairy Science, 86(4), 1052-1073.

[17] Iraira, S. P., Torre, J. L. R., Rodríguez-Prado, M., Calsamiglia, S., Manteca, X., & Ferret, A. (2013). Feed intake, ruminal fermentation, and animal behavior of beef heifers fed forage free diets containing nonforage fiber sources. Journal of Animal Science, 91(8), 3827-3835.

[18] Johnson, K. A., & Johnson, D. E. (1995). Methane emissions from cattle. Journal of Animal Science, 73(8), 2483-2492.

[19] Krause, K. M., & Oetzel, G. R. (2006). Understanding and preventing subacute ruminal acidosis in dairy herds: A review. Animal Feed Science and Technology, 126(3), 215-236.

[20] Lana, R. P., Russell, J. B., & Van Amburgh, M. E. (1998). The role of pH in regulating ruminal methane and ammonia production. Journal of Animal Science, 76(8), 2190-2196.

[21] Lee, S. Y., Lee, S. M., Cho, Y. B., Kam, D. K., Lee, S. C., Kim, C. H., & Seo, S. (2011). Glycerol as a feed supplement for ruminants: In vitro fermentation characteristics and methane production. Animal Feed Science and Technology, 166-167, 269-274.

[22] Mach, N., Bach, A., & Devant, M. (2009). Effects of crude glycerin supplementation on performance and meat quality of Holstein bulls fed high-concentrate diets. Journal of Animal Science, 87(2), 632-638.

[23] McGeough, E. J., O’Kiely, P., Hart, K. J., Moloney, A. P., Boland, T. M., & Kenny, D. A. (2010). Methane emissions, feed intake, performance, digestibility, and rumen fermentation of finishing beef cattle offered whole-crop wheat silages differing in grain content. Journal of Animal Science, 88(8), 2703-2716.

[24] Meale, S. J., Chaves, A. V., Ding, S., Bush, R. D., & McAllister, T. A. (2013). Effects of crude glycerin supplementation on wool production, feeding behavior, and body condition of Merino ewes. Journal of Animal Science, 91(2), 878-885.

[25] Mertens, D. R. (1997). Creating a system for meeting the fiber requirements of dairy cows. Journal of Dairy Science, 80(7), 1463-1481.

[26] Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science, 62(10), 1583-1586.

[27] National Research Council [NRC]. (2000). Nutrient requirements of beef cattle (7th ed., rev.). Washington, DC: The National Academies Press.

[28] Ørskov, E. R. (1986). Starch digestion and utilization in ruminants. Journal of Animal Science, 63(5), 1624-1633.

[29] Palmquist, D. L., & Conrad, H. R. (1971). Origin of plasma fatty acids in lactating cows fed high grain or high fat diets. Journal of Dairy Science, 54(7), 1025-1033.

[30] Parsons, G. L., Shelor, M. K., & Drouillard, J. S. (2009). Performance and carcass traits of finishing heifers fed crude glycerin. Journal of Animal Science, 87(2), 653-657.

[31] Quicke, G. V., Bentley, O. G., Scott, H. W., Johnson, R. R., & Moxon, A. L. (1959). Digestibility of soybean hulls and flakes and the in vitro digestibility of the cellulose in various milling by-products. Journal of Dairy Science, 42(1), 185-186.

[32] Ramos, M. H., & Kerley, M. S. (2012). Effect of dietary crude glycerol level on ruminal fermentation in continuous culture and growth performance of beef calves. Journal of Animal Science, 90(3), 892-899.

[33] Rémond, B., Souday, E., & Jouany, J. P. (1993). In vitro and in vivo fermentation of glycerol by rumen microbes. Animal Feed Science and Technology, 41(2), 121-132.

[34] Sarwar, M., Firkins, J. L., & Eastridge, M. L. (1992). Effects of varying forage and concentrate carbohydrates on nutrient digestibilities and milk production by dairy cows. Journal of Dairy Science, 75(6), 1533-1542.

[35] Shin, J. H., Wang, D., Kim, S. C., Adesogan, A. T., & Staples, C. R. (2012). Effects of feeding crude glycerin on performance and ruminal kinetics of lactating Holstein cows fed corn silage or cottonseed hull-based, low-fiber diets. Journal of Dairy Science , 95(7), 4006-4016.

[36] Stewart, C. S., Flint, H. J., & Bryant, M. P. (1997) The rumen bacteria. In P. N. Hobson, & C. S. Stewart, (Ed.), The rumen microbial ecosystem (2nd ed., p. 10-72). London, UK: Blackie Academic and Professional.

[37] Tremere, A. W., Merrill, W. G., & Loosli, J. K. (1968). Adaptation to high concentrate feeding as related to acidosis and digestive disturbances in dairy heifers. Journal of Dairy Science , 51(7), 1065-1072.

[38] Valadares Filho, S. C. (2006). Tabelas brasileiras de composição de alimentos para bovinos Viçosa, MG: UFV.

[39] Van Kessel, J. A. S., & Russell, J. B. (1996). The effect of pH on ruminal methanogenesis. FEMS Microbiology Ecology, 20(4), 205-210.

[40] Van Soest, P. J., Robertson, J. B., & Lewis, B. A. (1991). Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science , 74(10), 3583-3597.

[41] Walsh, K., O’Kiely, P., Taweel, H. Z., McGee, M., Moloney, A. P., & Boland, T. M. (2009). Intake, digestibility and rumen characteristics in cattle offered whole-crop wheat or barley silages of contrasting grain to straw ratios. Animal Feed Science and Technology, 148(2-4), 192-213.

[42] Wang, C., Liu, Q., Yang, W. Z., Huo, W. J., Dong, K. H., Huang, Y. X., ... He, D. C. (2009). Effects of glycerol on lactation performance, energy balance and metabolites in early lactation Holstein dairy cows. Animal Feed Science and Technology, 151(1), 12-20.

Item	40% concentrate			60% concentrate
Item	CO	CGC	CGSH	CO	CGC	CGSH
Ingredient, % of DM
Corn silage	60.0	60.0	60.0	40.0	40.0	40.0
Corn	26.3	16.0	-	46.4	36.1	-
Soybean meal	10.0	10.0	10.0	10.0	10.0	10.0
Soybean hulls	-	-	16.2	-	-	36.6
Crude glycerine	-	10.0	10.0	-	10.0	10.0
Urea/ammonium sulfate	0.70	1.00	0.80	0.60	0.90	0.40
Mineral premix²	3.0	3.0	3.0	3.0	3.0	3.0
Nutrient composition, %
DM	57.6	57.9	58.6	67.1	67.4	68.9
CP	14.3	14.7	14.6	14.5	14.2	14.1
NDF	30.1	28.5	37.6	25.2	23.6	43.0
EE³	3.13	3.01	2.92	3.18	3.05	2.83
NFC⁴	47.0	49.5	40.1	53.9	55.5	35.5
ME, Mca L kg^-1	2.56	2.54	2.50	2.68	2.67	2.60

Item	40% of concentrate			60% of concentrate				P-value²
Item	CO	CGC	CGSH	CO	CGC	CGSH	SEM	CL	Diet 10 vs. 0%	Diet corn vs. hulls	CL by diet 10 vs. 0%	CL by diet corn vs. hulls
DMI, kg day^-1	6.53	7.41	6.73	7.85	6.64	6.65	0.51	0.67	0.37	0.42	0.02	0.41
DMD, %³	51.86	59.46	55.79	59.28	57.27	52.15	4.00	0.89	0.84	0.23	0.16	0.84
NDFD, %⁴	34.85	40.94	41.76	42.94	42.63	39.25	6.72	0.73	0.63	0.82	0.51	0.74

Item	40% of concentrate			60% of concentrate				P-value²
Item	CO	CGC	CGSH	CO	CGC	CGSH	SEM	CL	Diet 10 vs. 0%	Diet corn vs. hulls	CL by diet 10 vs. 0%	CL by diet corn vs. hulls
pH	6.28	6.24	6.16	5.93	5.99	5.92	0.09	<0.01	0.40	0.05	0.11	0.80
NH₃-N (MG dL^-1)	17.63	17.62	15.10	17.09	16.29	14.13	0.79	0.14	0.03	0.01	0.76	0.76
Acetate	69.36	62.41	62.86	64.98	59.55	63.12	0.99	0.01	<0.01	0.01	0.04	0.06
Propionate	18.71	20.71	21.16	21.86	23.72	22.50	1.08	<0.01	<0.01	0.37	0.22	0.06
Butyrate	13.90	19.21	17.47	14.90	18.03	16.14	0.83	0.15	<0.01	<0.01	0.01	0.84
A:P ratio³	3.67	2.99	3.04	3.04	2.56	2.89	0.15	<0.01	<0.01	0.02	0.02	0.09

Brasil

Brasil

Ruminal fermentation of Nellore steers fed crude glycerine replacing starch vs. fibre-based energy ingredient in low or high concentrate diets

Fermentação ruminal de novilhos Nelore alimentados com glicerina bruta substituindo amido vs. ingrediente energético a base de fibra em dietas de baixo ou alto concentrado

ABSTRACT.

RESUMO.

Introduction

Material and methods

Results and discussion

Conclusion

Acknowledgements

References

Publication Dates

History