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1152 
Original Article 

Biosci. J., Uberlândia, v. 31, n. 4, p. 1152-1158, July/Aug. 2015 

CRUDE GLYCERIN IN THE DIETS OF CONFINED LAMBS: 
PERFORMANCE, CARCASS TRAITS AND ECONOMIC FEASIBILITY 

 
GLICERINA BRUTA NA DIETA DE CORDEIROS CONFINADOS: DESEMPENHO, 

CARACTERÍSTICAS DE CARCAÇA E VIABILIDADE ECONÔMICA 
 

Marco Antonio Previdelli ORRICO JUNIOR1; Flavio Duilio Eugênio BOTTINI FILHO2; 
Fernando Miranda de VARGAS JUNIOR1; Ana Carolina Amorim ORRICO1; 

 José Carlos da Silveira OSÓRIO3 
1. Professor Adjunto, Faculdade de Ciências Agrárias da Universidade Federal da Grande Dourados, Dourados, MS, Brasil. 

marcoorrico@yahoo.com.br; 2. Mestre em Zootecnia, Faculdade de Ciências Agrárias da Universidade Federal da Grande Dourados, 
Dourados, MS, Brasil. 3. Professor Visitante, Doutor, Faculdade de Ciências Agrárias da Universidade Federal da Grande Dourados, 

Dourados, MS, Brasil 

 
ABSTRACT: The crude glycerin is a byproduct of the biodiesel industry which has high levels of glycerol and 

can be utilized by ruminants for obtaining energy. This research was conducted in order to evaluate the performance, 
carcass characteristics and economic feasibility of lambs fed diets containing crude glycerin replacing ground corn. 24 
non-castrated lambs (Pantaneiro racial grouping) at 90 days of age and average body weight of 20.02 ± 1.5 kg were used. 
We evaluated diets containing 0, 2.5, 5.0 and 7.5% inclusion of crude glycerin on dry matter of the diet replacing ground 
corn. The parameters evaluated were the consumption of dry matter and nutrients, weight gain, feed conversion, biometric 
measurements in vivo and carcass characteristics, in addition to the cost of the diet based on the carcass production. 
Animals reduced dry matter intake as doses of crude glycerin were increased. However, no differences to the weight gain 
of the animals were observed. Thus, animals fed crude glycerin showed better feed conversion rates and lower feeding cost 
which contributed to higher profit margin of the diets with crude glycerin. It is concluded that at the doses tested, the crude 
glycerin can be used in the diet of finishing lambs, however only at the level of 7.5% becomes economically feasible. 

 
KEYWORDS: Production costs. Glycerol. Sheep. Byproduct. 

 
INTRODUCTION 

 
The crude glycerin is a byproduct generated 

from the production of biodiesel, which has key 
features such as high concentrations of glycerol, 
methanol and fatty acids. Along with the prospect of 
increased production of this biofuel also has grown 
a concern about the proper disposal of this 
byproduct (LARSEN et al., 2013; AVILA-
STAGNO et al., 2012). 

Due to the high levels of glycerol and fat, 
crude glycerin can be used in ruminant diets as a 
source of energy replacing part of the corn in diets 
and thereby reducing the costs of feeding 
(PELLEGRIN et al., 2013; SANTANA JUNIOR et 
al., 2013). According to Meale et al. (2013) glycerol 
and lipids present in the crude glycerin are potential 
energy sources for animals. However little is known 
about the effect of crude glycerin on performance 
and carcass characteristics of sheep, and how its use 
reduces production costs. 

Therefore the aim of the experiment was to 
evaluate the use of diets with 0, 2.5, 5.0 and 7.5% 
crude glycerin in feeding of lambs raised in 
confinement, and their effects on performance and 
carcass characteristics of these animals, as well the 
economic feasibility of these diets. 

MATERIAL AND METHODS 
 
The experiment was conducted at the Sheep 

Research Center and Laboratory of Quality and 
Carcass Evaluation of Agricultural Sciences 
College, Federal University of Grande Dourados, 
MS. On the total, 24 intact male lambs of 
"Pantaneiro" breed, with an average age of 90 days 
and average body weight of 20.02 ± 1.5 kg were 
used. 

The experiment was conducted in a 
randomized block design with four treatments and 
six replications. The treatments tested were diets 
containing 0, 2.5, 5.0 and 7.5% crude glycerin or 0, 
0.9, 1.8 and 2.7% glycerol in the dry matter of the 
diet. 

The animals were housed in 2m2 individual 
stalls with concrete floor covered with wood 
shavings, provided with feeder and nipple type 
drinkers and arranged in a covered area. 

During the pre-experimental period the 
animals were identified, weighed, dewormed 
(Ivermectin 1 %) and subjected to adaptation to the 
installation, management and diets for a period of 
10 days. 

Received: 24/04/14 
Accepted: 15/10/14 



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The diets (Table 1) were formulated to 
provide an average gain of 0.2 kg / day / animal, 

following the recommendations of NRC (2007). 

Table 1. Content (%) of experimental diets and chemical composition. 
 % Crude glycerin 
Composition (%DM) 0.0 2.5 5.0 7.5 
Oat hay 24.33 24.33 24.33 24.33 
Soybean, meal 11.06 11.06 11.06 11.06 
Soybean, whole 4.42 4.42 4.42 4.42 
Crude Glycerin* 0.00 2.50 5.00 7.50 
Corn, ground 58.62 56.12 53.62 51.12 
Limestone 1.11 1.11 1.11 1.11 
Salt 0.46 0.46 0.46 0.46 
Chemical Composition  

    
DM (%) 87.89 88.34 89.21 89.28 
OM (% DM) 93.94 94.25 93.76 93.28 
NDF (% DM) 24.92 24.69 24.47 24.24 
ADF (% DM) 14.54 14.44 14.34 14.24 
MM (% DM) 6.06 5.75 6.24 6.72 
CP (% DM) 16.15 15.90 15.65 15.40 
EE (% DM) 3.41 4.72 5.26 6.83 

  DM=Dry matter; OM=Organic matter; NDF=Neutral detergent fiber ADF=Acid detergent fiber; MM=Mineral matter; CP=Crude 
protein; EE=Ether extract; * composition: 3.63% moisture, 39.3% glycerol, 4.75% methanol, 47.3% fatty acids, 2% CP, 12.1 mgNa/kg, 
372.28 mgK/kg, 68.25 mgCa/kg, 15.15 mgMn/kg, 171.63 mgP/kg, < 0.4 mgCd/kg e < 4.0 mgPb/kg. 

 
The animals were fed three meals daily: 

8:00 am, 11:00 am and 16:00 pm. The food was 
provided ad libitum and recalculated every three 
days, to allow a leftover of 10% total ration. Every 
day, before the first meal the leftovers were weighed 
and sampled for evaluation of the DM and nutrients 
consumed by the animals. The samples were frozen 
and leftovers grouped into periods of 14 days (a 
composite sample/ animal /period) for subsequent 
nutrient analysis which were performed according to 
the methodology described by Silva & Queiroz 
(2002). 

Every 14 days, after fasting (food and 
water) for 16 hours, the animals were weighed on a 
digital scale to monitor weight gain and feed 
conversion. On this occasion also the body 
condition and biometric measurements were 
assessed: body length, chest girth, rump width, rump 
height and foreleg height, as described by Osório & 
Osório, (2005). 

Body condition was used as a criterion for 
slaughter and animals were slaughtered upon 
reaching the score between 2.5 (normal) to 3.0 
(slightly fat) on a scale of 1 (too thin) to 5 
(extremely fat), at intervals of 0.5 according to 
Osório & Osório, (2005). 

The slaughter of the lambs was conducted 
according to the guidelines of the Regulation of 
Industrial and Sanitary Inspection of Products of 
Animal Origin - RIISPOA (BRASIL, 2000). 

Carcasses were evaluated according to the 
methodology proposed by Osório & Osório, (2005) 
and the following parameters were evaluated: hot 
carcass weight, cold carcass weight, hot carcass 
yield, cold carcass yield, carcass external length, 
carcass internal length, leg length, leg width, leg 
depth, depth of chest, and fat conformation and 
score. 

The costs of feeding were determined and 
economic feasibility of diets containing different 
levels of glycerin was evaluated considering only 
the daily carcass yield without accounting for other 
fixed and operating costs of the production of sheep 
system, since these would be the same in the five 
situations. 

The data relating to parameters of animal 
performance and carcass characteristics were 
subjected to regression analysis and the initial body 
weight was used as a covariate. Orthogonal 
contrasts were used to assess the effects of linear 
and quadratic order of levels of crude glycerin. 
Nonparametric characteristics were evaluated 
through Kruskal - Wallis test, as described by 
(SAMPAIO, 2002). Analyses were performed using 
the SAEG 9.1 software (UFV, 2007). 

 
RESULTS AND DISCUSSION 

 
The consumption of DM (kg/day), 

percentage of body weight and metabolic weight) 



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was reduced in a linear fashion with inclusion of crude glycerin in the diets (Table 2). 
 

Table 2. Nutrient intake and performance of lambs fed diets containing different proportions of crude glycerin 
replacing corn. 

Parameters  
Crude Glycerin (%) 

Regression equation R2 P CV% 
0.0 2.5 5.0 7.5 

DM (kg/d) 1.20 1.06 1.03 1.01 y = -0.0239CG + 1.1691 0.53 <0.01 8.65 

DM (%BW) 4.20 3.94 3.68 3.66 y = -0.074 CG + 4.1468 0.33 <0.01 8.90 

DM (g/BW0,75) 94.10 88.20 85.50 84.05 y = -0.0013 CG + 0.0927 0.30 <0.01 7.89 

CP (kg/dia) 0.195 0.169 0.170 0.156 
y = 0.0008 CG2 - 0.0109 

GB + 0.1938 
0.74 <0.01 10.10 

CPB (%BW) 0.661 0.610 0.612 0.564 
y = 0.0015 CG2 - 0.0244 

CG + 0.6609 
0.37 <0.01 10.35 

EE (kg/d) 0.033 0.036 0.047 0.057 
y = 

0.0004CG2+0.0003CG+0
.0318 

0.91 <0.01 4.12 

EE (%BW) 0.157 0.180 0.235 0.289 
y=0.002CG2+0.0031CG+

0.1516 
0.92 <0.01 3.94 

NDF (kg/d) 0.299 0.261 0.252 0.244 y=0.264 - 0.12 14.67 

NDF (%BW) 1.422 1.285 1.263 1.242 y=1.303 - 0.14 19.34 

ADF (kg/d) 0.174 0.152 0.157 0.143 y=0.156 - 0.21 15.89 

ADF (%BW) 0.827 0.748 0.786 0.72 y=0.772 - 0.19 21.34 

FBW (kg) 38.10 35.52 36.5 36.5 y=36.65 - 0.07 8.07 

DW (kg/d) 0.22 0.20 0.21 0.23 y=0.22 - 0.22 8.46 

FC (kg/kg) 5.30 5.10 4.79 4.41 y = -0.118CG+ 5.351 0.53 0.01 9.39 

TG (kg) 17.08 15.22 16.55 16.87 y=16.43 - 0.06 9.54 
DM, CP and NDF, ADF (kg/d) = consumption in kilograms per day; DM, CP and NDF, ADF (% BW) = consumption related to body 
weight; DM (g/ BW0,75) = consumption related to metabolic weight; FBW- Final body weight; DW- Daily weight gain; FC- Feed 
conversion; TG- Total gain; R2= model coefficient of determination; P = significance value; CV(%)=coefficient of variation.  

 
The consumption values varied in the range 

from 1.20 to 1.01 kg DM/day with doses of 0 and 
7.5% respectively. The decreasing of diets 
consumption along with the addition of crude 
glycerin may be related to one or more of the 
following factors: chemical satiety due to higher 
energy concentration of the diet, toxic effect caused 
by excess lipids and decreasing palatability of the 
mixture. 

Ruminants when fed diets containing high 
content of grains, tend to regulate the intake 
depending on the amount of energy consumed 
(chemical mechanism of control of hunger and 
satiety). According to the data of Table 1, the ether 
extract ranged from 3.41 to 6.83 % of diet DM, 
resulting in different concentrations of 
metabolizable energy. In a review Krehbiel et al. 
(2006) analyzed data from 49 experiments (a 
population of 243 cattle) providing the diets with 
different concentrations of metabolizable energy to 
the animals. The models showed that animals 
decreased DM intake in proportion to the increase of 

metabolizable energy of the diet, therefore, there 
was no difference in the total metabolizable energy 
intake. 

The toxic effect of increased levels of lipids 
in the diet may also have contributed to the 
reduction in consumption. According Bosa et al. 
(2012) values above 5% ether extract impact 
negatively in food degradation by rumen 
microorganisms (toxic effect) and therefore the 
intake. The fatty acid toxicity to the rumen 
microorganisms is related to their nature and 
polyunsaturated long chain fatty acids (vegetable 
oils type) are the most harmful (PALMQUIST; 
MATTOS, 2006). 

Another factor that may have affected the 
animals consumption is the rancidity of fats present 
in the crude glycerin, whereas unsaturated fatty 
acids are more susceptible to rancidity process. One 
of the end products of rancidity are peroxides, 
which cause a characteristic odor and unpleasant 
taste in the diet, thereby reducing your intake by 
animals (BOSA et al., 2012). No analysis was 



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performed to assess the degree of rancidity of crude 
glycerin, but it was possible to detect a 
characteristic odor of rancid fat once the glycerin 
used in this study was from disposal of oil and 
stored at room temperature. 

The decrease in consumption of diets 
containing crude glycerin was also observed by 
Lage et al. (2010) in finishing lambs of Santa Inês 
breed. The authors observed that consumption 
ranged from 1.12 to 0.78 kg DM/day, according to 
doses of 0 and 12% inclusion of crude glycerin, 
respectively, also following a negative linear model. 
For the authors, the low DM intake was obtained as 
a function of methanol present in the crude glycerin 
used (8.7%), almost two-fold methanol 
concentration from crude glycerin used in this study 
(4.7%). The total concentrations of methanol in the 
diets ranged from 0.00 to 0.03% of DM, which 
according Jung & Batal (2011) is not related to the 
reduced consumption and performance. Leão et al. 
(2012) reported that at low concentrations the 
methanol is converted to methane by rumen 
microorganisms thus avoiding possible poisoning of 
animals. 

The CP intake showed the decreasing 
behavior according to the addition of crude glycerin 
as well as intake, however following a quadratic 
prediction model. From this model, the lower CP 
intake (kg / day) was obtained at a dose of 7.5 % 
crude glycerin. Although significant, the difference 
between the diet with highest (0 % crude glycerin) 
and lowest (7.5 % crude glycerin) CP content was 
0.7%, which explains the similar weight gain 
between animals. 

Despite lower intakes of DM and CP, the 
animals showed no differences in weight gain 
between the diets tested (Table 2), i.e., the animal 
requirements were met by the diets and the gains 
were close to those provided by NRC (2007). 
Probably the greatest energy density of diets 
containing crude glycerin (glycerol and ether 
extract) allowed to meet the energy needs of the 
animals even in the diets had the lowest intakes.  In 
the experiment conducted by LAGE et al. (2010) 
weight gains decreased linearly with dose of crude 
glycerin present in the diet, especially for doses 
above 6% crude glycerin. According to the authors 
the poor performance was a result of reduced DM 
intake by the animals and the lack of conformity 
with the nutritional requirements for the desired 
gain (0.3 kg/day). 

The feed conversion showed improvement 
due to the increase of crude glycerin in the diet. One 
reason for the reduction in the values of feed 
conversion is due to the glycerol present in crude 

glycerin is readily fermented in the rumen yielding 
propionate and /or absorbed directly through the 
rumen epithelium and metabolized in the liver to 
produce glucose (energy supply for animals), as 
stated by Parsons et al. (2009). 

Another factor that may have contributed to 
improve the feed conversion was the highest content 
of fat present in the diets containing crude glycerin 
(Table 1), thus the energy densities of the diets were 
higher and contributed to the compensation in total 
energy intake. This can be seen in Table 2 where we 
observe higher ether extract intakes due to the 
addition of crude glycerin in diets. If provided in 
adequate quantities lipids may be important energy 
sources for ruminants, leading to increased weight 
gain and improved feed conversion. Evaluating the 
performance of lambs Fernandes et al. (2011) had 
weight gain and feed conversion of 0.24 and 0.16 
kg/day and 4.06 and 6.4 for diet with 6% ether 
extract (similar content of diet with the highest dose 
of crude glycerin used in this study) compared with 
diets containing 2.2% ether extract. 

No differences were observed with respect 
to the consumption of NDF and ADF (Table 2) and 
this fact may be associated with small portion of 
forage in the diet (24.33% of diet) and the similarity 
between the NDF and ADF in the experimental diet. 

No differences were observed in the 
biometric measurements in vivo and carcass of 
lambs (Table 3). Probably this behavior is 
associated with weight gains which occurred in a 
similar manner for the diets, and due to 
standardization of the final weight of the animals, 
with the intention of slaughtering animals with 
similar conditions. It is noteworthy that animals of 
the same breed and age that have similar weight 
gains also have similar biometric features (COSTA 
et al., 2009). 

As the carcass weight at slaughter was 
similar among the animals, the hot carcass weight, 
hot carcass yield, cold carcass weight and cold 
carcass yield were also similar. However, it is 
noteworthy that the cold carcass weight and cold 
carcass yield could have varied depending on the 
cooling losses, but this did not occur because there 
was no difference between the fat thicknesses of 
carcasses. 

For the economic analysis, it was found that 
the use of crude glycerin is feasible only at 7.5%, as 
it enables higher profit margin, 6.3% higher than the 
diet without the inclusion of crude glycerin 
(Table4). 

 
 



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Table 3. Biometric measurements in vivo and the carcass of “Pantaneiro” lambs fed diets containing different 
proportion of crude glycerin replacing ground corn. 

Parameters Crude Glycerin (%)     P CV 
(%) 

.0 .5 .0 .5 
Body length (cm) 61.17 58.17 58.00 60.50 0.08 3.78 
Chest length (cm) 18.67 18.17 18.17 18.33 0.90 3.85 
Rump width (cm) 18.67 18.17 17.33 18.33 0.06 7.92 
Rump height (cm) 66.00 64.50 64.50 63.67 0.07 3.94 
Foreleg height (cm) 64.00 62.17 62.17 61.50 0.13 2.98 
Chest girth (cm) 66.17 62.33 62.83 63.83 0.22 4.18 
Body compactness (kg/cm) 0.55 0.51 0.50 0.52 0.34 8.90 
Body weigth at slaughter (kg) 38.10 35.52 36.50 36.50 0.06 13.02 
Hot carcass weight (kg) 18.97 17.88 17.97 18.49 0.09 5.83 
Hot carcass yield (%) 49.77 50.40 49.25 50.61 0.06 3.10 
Cold carcass weight (kg) 18.34 17.34 17.37 17.72 0.12 6.09 
Cold carcass yield (%) 48.12 48.85 47.57 48.48 0.09 3.20 
Cooling losses (%) 3.32 3.02 3.33 4.16 0.10 8.90 
Carcass external length (cm) 58.33 58.25 57.67 57.50 0.08 6.00 
Carcass internal length (cm) 62.00 61.00 62.00 60.67 0.07 6.00 
Length of leg (cm) 40.83 40.67 40.17 40.50 0.11 4.03 
Width of leg (cm) 10.67 9.50 9.92 9.67 0.13 9.15 
Depth of leg (cm) 14.17 14.42 14.42 13.83 0.09 7.09 
Depth of chest (cm) 27.00 26.42 22.83 26.17 0.08 16.12 
Conformation 3.00 2.83 3.00 2.83 0.13 14.22 
Fat score 3.58 3.33 3.42 3.50 0.09 15.24 
Carcass fat thickness (mm) 1.83 1.81 1.78 2.22 0.24 27.37 
P = significance value; CV%=coefficient of variation. 

 

Table 4. Economic analysis of the experimental diets in relation to carcass gain of lambs and sensitivity 
analysis of the variation in the price of crude glycerin (% price of ground corn) on the cost of carcass 
gain (R$/kg carcass gain) fed diets containing different proportions of crude glycerin replacing corn.  

 
Variable 

 Crude Glycerin (%) 

0.0 2.5 5.0 7.5 

Diet costs (R$/DM kg) 0.54 0.53 0.52 0.51 
DM consumption (kg/d) 1.20 1.06 1.03 1.01 
Diet costs (R$/animal/d) 0.64 0.56 0.53 0.51 
Carcass gain (kg/animal/d) 0.109 0.101 0.103 0.116 
Diet costs (R$/carcass kg) 4.89 5.23 5.01 4.37 
Profit margin (%)* 40.32 36.27 38.94 46.69 

(% corn price) 
Diet costs (R$/carcass kg) 

0.0 2.5 5.0 7.5 

0 4.89 4.82 4.79 4.26 

20 4.89 4.84 4.84 4.33 

40 4.89 4.87 4.88 4.40 

60 4.89 4.89 4.94 4.47 

80 4.89 4.91 4.98 4.53 

100 4.89 4.94 5.03 4.60 

120 4.89 4.97 5.09 4.67 

140 4.89 4.99 5.13 4.74 



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160 4.89 5.01 5.18 4.81 

180 4.89 5.04 5.23 4.87 
The prices of ingredients are referent to values with shipping included based on the dry matter of the diet. Oat hay R$ 0.33/kg; ground 
corn, R$ 0.53/kg; soybean meal, R$ 0.72/kg; soybean whole, R$ 1.30/kg; crude glycerin, R$ 0.17/kg; (only shipping price, so it has no 
commercial value); salt, R$ 1.2/kg; Limestone, R$ 0.20. (*) Profit margin = [(carcass price (R$/kg)- diet cost (R$/kg)]/carcass price 
(R$/ kg) x100. Considering a price of R$ 8.20 per kg of carcass. 

 

The sensitivity analysis showed that when 
the price of crude glycerin reaches 60% of the price 
of corn the inclusion levels of 2.5 and 5% glycerin 
become unviable. While the level of 7.5% crude 
glycerin remains viable even when the price of 
crude glycerin is 180% the price of corn, i.e., even 
crude glycerin having a value above the price of 
corn, the benefit generated in food conversion 
offsets this cost. 

CONCLUSION 
 

The use of up to 7.5% crude glycerin 
replacing corn in the diet of lambs (Pantaneiro racial 
grouping) raised in confinement keeps the 
performance and meat production of these animals, 
but only at the level of 7.5% becomes economically 
feasible. 

 
 

RESUMO: A glicerina bruta é um subproduto da indústria do biodiesel que apresenta elevados teores de 
glicerol que podem ser utilizados pelos ruminantes para obtenção de energia. Esta pesquisa foi realizada com o objetivo de 
se avaliar o desempenho, características de carcaça e viabilidade econômica de cordeiros alimentados com dietas contendo 
glicerina bruta em substituição ao grão de milho triturado. Foram utilizados 24 cordeiros não castrados do grupamento 
racial “Pantaneiro”, com 90 dias de idade e peso corporal médio de 20,02±1,5 kg. Avaliou-se dietas contendo 0, 2,5, 5,0 e 
7,5% de inclusão de glicerina bruta na matéria seca da dieta em substituição ao grão de milho triturado. Os parâmetros 
avaliados foram: consumo de matéria seca e de nutrientes, ganho de peso, conversão alimentar, medidas biométricas in 
vivo e características da carcaça, além do custo da dieta em função da produção de carcaça. Os animais reduziram o 
consumo de matéria seca à medida que aumentaram as doses de glicerina bruta. No entanto não foram observadas 
diferenças com relação ao ganho de peso dos animais. Desta forma os animais alimentados com glicerina bruta 
apresentaram melhores índices de conversão alimentar e menor custo com a alimentação o que contribuiu para maior 
margem de lucro das dietas com glicerina bruta. Conclui-se que nas doses testadas a glicerina bruta pode ser utilizada na 
dieta de cordeiros em terminação. 

 
PALAVRAS-CHAVE: Custo de produção. Glicerol. Ovinos. Subproduto. 

 
 

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