Rumen fermentation and nutrient flow to the omasum in Holstein cows fed extruded canola seeds treated with or without lignosulfonate

Santos, Wallacy Barbacena Rosa dos; Santos, Geraldo Tadeu dos; Neves, Carolina Antunes; De Marchi, Francilaine Eloise; Silva-Kazama, Daniele Cristina da; Ítavo, Luís Carlos Vinhas; Damasceno, Julio Cesar; Petit, Hélène Veronique

doi:10.1590/S1516-35982012000700026

Abstract

Four multiparous Holstein cows averaging 548 kg of body weight and 74 d in lactation were used in a Latin square design with four 21-d experimental periods to determine effects of feeding extruded versus non-extruded canola seed, with or without 50 g/kg lignosulfonate on rumen fermentation, nutrient flow to the omasum, and degradability of dry matter (DM) and N of each diet. The DM effective degradability increased with extrusion and lignosulfonate treatment had no effect. The effective degradability of N was similar between diets. Lignosulfonate treatment of extruded versus non-extruded canola seeds decreased ruminal and total tract apparent digestibility of organic matter. The lowest apparent ruminal and highest intestinal digestibilities of protein, expressed as a percentage of N intake were observed for cows fed extruded canola seeds without lignosulfonate. Lignosulfonate treatment and extrusion had no effect on pH and concentrations of ammonia N and volatile fatty acids in the rumen. Results suggest that extruded canola seed untreated with formaldehyde may stimulate efficiency of microbial protein synthesis and is an effective means of increasing the availability of protein in the small intestine without affecting the total tract apparent digestibility of protein.

chemical treatment; digestion; heat treatment; oilseed

RUMINANTS

Rumen fermentation and nutrient flow to the omasum in Holstein cows fed extruded canola seeds treated with or without lignosulfonate¹ 1 Project financed by Fundação Araucária, and MCT-CNPq, PRONEX, 2007.

Wallacy Barbacena Rosa dos Santos^I; Geraldo Tadeu dos Santos^II; Carolina Antunes Neves^II; Francilaine Eloise De Marchi^II; Daniele Cristina da Silva-Kazama^III; Luís Carlos Vinhas Ítavo^IV; Julio Cesar Damasceno^II; Hélène Veronique Petit^V

^IDepartamento de Produção Animal, IFAM, Maués, AM, Brasil

^IIDepartamento de Zootecnia, UEM, Maringá, PR, Brasil

^IIIDepartamento de Zootecnia e Desenvolvimento Rural, UFSC, Florianópolis, SC, Brasil

^IVDepartamento de Zootecnia, UCDB, Campo Grande, MS, Brasil

^VDairy and Swine Research and Development Centre, Agriculture and Agri-Food Canada, QC, Canada

ABSTRACT

Four multiparous Holstein cows averaging 548 kg of body weight and 74 d in lactation were used in a Latin square design with four 21-d experimental periods to determine effects of feeding extruded versus non-extruded canola seed, with or without 50 g/kg lignosulfonate on rumen fermentation, nutrient flow to the omasum, and degradability of dry matter (DM) and N of each diet. The DM effective degradability increased with extrusion and lignosulfonate treatment had no effect. The effective degradability of N was similar between diets. Lignosulfonate treatment of extruded versus non-extruded canola seeds decreased ruminal and total tract apparent digestibility of organic matter. The lowest apparent ruminal and highest intestinal digestibilities of protein, expressed as a percentage of N intake were observed for cows fed extruded canola seeds without lignosulfonate. Lignosulfonate treatment and extrusion had no effect on pH and concentrations of ammonia N and volatile fatty acids in the rumen. Results suggest that extruded canola seed untreated with formaldehyde may stimulate efficiency of microbial protein synthesis and is an effective means of increasing the availability of protein in the small intestine without affecting the total tract apparent digestibility of protein.

Key Words: chemical treatment, digestion, heat treatment, oilseed

Introduction

Heat treatment is commonly used to protect oilseeds from ruminal degradation (Mustafa et al., 2002; Abu-Ghazaleh et al., 2002a,b). Kennelly (1996) suggested that the application of heat to highly fat products such as oilseeds can denature the protein matrix surrounding the fat droplets, thus preventing the access of ruminal bacteria to fatty acids, protecting the dietary fat from ruminal biohydrogenation. Extrusion is a method to heat-processed oilseeds that has the potential of reducing ruminal crude protein (CP) degradability (Petit et al., 1999) and N solubility (Chouinard et al., 1997a) as shown for full fat soybeans. Moreover, extrusion results in a slow-release of linoleic acid from full-fat soybeans in the rumen (Peterson et al., 2002), with little effect on ruminal fermentation (Scott et al., 1991). However, previous results have shown that extrusion of canola seeds has no effect on total tract apparent digestibility, but it decreases milk fat concentration (Neves et al., 2009), which may result in a potential negative effect of extruding canola seeds on ruminal digestion.

Lignosulfonate, which is a by-product of the wood industry, decreases ruminal degradability of CP and increases the rumen undegradable CP concentration of full fat soybeans by up to 173% (Petit et al., 1999). However, there is little information on the effect of lignosulfonate treatment on ruminal degradability of ground canola seeds. Results from a previous experiment (Neves et al., 2009) showed that extrusion of canola seeds increased milk fat concentration of trans11-18:1 to a lower extent with, than without, lignosulfonate treatment (113 versus 150%) and that concentrations of cis9, trans11 conjugated linoleic acid and polyunsaturated fatty acids were similar between treatments. However, the concentration of trans11-18:1 increased with extrusion of full fat soybeans but not with lignosulfonate treatment and concentrations of cis9, trans11 conjugated linoleic acid and polyunsaturated fatty acids tended (P = 0.08 and P = 0.06, respectively) to increase with lignosulfonate treatment of full fat soybeans (Neves et al., 2007). Taken together, these results suggest that it is possible to modify the milk fatty acid composition by feeding extruded oilseeds, but the effect of lignosulfonate treatment on the milk fatty acid profile seems to differ depending on the type of oilseed treated. Enhanced comprehension of ruminal metabolism and nutrient utilization of extruded oilseeds treated with lignosulfonate will help to manipulate milk fatty acid profile. Although research has been conducted with supplementing canola to alter ruminal fermentation and N metabolism in the gastrointestinal tract, none could be found on effects of treating ground canola seeds with both extrusion and lignosulfonate.

The objectives of this experiment were to determine the effects of extrusion and lignosulfonate treatment of ground canola seeds on ruminal fermentation, ruminal degradability, and nutrient flow to the omasum in early-lactating dairy cows.

Material and Methods

Four rumen-fistulated multiparous Holstein cows averaging 548.1±66.9 kg of body weight and 74±12 days in lactation were assigned to a 4 × 4 Latin square design to determine the effects of extrusion and lignosulfonate treatment of canola seed on rumen fermentation, digestibility in the rumen, the intestine and the total tract, and degradability of dry matter (DM) and N of each diet. Each experimental period consisted of 14 d of adaptation to the diets and 7 d for sample collection. Cows were housed in tie stalls and fed individually (8 a.m. and 4 p.m.). Cows were weighed on the first and last days of each experiment period. A full description of the four diets was given by Neves et al. (2009). Briefly, the four total mixed diets (Table 1) consisted of supplements based on non-extruded canola seeds, extruded canola seeds, non-extruded canola seeds treated with 50 g/kg DM lignosulfonate or extruded canola seeds treated with 50 g/kg DM lignosulfonate.

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Feed intake was recorded daily and adjusted for 100 g/kg orts as fed. Samples of each diet were collected daily from day 15 to 20, frozen, and pooled on a period basis. Composite samples were mixed thoroughly and subsampled for chemical analyses. Fecal grab samples (100 g) obtained via rectal palpation and spot samples (ca. 500 mL) of the omasal digesta leaving the rumen were collected and accumulated for four consecutive days at 8, 12, 16 and 20 hours of each experimental period for days 16, 17, 18, and 19, respectively. The omasal sampling technique was similar to that of Huhtanen et al. (1997). Samples of feces and omasal digesta were kept at -20 ºC for further analyses. Indigestible neutral detergent fiber (iNDF) was the marker to measure omasal flow (Huhtanen et al., 1994). On day 21, rumen fluid samples were collected at 0, 2, 4, 6, and 8 hours from different sites within the rumen to obtain a total of around 200 mL. Ruminal contents were filtered with cheesecloth and the ruminal fluid pH was measured immediately (HI 931000 pH meter; Hanna Instruments, Ronchi di Villafranca, PD, Italy). Samples were acidified to pH 2 with 1 ml of 20% H₂SO₄ and frozen at -20 ºC for determination of volatile fatty acids (VFA) and ammonia N concentrations. Another sample of ruminal contents (ca. 3 kg) was collected from each cow from different sites within the rumen before the 08:00 h feeding and processed according to the procedure of Cecava et al. (1990) to determine microbial protein synthesis as described by Ushida et al. (1985).

Ruminal in situ incubations were carried out using three rumen fistulated multiparous cows fed the non-extruded untreated canola seeds. The diet was fed ad libitum for two weeks before the incubation trial. Samples of each of the four canola treatments were milled through a 2-mm screen and subsamples (6 g) were then placed in nitrogen-free polyester bags (10 × 20 cm) with a pore size of 50±15 µm (R1020 Ankom products; Ankom, Fairport, NY, USA). Samples of each canola treatment were incubated in the rumen of each cow for 72, 48, 36, 24, 12, 8, 6, 4, 2, and 0 h. The bags were inserted in reverse order of incubation period, so that they could all be removed at the same time (NRC, 2001). All bags were incubated in duplicate for each time point of incubation except for 72 h, when bags were incubated in triplicate to have enough residue for chemical analyses. All bags were attached to a stainless-steel weight of 540 g, and placed in the ventral sac of the rumen. Once the bags were removed from the rumen, they were immersed in 20-L buckets containing cold water, then washed in an automatic washing machine (40 min, 4 cycles; 5 × 1-min wash, 2-min spin) until the rinse water was clear. The bags (with residues) were then frozen.

Degradation of dry matter (DM) and N were calculated using the following first-order model with a lag of t₀ based on the model of McDonald (1981):

p = a if t < or = to,

p = a + b [1 e^(c(tt0))] if t > to,

where p = percentage disappearance at time t, a = the intercept representing the portion of DM or N solubilized at time 0, b = the fraction of DM or N that is potentially degradable in the rumen, c = the constant rate of disappearance of fraction b, and t = time on incubation. The nonlinear parameters a, b, c, and t₀ were estimated by an iterative least squares procedure of the software SAS (Statistical Analyses System, version 5.0), and best-fit values were chosen with the Secant method using the convergence criterion (10⁸) of SAS (Statistical Analyses System, version 5.0).

Values of effective degradability of DM (EDDM) and total N (EDTN) were calculated using the equation of Dhanoa et al. (1999) stated in terms of a, b, c, t₀, and k (the rumen outflow rate at 8% h¹).

EDMM or EDTN = a + bc (e^(k.t)) / (c + k)

Dry matter of the diets was determined in a forced-ventilation oven according to the procedure 934.01 (AOAC, 1990). Total mixed diets were ground to pass through 1-mm screen Wiley mill before analyses of N, ether extract (EE), acid detergent fiber (ADF), and neutral detergent fiber (NDF). Total N determination used a Tecnal TE036/1 (Piracicaba, São Paulo, Brazil) following procedure 990.03 of AOAC (1990). Concentrations of NDF and ADF, including those of residual ash were measured according to the nonsequential procedures of Van Soest et al. (1991) with the use of amylase but without sodium sulfite in the neutral detergent solution. Ether extraction in diets was conducted with Tecnal TE044/1 (Piracicaba São Paulo, Brazil) according to the method No. 7.060 of AOAC (1990). Indigestible NDF was used as an internal marker to estimate apparent nutrient digestibility and fecal output (Cochran et al., 1986; Dann et al., 2007). Preparation of feed, orts and fecal residues from in situ incubation followed by iNDF extraction was similar to the technique described by Ellis et al. (1984) for preparation of indigestible NDF (i.e., NDF remaining after 144 h of in situ incubation). Coefficients of apparent digestion of dietary components were determined by comparing dietary indigestible NDF concentration (corrected for that in orts) with fecal or omasal digesta indigestible NDF concentration as outlined by Cochran et al. (1986). Apparent digestibility in the small intestine was calculated as the difference between 100 and apparent digestibility in the rumen. Isolation of rumen bacteria was carried out following the procedure of Cecava et al. (1990).

All results were analyzed as a 4 × 4 Latin square design balanced for residual effect using the MIXED procedure of SAS (Statistical Analyses System, version 8.02) and with a 2 × 2 factorial arrangement of treatments. Data on in sacco degradability, intake, omasal flow, ruminal, intestinal and total tract apparent digestibility, and ruminal fermentation parameters were analyzed using the following general model:

Y_ijk= μ + C_i + P_j+ T_k+ e_ijk

where: Y_ijk= the dependent variable, μ = overall mean, C_i = random effect of cow (i = 1 to 4), P_j = fixed effect of period (k = 1 to 4), T_k = fixed effect of treatment (k = non-extruded untreated canola seeds, extruded untreated canola seeds, non-extruded canola seeds treated with 50 g/kg DM of lignosulfonate and extruded canola seeds treated with 50 g/kg DM of lignosulfonate), and e_ijk = random residual error. Data on ruminal pH, ammonia concentration and VFAs were analyzed as repeated measurements. The compound symmetry was used as the covariance structure. Treatments were compared to provide factorial contrasts: 1) non-extruded versus extruded canola, 2) with versus without lignosulfonate, and 3) the interaction between extrusion and lignosulfonate treatment. Significance was declared at P<0.05 and a trend was accepted at P£0.10, unless otherwise stated.

Results and Discussion

There was a trend (P = 0.09) for an interaction between extrusion and lignosulfonate for the rapidly (a) degradable fraction of DM; extruding canola seeds with lignosulfonate increased the rapidly degradable fraction of DM and there was no effect of extrusion in the absence of lignosulfonate (Table 2). Adding lignosulfonate to canola seeds had no effect on the slowly (b) degradable fraction and the rate of degradation of DM. On the other hand, extrusion of canola seeds decreased the slowly (b) degradable fraction of DM with no effect on the rate of degradation.

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There was a significant interaction between extrusion and lignosulfonate for the rapidly (a) degradable fraction of N and there was a trend (P = 0.08) for the slowly (b) degradable fraction of N. The lowest (a) and highest (b) values of N were obtained for extruded canola seeds treated with lignosulfonate. The rate of N degradation was similar between diets.

The fact that extrusion increased the percentage of DM solubilized at initiation of ruminal incubation and decreased the percentage of DM potentially degradable in the rumen is in agreement with results previously reported by Petit et al. (1997) for canola seeds. The percentage of DM solubilized at initiation of ruminal incubation was increased with extrusion in the presence of lignosulfonate while the percentage of CP solubilized at initiation of ruminal incubation was decreased. These results may suggest that the higher fraction of DM solubilized at initiation of ruminal incubation was not due to higher solubilization of the protein fraction but to a higher release of the lipid fraction. Processes such as extrusion have been shown to increase the release of oil from soybeans (Mohamed et al., 1988). Moreover, Chouinard et al. (1997b) reported a greater accumulation of trans intermediates isomers in milk fat of cows fed extruded compared with micronized soybeans and roasted soybeans, which may result from greater release of fat in the rumen that led to lipolysis and biohydrogenation of fatty acids by rumen microorganisms (Griinari & Bauman, 1999).

Extrusion has been used to protect the protein of leguminous grains, such as peas, lupins and soybeans (Poncet & Rémond, 2002) from ruminal degradation, but the effect on oilseeds rich in lipids has seldom been observed. Ferlay et al. (1992) found no effect of extrusion at 140 ºC on protein degradability of rapeseeds. Moreover, Deacon et al. (1988) found that extrusion increased the in situ soluble fraction of protein from canola seed although there were no differences in ruminal DM and N degradabilities between non-extruded versus extruded canola seed. Several researchers have reported that extrusion is less effective than other heat treatments such as roasting in protecting oilseeds from ruminal degradation (Pena et al., 1986; Reddy et al., 1994).

Lignosulfonate, which is a by-product of the wood industry, decreased the percentage of N solubilized at initiation of ruminal incubation of extruded versus non-extruded canola seeds. Previous results have shown that lignosulfonate decreases ruminal degradability and increases the rumen undegradable CP concentration of full fat soybeans (Petit et al., 1999). Moreover, according to Windschitl & Stern (1988), the effective ruminal CP degradability of soybean meal treated with 50 g/kg DM lignosulfonate and heated at 90-95 °C for 45 min was significantly decreased when compared with untreated soybean meal. Similarly, treatment of canola screenings with 50 g/kg DM lignosulfonate and heat at 100 °C for 60 min (von Keyserlingk et al., 2000) and of canola meal with 50 g/kg DM lignosulfonate and heat at 100 °C for 60 to 120 min (McAllister et al., 1993) effectively reduced degradation of DM and CP in the rumen. Rumen protection of CP usually parallels fat, as a protein-rich matrix surrounds the fat droplets of oilseeds (Khorasani et al., 1992). This led us to hypothesize that protection of protein against ruminal degradability with lignosulfonate treatment could overcome the negative effects of a greater release of oil with extrusion on ruminal digestion. Protection of protein against ruminal degradability on the diet of extruded canola seeds treated with 50 g/kg DM of lignosulfonate is corroborated by extruded canola seeds treated with lignosulfonate that resulted in the lowest fraction of N solubilized at initiation of ruminal incubation. As a result, N duodenal flow was higher for cows fed extruded versus non-extruded canola seeds without lignosulfonate. This is in agreement with the greater N flow in the duodenum observed for cows fed diets with protein of lower ruminal degradability (Zerbini et al., 1988).

Daily intake and total omasal flow of DM averaged, respectively, 14.5 kg and 8.96 kg and they were similar between treatments (Table 3). There was a significant interaction between extrusion and lignosulfonate and there was a trend (P = 0.06), respectively, for ruminal digestibility of DM and intestinal digestibility of DM, expressed as a percentage of DM intake. Cows fed extruded canola untreated with lignosulfonate had the lowest DM digestibility in the rumen and the highest DM intestinal digestibility, expressed as a percentage of intake. Digestibility in the intestine, expressed as a percentage of DM omasal flow, tended (P = 0.05) to decrease with lignosulfonate treatment.

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The lack of an extrusion effect on feed intake agrees with Bayourthe et al. (2000) for cows fed extruded versus whole canola seeds. Similarly, lignosulfonate treatment of soybean meal had no effect on dry matter intake of cows (Windshitl & Stern, 1988; Mansfield & Stern, 1994; Wright et al., 2005).

The lignosulfonate treatment could contribute to decreasing the amount or rate of release of fat in the rumen, which will overcome the negative effect of extrusion on ruminal digestibility and result in similar ruminal and total tract apparent digestibility of OM for cows fed non-extruded canola seeds treated or not with lignosulfonate versus extruded canola seeds treated with lignosulfonate. However, extrusion of rapeseeds fed at 145 g/kg DM (Ferlay et al., 1992) and lignosulfonate treatment of soybean meal and soybean hulls (Mansfield & Stern, 1994) had no effect on ruminal digestibility, duodenal flow, and total tract apparent digestibility of OM. The conditions of treatment may be responsible for discrepancies between experiments. For example, the effect of extrusion on release of oil in the rumen differs according to the temperature used for treating as shown for soybeans (Chouinard et al., 1997a; Petit et al., 1999). The lack of a lignosulfonate effect on intestinal digestibility of OM agrees with results of Windshitl & Stern (1988) for cows fed soybean meal.

The total tract apparent digestibility was similar between treatments. Organic matter intake was similar between treatments (Table 3). There was a significant interaction between extrusion and lignosulfonate for total OM omasal flow, and cows fed extruded canola untreated with lignosulfonate had the highest flow. Ruminal digestibility of organic matter, expressed as a percentage of organic matter intake, tended (P = 0.08) to be lower for cows fed extruded canola untreated with lignosulfonate as shown by the trend for the interaction between extrusion and lignosulfonate. Treating canola with lignosulfonate tended (P = 0.10) to decrease OM intestinal digestibility, expressed as a percentage of OM intake.

Organic matter intestinal digestibility, expressed as a percentage of omasal flow, OM apparently digested in the rumen, expressed in kilogram per day, and OM truly digested in the rumen, expressed in kilogram per day and as a percentage of organic matter intake, were similar between diets. Total tract apparent digestibility of OM, expressed as a percentage of intake, decreased with extrusion in the absence of lignosulfonate, while extrusion had no effect with the lignosulfonate treatment.

Ether extract intake, expressed in kilogram per day, was significantly higher for cows fed extruded canola untreated with lignosulfonate (Table 4). Extrusion and lignosulfonate treatment had no effect on total omasal flow, ruminal, intestinal and total tract apparent digestibility, expressed as a percentage of intake and intestinal digestibility, expressed as a percentage of omasal flow, of ether extract.

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Nitrogen intake was similar between treatments (Table 5). The highest omasal N flow and microbial N flow, expressed in grams per day, were observed for cows fed extruded canola untreated without lignosulfonate as shown by the significant interaction between extrusion and lignosulfonate. Non-microbial N flow, expressed in g per day, was similar between diets. Duodenal N flow, expressed as a percentage of intake, tended (P = 0.05) also to reach the highest value for cows fed extruded untreated canola seeds.

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There was an interaction between extrusion and lignosulfonate for microbial efficiency, expressed in g of N per kg of organic matter apparently or truly digested in the rumen, and the highest values were obtained for cows fed extruded untreated canola seeds. The lowest apparent ruminal and highest intestinal digestibilities, expressed as a percentage of N intake, were observed for cows fed extruded untreated canola seeds. True ruminal digestibility, intestinal digestibility, expressed as a percentage of omasal flow, and total tract apparent digestibility of N were similar among treatments.

Microbial N flow to the duodenum and efficiency of microbial protein synthesis have been shown to decrease when treating soybean meal with lignosulfonate (Windshitl & Stern, 1988). In the present experiment, treating extruded canola seeds with lignosulfonate may have protected seeds against degradability and/or fat release in the rumen as discussed previously, while extruded canola seeds with no formaldehyde had no protection, which led to higher microbial N and total N flow to the duodenum and lower N apparent ruminal digestibility. Increased efficiency of microbial protein synthesis also was found with extruded versus non-extruded canola seeds untreated with formaldehyde. According to Murphy et al. (1987), increased efficiency of microbial protein synthesis is a result of fat supplementation of the diet and results of the present experiment suggest that fat from extruded versus non-extruded canola seeds untreated with formaldehyde was more available in the rumen. The higher N duodenal flow with extruded versus non-extruded canola seeds untreated with formaldehyde was a result of higher microbial N flow in the duodenum as there was no difference in non-microbial N flow in the duodenal between diets, which resulted in improved microbial protein synthesis.

There was a shift in digestibility of N from the rumen to the small intestine with extruded versus non-extruded canola seeds untreated with formaldehyde, which may increase the amount of rumen bypass protein available to the cows. This agrees with results of Solanas et al. (2005), who reported that residues from ruminal incubation of extruded versus non-extruded feeds such as soybeans and lupins had higher intestinal N digestibility. However, there was no difference in intestinal N digestibility between extruded versus non-extruded canola seeds treated with the formaldehyde treatment. This disagrees with von Keyserlingk et al. (2000), who observed an increase in intestinal CP disappearance of lignosulfonate-treated canola screenings when compared with untreated canola screenings, although the total tract apparent digestibility of CP was not affected by the 50 g/kg DM lignosulfonate treatment, as observed in the present experiment.

The lack of an extrusion effect on ruminal digestibility of ether extract is in agreement with results of Bauchart et al. (1990), who observed similar duodenal flows of linoleic acid at the duodenum between diets containing raw versus extruded rapeseeds. Moreover, Gonthier et al. (2004) found no effect of extrusion of flaxseed on ruminal digestibility, post-ruminal digestibility and total tract apparent digestibility of fatty acids. Similarly, Scott et al. (1991) found no effect of extrusion of soybeans on the total tract apparent digestibility of fatty acids.

There was no interaction between extrusion and lignosulfonate and between treatment and sampling time for any parameters of ruminal fermentation (Table 6). Ruminal pH, logpH, concentrations of ammonia, total volatile fatty acids (VFA), and molar proportions of VFA were similar between treatments. Treatment with lignosulfonate tended (P = 0.09) to decrease the acetate-to-propionate ratio in the rumen.

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The lack of an extrusion effect on ruminal pH, total VFA, and molar proportions of individual VFA disagrees with results of Khorasani & Kennelly (1998), who reported trends for higher ruminal pH and lower total VFA concentrations and molar percentages of propionate with an increased amount of canola seeds from 0 to 145 g/kg DM in the diet of dairy cows.

Changes in the proportions of propionate and acetate in the rumen with canola seed supplementation (Leupp et al., 2006) have been attributed to a decrease in ruminal fiber digestion. However, although there was a trend towards lower acetate-to-propionate ratio with the lignosulfonate treatment in the present experiment, there was no difference in the total tract apparent digestibility of fiber between diets (Neves et al., 2009). Lignosulfonate has been shown to decrease protein degradability in the rumen (Windschitl & Stern, 1988), which decreases ammonia N in the rumen (Zerbini et al., 1988). However, in the present experiment, effective degradability of N was not affected by lignosulfonate or extrusion, which may explain that ammonia N concentration in the rumen was similar between treatments.

Conclusions

Fat supplementation from canola seeds at 140 g/kg DM in the form of extruded vs non-extruded and untreated vs treated with 50 g/kg DM lignosulfonate had no effect on the flows of organic matter and ether extract to the duodenum. Moreover, results suggest that extruded canola seed untreated with formaldehyde may stimulate efficiency of microbial protein synthesis and is an effective means of increasimg the availability of protein in the small intestine without affecting the total tract apparent digestibility of protein.

Acknowledgements

The project was supported by Fundação Araucária, Curitiba, PR and CNPq, Brasilia, DF, under protocol no. 10913/2006, PRONEX/2006.

Received June 29, 2011 and accepted December 21, 2012.

Corresponding author: gtsantos@uem.br

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KHORASANI, G.R.; DE BOER, G.; ROBINSON, P.H. et al. Effect of canola fat on ruminal and total tract digestion, plasma hormones, and metabolites in lactating dairy cows. Journal of Dairy Science, v.75, p.492-501, 1992.
KHORASANI, G.R.; KENNELLY, J.J. Effect of added dietary fat on performance, rumen characteristics, and plasma metabolites of midlactation dairy cows. Journal of Dairy Science, v.81, p.2459-2468, 1998.
LEUPP, J.L.; LARDY, G.P.; SOTO-NAVARRO, S.A. et al. Effects of canola seed supplementation on intake, digestion, duodenal protein supply, and microbial efficiency in steers fed forage-based diets. Journal of Animal Science, v.84, p.499-507, 2006.
MANSFIELD, H.R.; STERN, M.D. Effects of soybean hulls and lignosulfonate-treated soybean meal on ruminal fermentation in lactating dairy cows. Journal of Dairy Science, v.77, p.1070-1083, 1994.
MCALLISTER, T.A.; CHENG, K.J.; BEAUCHEMIN, K.A. et al. Use of lignosulfonate to decrease the rumen degradability of canola meal protein. Canadian Journal of Animal Science, v.73, p.211-215, 1993.
MCDONALD, I. A revised model for the estimation of protein degradability in the rumen. Journal of Agricultural Science, v.96, p.251-252, 1981.
MOHAMED, O.E.; SATTER, L.D.; GRUMMER, R.R. et al. Influence of dietary cottonseed and soybean on milk production and composition. Journal of Dairy Science, v.71, p.2677-2688, 1988.
MURPHY, M.; UDEN, P.; PALMQUIST, D.L. et al. Rumen and total diet digestibilities in lactating cows fed diets containing full-fat rapeseed. Journal of Dairy Science, v.70, p.1572-1582, 1987.
MUSTAFA, A.F.; MCKINNON, J.J.; CHRISTENSEN, D.A. et al. Effects of micronization of flaxseed on nutrient disappearance in the gastrointestinal tract of steers. Animal Feed Science and Technology, v.95, p.123-132, 2002.
NATIONAL RESEARCH COUNCIL - NRC. Nutrient requirements of dairy cattle 7.rev.ed. Washington, D.C.: National Acaddmy Press, 2001. 381p.
NEVES, C.A.; SANTOS, G.T.D.; MATSUSHITA, M. et al. Intake, digestibility, milk production, and milk composition of Holstein cows fed extruded soybeans treated with lignosulfonate. Animal Feed Science and Technology, v.134, p.32-44, 2007.
NEVES, C.A.; DOS SANTOS, W.B.R.; SANTOS, G.T.D. et al. Production performance and milk composition of dairy cows fed extruded canola seeds treated with or without lignosulfonate. Animal Feed Science and Technology, v.154, p.83-92, 2009.
PENA, F.; TAGARI, H.; SATTER, L.D. The effect of heat treatment of whole cottonseed on site and extent of protein digestion in dairy cows. Journal of Dairy Science, v.62, p.1423-1433, 1986.
PETERSON, D.G.; KELSEY, J.A.; BAUMAN, D.E. Analysis of variation in cis-9, trans-11 conjugated linoleic acid (CLA) in milk fat of dairy cows. Journal of Dairy Science, v.85, p.2164-2172, 2002.
PETIT, H.V.; TREMBLAY, G.F.; TURCOTTE, M. et al. Degradability and digestibility of full-fat soybeans treated with different sugar and heat combinations. Can. Journal of Animal Science, v.79, p.213-220, 1999.
PETIT, H.V.; RIOUX, R.; D'OLIVEIRA, P.S. et al. Performance of growing lambs fed grass silage with raw or extruded soybean or canola seeds. Canadian Journal of Animal Science, v.77, p.455-463, 1997.
PONCET, C.; RÉMOND, D. Rumen digestion and intestinal nutrient flows in sheep consuming pea seeds: the effect of extrusion and of chestnut tannin addition. Animal Research, v.51, p.201-206, 2002.
REDDY, P.V.; MORRILL, J.L.; NAGARAJA, T.G. Release of free fatty acids from raw or processed soybeans and subsequent effects on fiber digestibilities. Journal of Dairy Science, v.77, p.3410-3416, 1994.
SCOTT, T.A.; COMBS, D.K.; GRUMMER, R.R. Effects of roasting, extrusion, and particle size on the feeding value of soybeans for dairy cows. Journal of Dairy Science, v.74, p.2555-2562, 1991.
SOLANAS, E.; CASTRILLO, C.; BALCELLS, J. et al. In situ ruminal degradability and intestinal digestion of raw and extruded legume seeds and soyba mean meal protein. Journal of Animal Physiology and Animal Nutrition, v.89, p.166-171, 2005.
USHIDA, K.; LALLALAS, B.; JOUANY, J.P. Determination of assay parameters for RNA analysis in bacterial and duodenal samples by spectrophotometry. Influence of sample treatment and preservation. Reproduction Nutrition Development, v.25, p.1037-1046., 1985.
VAN SOEST, P.J.; ROBERTSON, J.B.; LEWIS, B.A. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science, v.74, p.3583-3597, 1991.
VON KEYSERLINGK, M.A.G.; WEURDING, E.; SWIFT, M.L. Effect of adding lignosulfonate and heat to canola screenings on ruminal and intestinal disappearance of dry matter and crude protein. Journal Animal Science, v.80, p.215-219, 2000.
WINDSCHITL, P.M.; STERN, M.D. Evaluation of calcium lignosulfonate-treated soybean meal as a source of rumen-protected protein for dairy cattle. Journal of Dairy Science, v.71, p.3310-3325, 1988.
WRIGHT, C.F.; VON KEYSERLINGK, M.A.G.; SWIFT, M.L. et al. Heat- and lignosulfonate-treated canola meal as a source of ruminal undegradable protein for lactating dairy cows. Journal of Dairy Science, v.88, p.238-243, 2005.
ZERBINI, E.; POLAN, C.E.; HERBEIN, J.H. Effect of dietary soybean meal and fish meal on protein digesta flow in Holstein cows during early and midlactation. Journal of Dairy Science, v.71, p.1248-1258, 1988.

1

Project financed by Fundação Araucária, and MCT-CNPq, PRONEX, 2007.

Publication Dates

Publication in this collection
30 July 2012
Date of issue
July 2012

History

Received
29 June 2011
Accepted
21 Dec 2012

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

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[2] ABU-GHAZALEH, A.A.; SCHINGOETHE, D.J.; HIPPEN, A.R. et al. Fatty acid profiles of milk and rumen digesta from cows fed fish oil, extruded soybeans or their blend. Journal of Dairy Science, v.85, p.2266-2276, 2002b.

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[12] DEACON, M.A.; DE BOER, G.; KENNELLY, J.J. Influence of jet-Sploding and extrusion on ruminal and intestinal disappearance of canola and soybeans. Journal of Dairy Science, v.71, p.745-753, 1988.

[13] ELLIS, W.C.; BAILEY, E.M.; TAYLOL, C.A. A silicone esophageal cannula; its surgical installation and use in research with grazing cattle, sheep or goats. Journal of Animal Science, v.59, p.204-209, 1984.

[14] FERLAY, A.; LEGAY, F.; BAUCHART, D. et al. Effect of a supply of raw or extruded rapeseeds on digestion in dairy cows. Journal of Dairy Science, v.70, p.915-923, 1992.

[15] GONTHIER, C.; MUSTAFA, A.F.; BERTHIAUME, R. et al. Feeding micronized and extruded flaxseed to dairy cows: effects on digestion and ruminal biohydrogenation of long-chain fatty acids. Can. Journal of Animal Science, v.84, p.705-711, 2004.

[16] GRIINARI, J.M.; BAUMAN, D.E. Biosynthesis of conjugated linoleic acid and its incorporation into meat and milk in ruminants. In: YURAWECZ, M.P.; MOSSABA, M.M.; KRAMER, J.K.G. et al. (Eds.) Advances in conjugated linoleic acid research Champaign: AOCS Press, 1999. v.1, p.180-200.

[17] HUHTANEN, P.; KAUSTELL, K.; JAAKKOLA, S. The use of internal markers to predict total digestibility and duodenal flow of nutrients in cattle given six different diets. Animal Feed Science and Technology, v.48, p.211-227, 1994.

[18] HUHTANEN, P.; BROTZ, P.G.; SATTER, L.D. Omasal sampling technique for assessing fermentative digestion in the forestomach of dairy cows. Journal of Animal Science, v.75, p.1380-1392, 1997.

[19] KENNELLY, J.J. The fatty acid composition of milk fat as influenced by feeding oilseeds. Animal Feed Science and Technology, v.60, p.137-152, 1996.

[20] KHORASANI, G.R.; DE BOER, G.; ROBINSON, P.H. et al. Effect of canola fat on ruminal and total tract digestion, plasma hormones, and metabolites in lactating dairy cows. Journal of Dairy Science, v.75, p.492-501, 1992.

[21] KHORASANI, G.R.; KENNELLY, J.J. Effect of added dietary fat on performance, rumen characteristics, and plasma metabolites of midlactation dairy cows. Journal of Dairy Science, v.81, p.2459-2468, 1998.

[22] LEUPP, J.L.; LARDY, G.P.; SOTO-NAVARRO, S.A. et al. Effects of canola seed supplementation on intake, digestion, duodenal protein supply, and microbial efficiency in steers fed forage-based diets. Journal of Animal Science, v.84, p.499-507, 2006.

[23] MANSFIELD, H.R.; STERN, M.D. Effects of soybean hulls and lignosulfonate-treated soybean meal on ruminal fermentation in lactating dairy cows. Journal of Dairy Science, v.77, p.1070-1083, 1994.

[24] MCALLISTER, T.A.; CHENG, K.J.; BEAUCHEMIN, K.A. et al. Use of lignosulfonate to decrease the rumen degradability of canola meal protein. Canadian Journal of Animal Science, v.73, p.211-215, 1993.

[25] MCDONALD, I. A revised model for the estimation of protein degradability in the rumen. Journal of Agricultural Science, v.96, p.251-252, 1981.

[26] MOHAMED, O.E.; SATTER, L.D.; GRUMMER, R.R. et al. Influence of dietary cottonseed and soybean on milk production and composition. Journal of Dairy Science, v.71, p.2677-2688, 1988.

[27] MURPHY, M.; UDEN, P.; PALMQUIST, D.L. et al. Rumen and total diet digestibilities in lactating cows fed diets containing full-fat rapeseed. Journal of Dairy Science, v.70, p.1572-1582, 1987.

[28] MUSTAFA, A.F.; MCKINNON, J.J.; CHRISTENSEN, D.A. et al. Effects of micronization of flaxseed on nutrient disappearance in the gastrointestinal tract of steers. Animal Feed Science and Technology, v.95, p.123-132, 2002.

[29] NATIONAL RESEARCH COUNCIL - NRC. Nutrient requirements of dairy cattle 7.rev.ed. Washington, D.C.: National Acaddmy Press, 2001. 381p.

[30] NEVES, C.A.; SANTOS, G.T.D.; MATSUSHITA, M. et al. Intake, digestibility, milk production, and milk composition of Holstein cows fed extruded soybeans treated with lignosulfonate. Animal Feed Science and Technology, v.134, p.32-44, 2007.

[31] NEVES, C.A.; DOS SANTOS, W.B.R.; SANTOS, G.T.D. et al. Production performance and milk composition of dairy cows fed extruded canola seeds treated with or without lignosulfonate. Animal Feed Science and Technology, v.154, p.83-92, 2009.

[32] PENA, F.; TAGARI, H.; SATTER, L.D. The effect of heat treatment of whole cottonseed on site and extent of protein digestion in dairy cows. Journal of Dairy Science, v.62, p.1423-1433, 1986.

[33] PETERSON, D.G.; KELSEY, J.A.; BAUMAN, D.E. Analysis of variation in cis-9, trans-11 conjugated linoleic acid (CLA) in milk fat of dairy cows. Journal of Dairy Science, v.85, p.2164-2172, 2002.

[34] PETIT, H.V.; TREMBLAY, G.F.; TURCOTTE, M. et al. Degradability and digestibility of full-fat soybeans treated with different sugar and heat combinations. Can. Journal of Animal Science, v.79, p.213-220, 1999.

[35] PETIT, H.V.; RIOUX, R.; D'OLIVEIRA, P.S. et al. Performance of growing lambs fed grass silage with raw or extruded soybean or canola seeds. Canadian Journal of Animal Science, v.77, p.455-463, 1997.

[36] PONCET, C.; RÉMOND, D. Rumen digestion and intestinal nutrient flows in sheep consuming pea seeds: the effect of extrusion and of chestnut tannin addition. Animal Research, v.51, p.201-206, 2002.

[37] REDDY, P.V.; MORRILL, J.L.; NAGARAJA, T.G. Release of free fatty acids from raw or processed soybeans and subsequent effects on fiber digestibilities. Journal of Dairy Science, v.77, p.3410-3416, 1994.

[38] SCOTT, T.A.; COMBS, D.K.; GRUMMER, R.R. Effects of roasting, extrusion, and particle size on the feeding value of soybeans for dairy cows. Journal of Dairy Science, v.74, p.2555-2562, 1991.

[39] SOLANAS, E.; CASTRILLO, C.; BALCELLS, J. et al. In situ ruminal degradability and intestinal digestion of raw and extruded legume seeds and soyba mean meal protein. Journal of Animal Physiology and Animal Nutrition, v.89, p.166-171, 2005.

[40] USHIDA, K.; LALLALAS, B.; JOUANY, J.P. Determination of assay parameters for RNA analysis in bacterial and duodenal samples by spectrophotometry. Influence of sample treatment and preservation. Reproduction Nutrition Development, v.25, p.1037-1046., 1985.

[41] VAN SOEST, P.J.; ROBERTSON, J.B.; LEWIS, B.A. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science, v.74, p.3583-3597, 1991.

[42] VON KEYSERLINGK, M.A.G.; WEURDING, E.; SWIFT, M.L. Effect of adding lignosulfonate and heat to canola screenings on ruminal and intestinal disappearance of dry matter and crude protein. Journal Animal Science, v.80, p.215-219, 2000.

[43] WINDSCHITL, P.M.; STERN, M.D. Evaluation of calcium lignosulfonate-treated soybean meal as a source of rumen-protected protein for dairy cattle. Journal of Dairy Science, v.71, p.3310-3325, 1988.

[44] WRIGHT, C.F.; VON KEYSERLINGK, M.A.G.; SWIFT, M.L. et al. Heat- and lignosulfonate-treated canola meal as a source of ruminal undegradable protein for lactating dairy cows. Journal of Dairy Science, v.88, p.238-243, 2005.

[45] ZERBINI, E.; POLAN, C.E.; HERBEIN, J.H. Effect of dietary soybean meal and fish meal on protein digesta flow in Holstein cows during early and midlactation. Journal of Dairy Science, v.71, p.1248-1258, 1988.