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1306 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

INTAKE, NITROGEN BALANCE AND MICROBIAL PROTEIN SYNTHESIS 
OF STEERS FED WITH OR WITHOUT LIPID ADDITION 

 
CONSUMO, BALANÇO DE NITROGÊNIO E SÍNTESE DE PROTEÍNA 

MICROBIANA DE NOVILHOS ALIMENTADOS COM OU SEM ADIÇÃO DE 
LIPÍDIOS 

 
Laila Cecília Ramos BENDIA1; Carlos Augusto de Alencar FONTES1†;  

Elizabeth Fonsêca PROCESSI1; Clóvis Carlos SILVEIRA FILHO1;  
Cláudio Teixeira LOMBARDI1; Paulo Roberto Silveira PIMENTEL2;  

Ronaldo Lopes OLIVEIRA2; Leilson Rocha BEZERRA3; Tiago Cunha ROCHA4* 
1. State University of North Fluminense Darcy Ribeiro, Department of Animal Science, Campos dos Goytacazes, Rio de Janeiro, Brazil. 

†in memoriam. 2. Federal University of Bahia, Department of Animal Science, Salvador, Bahia, Brazil; 3. Federal University of 
Campina Grande, Center of Health and Agricultural Technology, Patos, Paraíba, Brazil; 4. State University of the Tocantina Region of 

Maranhão, Imperatriz, Maranhão, Brazil. *tiagoticuro@yahoo.com.br 
 

ABSTRACT: This study investigated the influence of energy supplementation with or without the 
addition of lipids on microbial production, microbial synthesis efficiency and nitrogen balance. Eight fistulated 
steers were used with accessible rumens and kept in individual stalls. Their diets consisted of corn silage; corn 
silage + concentrate; corn silage + concentrate with addition of lipids in the form of soybean oil; and corn 
silage + concentrate with addition of lipids in the form of soybean grains. Estimates of microbial protein 
synthesis were obtained based on the urinary excretion of purine derivatives. The concentrations of ammonia in 
the rumen were determined immediately at 2, 4, 6 and 8 hours after feeding. The diets with concentrate 
increased (P<0.05) the microbial protein synthesis and the efficiency of the synthesis and nitrogen balance 
without a difference between the lipid sources (P>0.05). Concentrated diets presented higher concentrations of 
urea nitrogen in the serum and urinary urea excretion (P<0.05), but there was no difference between the lipid 
sources (P>0.05). Energy supplementation, with or without lipid addition, can be used as a strategy to increase 
the synthesis of the microbial protein in the cattle fed corn silage.  
 

KEYWORDS: Corn silage. Nitrogen balance. Ruminal ammonia. Soybeans. Soybean oil.  
 
INTRODUCTION 

 
The rumen is an important component of the 

digestive tract of ruminants, inhabited by a dense 
and varied population of microorganisms, whose 
importance is in degrading organic matter, 
producing mainly volatile fatty acids, methane, 
carbon dioxide and microbial protein. Although 
there are sequestration and turnover of 
microorganisms in the rumen, a large proportion of 
the microorganisms leaves the rumen and is 
digested in the posterior gastrointestinal tract, 
supplying about 50 to 80% of the daily requirements 
of ruminants amino acids from the absorbed 
microbial protein (CPmic) in the small intestine 
(SNIFFEN; ROBINSON, 1987; FIRKINS; YU; 
MORRISON, 2007). 

 The amino acid composition of CPmic is 
similar to that found in animal products, milk and 
meat, and, when compared to grains, has a higher 
proportion of methionine and lysine, essential amino 
acids (ROBINSON, 2010). In view of the 
importance of CPmic for the protein nutrition of 

ruminants, we have tried to maximize the synthesis 
of CPmic (HACKMANN; FIRKINS, 2015), and 
elucidate the factors that affect it. 

Evaluate the production CPmic in wide feed 
conditions becomes essential to identify and correct 
the factors that affect it, improvement the use of the 
nitrogen present in fodder and sources of rumen 
undegradable protein (RUP), since the requirements 
of metabolizable protein of ruminants are met by the 
intestinal absorption of CPmic and RUP. RUP 
requirements are calculated as the total protein 
requirement minus the CPmic amount reaching the 
duodenum (NRC, 1996). 

The use of lipid supplementation by means 
of oils, oilseeds or fat bypass has a main objective to 
increase the energy density of the diet. However, 
lipid supplementation often leads to a decrease in 
organic matter (OM) digestion, mainly due to a 
reduction in the digestion of the fibrous fraction 
(BENCHAAR et al., 2015) and modifications in the 
ruminal ecosystem (MAIA et al., 2007, WELD; 
ARMENTANO, 2017), which could consequently 
affect CPmic synthesis. 

Received: 08/04/19 
Accepted: 20/12/19 



1307 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

Considering the importance of CPmic for 
protein nutrition of ruminants, as well as the interest 
in adding lipid sources to the diet, this study aimed 
to evaluate the influence of energy supplementation 
and lipid addition to the supplement on microbial 
production and efficiency of microbial synthesis 
(Emic), estimated on the basis of urinary excretion 
of purine derivatives (PD), nitrogen balance (NB), 
levels of ruminal ammonia (N-NH3) and serum N-
urea (NUS) and urinary excretion of urea  (UEU) in 
confined cattle whether or not supplemented with 
different lipid sources, in the form of milled 
soybeans or soybean oil. 
 
MATERIAL AND METHODS 
 
Location and ethical considerations 

This study was approved by the Research 
Ethics Committee of the State University of North 
Fluminense, protocol number 168/12. The 
experiment was carried out at the Animal 
Husbandry Research Support Unit, the Animal 
Science and Animal Nutrition Laboratory of the 
Northern Fluminense State University - Darcy 
Ribeiro (UENF), Campos dos Goytacazes, RJ. 

Animals, experimental treatments and diets 
Eight rumen-fistulated crossbred steers with 

an average initial body weight of 300 kg were used 
and kept in individual, partially covered stalls with 
concrete floors, drinking fountains and a feeders. 
The animals were vermifuged and submitted a pre-

experimental period for adaptation to experimental 
facilities and conditions. During this period, all the 
animals received the same feed, consisting of corn 
silage and a concentrated ration containing corn and 
soybean meal. 

After the adaptation period, the animals 
were randomly assigned to two 4x4 balanced Latin 
squares, comprising four animals, four diets and 
four periods, which were conducted simultaneously. 

The diets comprised the following: 
CS – Corn silage; 
CS + C - 70% corn silage and 30% 

concentrate; 
CS + SO - 70% corn silage and 30% 

concentrate containing 5% lipids from soybean oil; 
CS + SG - 70% of corn silage and 30% of 

concentrate, containing 5% of lipids derived from 
soybean grains. 

Feeding was done twice a day in equal 
portions at 8:00 am and 4:00 p.m. in the form of a 
total mixed ration, aiming to keep leftovers at 
approximately 5% to guarantee ad libitum feed 
intake. The concentrate was manually mixed into 
the silage at the time of feeding. The intake was 
obtained by the difference between the supplied 
feed and the leftovers, with the leftovers being 
weighed daily and 10% of their sampled weight 
being used for further analysis. Table 1 shows the 
proportion of the ingredients and the composition of 
the experimental diets. 

 
Table 1. Ingredients and chemical composition of the supplements and pasture 

Composition Diets 
CS CS+C CS+SO CS+SG 

Corn silage 100 70.0 70.0 70.0 
Soybean grains     16.4 
Corn  16.9 13.1 13.0 
Soybean Oil   3.10  
Limestone  0.59 0.57 0.55 
Soybean meal  12.5 13.2  

Nutrient DM basis (%DM) 

Dry matter (g/kg as fed) 31.6 46.9 48.8 47.4 
Organic matter 84.5 85.5 85.7 85.9 
Crude protein 6.95 12.6 12.0 12.2 
Ether extract 1.60 1.77 5.00 5.00 
NDF1 54.2 40.5 41.4 39.9 
1Neutral detergent fiber 
 
Collections, blood sampling and laboratory 
analyses 

The experimental periods lasted eighteen 
days, with the first fourteen days used for the 

adaptation of the animals and the data collections 
performed in the last four days. 

At the beginning of each collection period, 
the animals were weighed, and blood was collected. 
Blood samples were obtained four hours after the 



1308 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

morning feeding via puncture of the jugular vein 
using test tubes. The blood samples were 
immediately centrifuged at 5,000 rpm for 15 
minutes, and the blood serum was obtained and 
stored at -15ºC for further analysis of serum urea. 

On the 16th and 17th day of each 
experimental period, the total urine and feces for 24 
hours were collected. Urine collections performed in 
the 24-hour period were obtained using collector 
funnels adapted to the animals. Rubber hoses were 
coupled to the funnels and led the urine into plastic 
containers containing 200 mL of 20% sulfuric acid 
solution (H2SO4). At the end of each 24-hour period, 
the produced urine was properly measured, 
homogenized and filtered on filter paper. Then, two 
urine samples were obtained: one with a volume of 
10 mL diluted with 40 mL of sulfuric acid (H2SO4) 
and the other, an undiluted sample of approximately 
50 mL. Both of the samples were identified and 
stored in plastic bottles at -15°C for further 
creatinine, urea, allantoin and uric acid analysis. 

Simultaneously, the urine samples were 
collected. Feces samples obtained by spontaneous 
defecation were collected and stored in plastic bags. 
At the end of each 24-hour period, the samples were 
weighed, homogenized, and samples corresponding 
to 20% of the total weight were taken, which were 
pre-dried in a forced ventilation oven at 65°C and 
stored for further analysis of the N in the feces. 

On the 18th day, ruminal fluid samples were 
collected for the determination of the ruminal 
ammonia nitrogen (N-NH3) concentrations, before 
the morning ration and two, four, six and eight 
hours after. The ruminal liquid samples, after 
collection, were filtered in a triple layer of 
cheesecloth and stored in plastic flasks containing 1 
mL of sulfuric acid solution (1:1) at -20ºC for 
further determination of N-NH3 by distillation with 
potassium hydroxide (KOH) 2N, according to the 
technique described by Vieira (1980). 

Estimates of the microbial nitrogen flux 
were obtained by purine intestinal absorption (X, 
mmol/day), estimated based on the excretion of 
purine derivatives (Y, mmol/day) and metabolic 
weight (PV 0.75) according to the following 
equation (VERBIC et al., 1990): 

 

 
 
Where 0.85 is the recovery of the purines 

absorbed as urine purine derivatives, and 0.385 
PV0.75 corresponds to the endogenous contribution to 
urine excretion. 

The intestinal flow of the microbial 
nitrogenous compounds (N) (Y, mmol/day) was 
estimated as a function of the absorbed microbial 
purines (X, mmol/day) using the following equation 
(CHEN; GOMES, 1992): 

 

 
 
Where in 70 represents the N content in the 

purines (mg N. mmol-1); 0.83 corresponds to the 
digestibility of the microbial purines; and 0.116 is 
the N-RNA:N ratio in the bacteria. 

 
The urinary volume (L), estimated from the 

spot samples, was calculated from the creatinine 
concentration in the urine spot sample (mg/L), and 
the amount of creatinine excreted daily in mg/kgBW 
was: 

 

 
 
For comparison purposes, the daily 

creatinine (EC) excretions were estimated in three 
ways: 

-From the product of the total volume and 
creatinine concentration of the total collection; 

-By means of the equations proposed in the 
literature: 
-Chizzotti, Valadares Filho and Valadares (2004):  

 
 

 
-Silva et al. (2012):  
 

 
 
Analyses of the plasma urea, creatinine, uric 

acid, and urine urea were performed using 
commercial kits (LABTEST; LAGOA SANTA, 
MINAS GERAIS, BRASIL), according to the 
manufacturer’s guidelines. The analysis of allantoin 
in the urine was done using the colorimetric method 
proposed by Fujihara et al. (1987), as described by 
Chen and Gomes (1992). 

Food, leftovers, and feces samples were 
evaluated for DM (967.03, AOAC, 1990), organic 
matter (OM), PB (981.10, AOAC, 1990), ethereal 
extract (EE) (920.29, AOAC, 1990), and neutral 
detergent fibers (NDF) (Mertens, 2002). 

 
Statistical analysis  

Statistical analyses of daily urinary 
excretion of allantoin, uric acid, purine derivatives, 



1309 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

and urea, as well as the daily absorptions of purine 
derivatives, microbial nitrogen compounds and 
microbial efficiency, were performed using the SAS 
Proc Mixed Procedure for repeated measurements 
(day aligned in period). The model included the 
effects of the Latin square, diet, period, day within 
the period, the diet x Latin square and Latin square 
x period interactions. 

The AR (1) and composite symmetry (CS) 
covariance structures were tested, using the AR (1) 

structure, based on the information criteria: AIC, 
AICC, BIC and -2 Res Log Likelihood. 
 
RESULTS AND DISCUSSION 

 
Contrast C1 indicated that the ALA, UA, 

DP, Pabs, Nmic, RDCHO and Emic of the SM 
treatment were lower than the other diets (P<0.01) 
(Table 2). 

 
Table 2. Mean, standard error (SEM) and probability levels for excretions of allantoin (ALA), uric acid (UA), 

purine derivatives (PD) obtained in total urine collection, absorbed purines (Pabs), percentage of 
allantoin (ALA/DP) in PD, microbial nitrogen (Nmic), rumen degraded carbohydrates (RDCHO), and 
microbial efficiency (Emic) for cattle supplemented or not supplemented with different lipid sources. 

Variables 
Diets 

SEM 
Contrasts 

CS CS+C CS+SO CS+SG C1 C2 C3 
 mmol/day     
ALA 59.3 83.2 87.0 80.9 3.28 <0.01 0.84 0.16 
UA 6.6 11.4 10.2 10.4 0.98 <0.01 0.30 0.89 
PD 66.7 94.8 96.8 91.5 3.52 <0.01 0.88 0.24 
Pabs 42.3 76.4 78.2 72.7 4.27 <0.01 0.84 0.31 
 %     
ALA/PD 89.4 88.2 89.5 88.5 1.03 0.45 0.34 0.36 
 g/day     
Nmic 30.3 55.2 57.4 52.2 2.64 <0.01 0.89 0.15 
 kg/day     
RDCHO 1.72 2.61 2.38 2.35 0.13 <0.01 0.15 0.88 
Emic1 17.6 21.2 24.6 22.3 1.25 0.02 0.14 0.18 
C1= CS vs other diets; C2=CS+C vs CS+SO e CS+SG, C3= CS+SO vs CS+GS. 
1 gNmic/kg RDCHO. 
 

The differences observed in this experiment 
are possibly related to differences in the rate of 
microbial synthesis between the diets. According to 
Verbic et al. (1990), when the excretion of PD is 
above 35 mmol/day, the excretion of PD in the urine 
would be linearly correlated with the uptake of 
microbial nucleic acids. 

However, there was no difference (P>0.05) 
in the ALA/PD ratio between the diets, with values 
between 88.16 and 89.53%. The contribution of 
allantoin to the total excreted urine has been shown 

to be constant both in steers (VERBIC et al., 1990) 
and in cows (VAGNONI et al., 1997), independent 
of purine flow. 

The availability of energy and nitrogen are 
the main dietary factors limiting microbial 
synthesis. Thus, higher Nmic syntheses observed for 
the CS + C, CS + SO and CS + SG diets in relation 
to the CS can be attributed to the higher observed 
intakes of organic matter (P<0.01) and protein 
(P<0.01), as indicated by the C1 contrast (Table 3).  

 
Table 3. Mean, standard error (SD) and probability levels for dry matter intake (IDM), organic matter intake 

(IOM), crude protein intake (ICP), ethereal extract intake (IEE), neutral detergent fiber intake (INDF) 
for cattle supplemented or not supplemented with different lipid sources. 

Variables 
Diets 

SEM 
Contrasts 

CS CS+C CS+SO CS+SG C1 C2 C3 
IDM 5.47 7.97 7.47 7.36 0.44 <0.01 0.31 0.86 
IOM 4.95 7.33 6.86 6.83 0.15 <0.01 0.33 0.95 
ICP 0.33 0.93 0.87 0.84 0.04 <0.01 0.16 0.71 
IEE 0.07 0.14 0.37 0.36 0.01 <0.01 <0.01 0.69 
INDF 3.08 3.31 3.13 3.02 0.20 0.74 0.35 0.70 
C1= CS vs other diets; C2=CS+C vs CS+SO e CS+SG, C3= CS+OS vs CS+SG. 



1310 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

Thus, the higher Nmic and Emic syntheses 
observed for the energy supplementation diets (CS + 
C, CS + SO and CS + SG) may be attributed in part 
to higher energy availability and a more uniform 
pattern throughout the day. Then, diets based on 
silage were supplemented with concentrate, which 
correlated with higher food intake in these diets 
(Table 3). 

Increased intake provides a higher rate of 
passage, reducing the retention time of 
microorganisms in the rumen and the maintenance 
cost of these microorganisms. Thus, the highest dry 

matter intake (P<0.01) for the CS + C, CS + SO and 
CS + SG treatments in relation to CS as indicated by 
contrast C1 (Table 3), may have increased (PIRT, 
1965), making it possible to use energy more 
efficiently for growth and, consequently, producing 
higher Emic in these treatments. 

The concentrations of N-NH3 were 
influenced quadratically by the collection times 
(Table 4). The maximum concentrations estimated 
were 8.22 at 3.20, 17.14 at 2.10, 12.25 at 1.84 and 
13.05 mg/dL at 2.62 hours after feeding for the CS, 
CS + C, CS + SO and CS + SG, respectively. 

 
Table 4. Mean, regression, coefficients of determination (R2), and variation (CV) obtained as a function of 

ammonia concentrations. 
Diets [NH3]

1 Regression R2 CV% 
CS 7.13a Ŷ=6,8642 + 0,8452*X - 0,1318*X2 0.42 29.2 
CS+C 13.5c Ŷ=16,0244 + 1,0575X - 0,2510*X2 0.56 29.1 
CS+SO 9.90b Ŷ= 11,6636 + 0,6470X - 0,1758*X2 0.42 36.0 
CS+SG 11.1b Ŷ= 10,9301 + 1,5873*X – 0,3049*X2 0.52 28.6 
1 Values followed with different letters in the column differ from each other by the Confidence Interval at 95% probability. 
* Significant at the 5% probability level by the t-test. 

 
The quadratic behavior of ammonia 

concentration agrees with previous observations, 
where the maximum values were approximately 2 to 
3 hours after the feeding (SOUZA et al., 2009). The 
maximum ammonia concentration in the CS 
treatment was obtained only 3.02 hours after 
feeding, a value close to that observed by Cabral et 
al. (2008) at 3.55 hours. However, the protein 
degradation in the rumen depends not only on 
protein solubility but also on the proteolytic activity 
of rumen microorganisms. The proliferation of 
amylolytic ruminal microorganisms, known to be 
more proteolytic than cellulolytics, is stimulated by 
cereal-based diets (SIDDONS; PARADINE, 1981). 
In this way, the proteolytic activity of the 
microorganisms seems to be the most logical 
explanation for the observed differences between 
the diets. 

The lowest estimated ammonia 
concentration (Table 4) was observed for the CS 
diet; however, it was higher than the minimum 
value of 5.0 mg/dL that was required for maximum 
Nmic synthesis (SATTER; SLYTER, 1974). In this 
way, it can be inferred that the microbial synthesis 
for the CS diet was limited by the energy 
availability associated with the fact that the animals 
in this treatment had lower crude protein intake. 

As indicated by contrast C2 (Table 3), the 
CS + C treatment did not differ (P=0.16) from the 
lipid addition treatments (CS + SO and CS + SG) in 
relation to the protein intake, but there was a 
significant difference (P<0.05) in the concentration 

of ammonia, with a lower concentration observed 
for the treatments with lipid addition (P<0.05) 
compared to the CS + C treatment (Table 4). 

In this experiment, there was no difference 
in the Nmic synthesis (P=0.89) between the CS + C 
diet in relation to CS + SO and CS + SG. 
Consequently, variations in the ruminal ammonia 
concentration can be attributed to modifications in 
the degradation of nitrogenous compounds and 
dietary and microbial proteins in the rumen. The 
effects of lipids on dietary protein degradation in the 
rumen are not yet clear, as decreases (JENKINS; 
FOTOUHI, 1990), increases (BEN SALEM et al. 
1993) and an absence of effect (DOREAU; 
LEGAY; BAUCHART, 1991) have been reported. 

There was no observed effect of lipid 
addition (P=0.14) or the way lipids were added to 
diets (P = 0.18) on Emic, as indicated by the C2 and 
C3 contrasts, respectively (Table 2). However, it is 
worth mentioning that, in the present experiment, 
the amount of carbohydrates degraded in the rumen 
(RDCHO), which are used to calculate the Emic, 
was obtained by means of estimation using 
equations proposed by Sniffen et al. (1992). As the 
aforementioned equations do not consider a possible 
reduction in carbohydrate degradation in the rumen, 
due to the addition of lipids, which may increase the 
estimated value of Emic, the Emic values found for 
the lipid addition treatments may have been 
underestimated. However, the amount of Nmic 
reaching the duodenum was not affected by the 
addition of lipids in this study, which is a more 



1311 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

reliable indicator of the amount of microbial protein 
synthesized compared to Emic. 

The mean values observed for urinary 
excretion of urea (UEU), serum N-urea (NUS), N-
ingested, N-urine, N-feces and nitrogen balance 

(NB) are shown in Table 5. As indicated by contrast 
C1, lower concentrations of NUS (P<0.01) and 
UEU (P<0.01) were observed in animals that 
received the CS diet in relation to those that 
received CS + C, CS + SO and CS + SG treatments. 

 
Table 5. Mean, standard error (SD) and probability levels for urinary excretion of urea (UEU), serum N-urea 

(NUS), N-ingested, N-urine, N-feces and nitrogen balance for cattle supplemented or not 
supplemented with different lipid sources. 

Variables 
Diets 

SEM 
Contrasts 

CS CS+C CS+SO CS+SG C1 C2 C3 
 mg/dL     
NUS 5.28 11.4 14.5 12.5 0.89 <0.01 0.44 0.79 
 mg/kg/BW     
UEU 17.2 148 157 162 14.9 <0.01 0.06 0.12 
 g/day     
N-ingested 52.8 149 139 134 5.78 <0.01 0.22 0.33 
N-urine 29.2 74.5 63.6 72.9 3.86 <0.01 0.17 0.77 
N-feces 14.3 36.6 47.1 37.0 3.42 <0.01 0.24 0.09 
NB 9.30 37.9 28.3 24.2 4.78 <0.01 0.84 0.31 
C1= CS vs other diets; C2=CS+C vs CS+SO e CS+SG, C3= CS+SO vs CS+SG. 

 
There was consensus that there is a positive 

correlation between the concentrations of NUS and 
UEU (KOHN; DINNEEN; RUSSEK-COHEN, 
2005), which are influenced by the percentage of CP 
in the diet and the nitrogen intake (VAN SOEST, 
1994). Thus, the lower CP percentage in the diet and 
the lower amount of ingested N observed for the SM 
diet provided lower concentrations of NUS and 
UEU. 

The CS + C treatment did not differ from 
the treatments with lipid addition, namely, CS + SO 
and CS + SG, in relation to the concentration of 
NUS (P=0.44) and UEU (P=0.06), as indicated by 
the C2 contrast (Table 5). Although significant, 
differences in the rumen ammonia concentration 
were small, namely, 3.64 and 2.6 mg/dL for the CS 
+ SO and CS + SG treatments, respectively, in 
relation to the CS + C treatment. Therefore, 
differences may not have been detected for the NUS 
concentrations between CS + C treatment and those 
with lipid addition (CS + SO and CS + SG). 

Excretions of urinary (P<0.01) and fecal 
nitrogen (P<0.01) increased with the inclusion of 
concentrate in the diet; however, these presented 
higher NB, as indicated by the C1 contrast. 
According to Yan et al. (2007), the intake, 
excretion, and the amount of nitrogen retained are 
positively related to the intake of dry matter and 
energy and negatively related to the proportion of 
forage. 

There was no difference in the urine 
(P=0.17) and feces nitrogen excretions (P=0.24), as 

well as for NB (P>0.05), between the CS + C diet 
and the diets with lipid addition as indicated by 
contrast C2. Despite the 3.64 and 2.46 mg/dL 
observed reductions in the rumen ammonia 
concentrations for the CS + SO and CS + SG diets, 
respectively, in relation to the CS + C diet, there 
was no difference in the reduction in N excretion in 
the urine compared to the CS + C diet, with urine 
being the main form of nitrogen excretion observed 
for all the diets. 

For there to be a difference in the nitrogen 
retention changes, the nitrogen excretion in the urine 
should be accompanied by a reduction or 
maintenance in the amount of nitrogen excreted in 
the feces and vice versa, so that changes in the 
nitrogen excretion pathway do not result in changes 
in BN. 

Although there was an increase in nitrogen 
excretion when supplementation was added, and 
there was no influence of lipid addition, which was 
higher for supplemented animals, NB was positive 
in all the diets, indicating adequate protein and 
energy balance in diets and the absence of the 
mobilization of body reserves, even for diets 
consisting only of corn silage. 
 
CONCLUSION 
 

Energy supplementation, with or without 
lipid addition, can be used as a strategy to increase 
the synthesis of microbial protein in cattle fed a corn 
silage diet. 

 



1312 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

RESUMO: Este estudo investigou a influência da suplementação energética com ou sem adição de 
lipídios na produção microbiana, eficiência de síntese microbiana e balanço de nitrogênio. Oito novilhos 
fistulados foram utilizados com rúmen acessível e mantidos em baias individuais. Suas dietas consistiram de 
silagem de milho; silagem de milho + concentrado; silagem de milho + concentrado com adição de lipídios na 
forma de óleo de soja; e silagem de milho + concentrado com adição de lipídios na forma de grãos de soja. 
Estimativas de síntese de proteína microbiana foram obtidas com base na excreção urinária de derivados de 
purina. As concentrações de amônia no rúmen foram determinadas imediatamente às 2, 4, 6 e 8 horas após a 
alimentação. As dietas com concentrado aumentaram (P<0,05) a síntese de proteína microbiana e a eficiência 
da síntese e o balanço de nitrogênio sem diferença entre as fontes lipídicas (P>0,05). As dietas concentradas 
apresentaram maiores concentrações de nitrogênio uréico no soro e excreção urinária de uréia (P <0,05), mas 
não houve diferença entre as fontes lipídicas (P>0,05). A suplementação energética, com ou sem adição de 
lipídios, pode ser utilizada como estratégia para aumentar a síntese da proteína microbiana em bovinos 
alimentados com silagem de milho. 
 

PALAVRAS-CHAVE: Amônia ruminal. Balanço de nitrogênio. Óleo de soja. Silagem de milho. Soja.  
 
 
REFERENCES 
 
AOAC Official Analytical Chemists. 15.ed. Association of official methods of analysis, Washington, DC, 
USA, 1990. 
 
BEN SALEM, H.; KRZEMINSKI, R.; FERLAY, A.; DOREAU, M. Effect of lipid supply on in vivo digestion 
in cows: comparison of hayand corn-silage diets. Canadian Journal of Animal Science, v. 73, p. 547–557, 
1993.  http://dx.doi.org/doi:10.4141/cjas93-059 
 
BENCHAAR, C.; HASSANAT, F.; MARTNEAU, R.; GERVAIS, R. Linseed oil supplementation to dairy 
cows fed diets based on red clover silage or corn silage: Effects on methane production, rumen fermentation, 
nutrient digestibility, N balance, and milk production. Journal of dairy science, v. 98, n. 11, p. 7993-8008, 
2015. http://dx.doi.org/doi:10.3168/jds.2015-9398 
 
CABRAL, L. S. C.; VALADARES FILHO, S. C.; DETMANN, E.; ZERVOUDAKIS, J. T.; SOUZA, A. L.; 
VELOSO, R. G. Microbial efficiency and ruminal parameters in cattle fed diets based on tropical forage. 
Brazilian Journal of Animal Science, v.37, n.5, p.919-925, 2008. http://dx.doi.org/doi:10.1590/S1516-
35982008000500021  
 
CHEN, X. B.; GOMES, M. J. Estimation of microbial protein supply to sheep and cattle based on urinary 
excretion of purine derivatives – an overview of technical details. Bucksburnd: Rowett Research Institute, 
International Feed Resources Unit, 1992, 21p. 
 
CHIZZOTTI, M. L.; VALADARES FILHO, S. C.; VALADARES, R. F. D. Excreção de creatinina em 
novilhos e novilhas. In: REUNIÃO ANUAL DA SOCIEDADE BRASILEIRA DE ZOOTECNIA, 41., 2004, 
Campo Grande. Anais...Campo Grande:2004. (CD-ROM). 
 
DOREAU, M.; LEGAY, F.; BAUCHART, D. Effect of source and level of supplemental fato on total and 
ruminal organic matter and nitrogen digestion in dairy cows. Journal Dairy Science. v. 74, p. 2233-2242, 
1991. http://dx.doi.org/doi:10.3168/jds.S0022-0302(91)78396-3 
 
FIRKINS, J. L.; YU, Z.; MORRISON, M. Ruminal nitrogen metabolism: perspectives for integration of 
microbiology and nutrition for dairy. Journal of Dairy Science, v. 90, p. 1–16, 2007. 
http://dx.doi.org/doi:10.3168/jds.2006-518 
 
FUJIHARA, T.; ORSKOV, E. R.; REEDS, P. J.; KYLE, D. J. The effect of protein infusion on urinary 
excretion of purine derivatives in ruminants nourished by intragastric nutrition. Journal of Agricultural 
Science, v. 109, p 7-12, 1987. http://dx.doi.org/doi:10.1017/S0021859600080916 



1313 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

HACKMANN, T. J.; FIRKINS, J. L. Maximizing efficiency of rumen microbial protein production. Frontiers 
in microbiology, v. 6, p. 465, 2015. http://dx.doi.org/doi:10.3389/fmicb.2015.00465 
 
JENKINS, T. C.; FOTOUHI, N. Effects of lecithin and corn oil on site of digestion, ruminal fermentation and 
microbial protein synthesis in sheep. Journal Animal Science, v. 68, p. 460-466, 1990. 
http://dx.doi.org/doi:10.2527/1990.682460x 
 
KOHN, R. A.; DINNEEN, M. M.; RUSSEK-COHEN, E. Using blood urea nitrogen to predict nitrogen 
excretion and efficiency of nitrogen utilization in cattle, sheep, goats, horses, pigs, and rats. Journal Animal 
Science. v. 83, p. 879-889, 2005. http://dx.doi.org/doi:10.2527/2005.834879x 
 
MAIA, M. R.; CHAUDHARY, L. C.; FIGUERES, L.; WALLACE, R. J. Metabolism of polyunsaturated fatty 
acids and their toxicity to the microflora of the rumen. Antonie Van Leeuwenhoek, v. 91, n.4, p. 303-314, 
2007. http://dx.doi.org/doi:10.1007/s10482-006-9118-2 
 
NRC - Nutrient Requirements of Beef Cattle, National Academy Press, National Research Council, 
Washington, USA, 1996. 359 p. 
 
PIRT, S. J. The maintenance energy of bacteria in growing cultures. Proceedings of the Royal Society B, 
v.163, p.224-231, 1965. http://dx.doi.org/doi:10.1098/rspb.1965.0069 
 
ROBINSON, P. H. Impacts of manipulating ration metabolizable lysine and methionine levels on the 
performance of lactating dairy cows: A systematic review of the literature. Livestock Science, v. 127, n. 2, p. 
115-126, 2010. http://dx.doi.org/doi:10.1016/j.livsci.2009.10.003 
 
SATTER, L. D.; SLYTER, L. L. Effect of ammonia concentration on rumen microbial protein production in 
vitro. British Journal Nutrition. v. 32, p. 199-208, 1974. http://dx.doi.org/doi: 10.1079/BJN19740073 
 
SIDDONS, R. C.; PARADINE, J. Effect of diet on protein degrading activity in the sheep rumen. Journal of 
the Science of Food and Agriculture. v. 32, p. 973-981, 1981. http://dx.doi.org/doi: 10.1002/jsfa.2740321005 
 
SILVA, L. F. C.; VALADARES FILHO, S. C.; CHIZZOTTI, M. L.; ROTTA, P. P.; PRADO, L. F.; 
VALADARES, R. F. D.; ZANETTI, D.; BRAGA, J. M. S. Creatinine excretion and relationship with body 
weight of Nellore cattle. Brazilian Journal of Animal Science, v. 41, p. 807-810, 2012. 
http://dx.doi.org/doi:10.1590/S1516-35982012000300046 
 
SNIFFEN, C. J.; O'CONNOR, J. D.; VAN SOEST, P. J.; FOX, D. G.; RUSSELL, J. B. A net carbohydrate and 
protein system for evaluating cattle diets: II. Carbohydrate and protein availability. Journal of Animal 
Science, v. 70, n.10, p.3562-3577, 1992. http://dx.doi.org/doi:10.2527/1992.70113562x  
 
SNIFFEN, C. J.; ROBINSON, P. H. Microbial growth and flow as influenced by dietary 
manipulations. Journal of Dairy Science, v. 70, n. 2, p. 425-441, 1987. https://doi.org/10.3168/jds.S0022-
0302(87)80027-9 
 
SOUZA, D. P.; CAMPOS, J. M. S.; VALADARES FILHO, S. C.; VALADARES, R. F. D.; SEDIYAMA, C. 
A. Z.; CRUZ, J. C. C. Fermentative parameters, microbial protein production, plasma and milk urea 
concentration and nitrogen balance of milking cows fed maize silage or sugarcane with whole cottonseed. 
Brazilian Journal of Animal Science. v.38, n.10, p.2063-2071, 2009. http://dx.doi.org/doi:10.1590/S1516-
35982009001000029  
 
VAGNONI, D. B.; BRODERICK, G. A.; CLAYTON, M. K.; HATFIELD, R. D. Excretion of purine 
derivatives by Holstein cows abomasally infused with incremental amounts of purines. Journal Dairy Science, 
v. 80, p. 1695-1702, 1997. http://dx.doi.org/doi:10.3168/jds.S0022-0302(97)76101-0 
 
VAN SOEST, P. J. Nutritional ecology of the ruminants. 2.ed., Ithaca: Cornell University. 1994. 476p. 



1314 
Intake, nitrogen…  BENDIA, L. C. R. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1306-1314, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-42294 

VERBIC, J.; CHEN, X. B.; MACLEOD, N. A.; ORSKOV, E. R. Excretion of purine derivatives by 
ruminants:Effect of microbial nucleic acid infusion on purine derivative excretion by steers. Journal of 
Agricultural Science. v. 114, p. 243-248, 1990. http://dx.doi.org/doi:10.1017/S0021859600072610. 
 
VIEIRA, P. F. Efeito do formaldeído na proteção de proteínas e lipídios em rações para ruminantes. 1980. 98 f. 
Tese (Doutorado em Zootecnia) – Curso de Pós-graduação em Zootecnia, Universidade Federal de Viçosa, 
Viçosa, 1980. 
 
WELD, K. A.; ARMENTANO, L. E. The effects of adding fat to diets of lactating dairy cows on total-tract 
neutral detergent fiber digestibility: A meta-analysis. Journal of dairy science, v. 100, n. 3, p. 1766-1779, 
2017. http://dx.doi.org/doi:10.3168/jds.2016-11500 
 
YAN, T.; FROST, J. P.; KEADY, T. W. J.; AGNEW, R. E.; MAYNE, C. S. Prediction of nitrogen excretion in 
feces and urine of beef cattle offered diets containing grass silage. Journal Animal Science. v. 85, p. 1982-
1989, 2007. http://dx.doi.org/doi:10.2527/jas.2006-408