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Original Article 

Biosci. J., Uberlândia, v. 34, n. 6, p. 1663-1673, Nov./Dec. 2018 

FRACTIONATION OF CARBOHYDRATES AND PROTEINS IN TIFTON 85 
BERMUDAGRASS HAY AT DIFFERENT CUTTING LEVELS AND 

STORAGE TIME 
 

FRACIONAMENTO DE CARBOIDRATOS E PROTEÍNA EM FENO DE CAPIM 
TIFTON 85 SOB DUAS ALTURAS DE CORTE E TEMPOS DE ARMAZENAMENTO 

 
Samantha Mariana Monteiro SUNAHARA¹; Marcela Abbado NERES¹;  

Jaqueline Rocha Wobeto SARTO
2
; Caroline Daiane NATH¹; Kácia Carine SCHEIDT

3
; 

Maximiliane Alavarse ZAMBOM
1
 

1. Universidade Estadual do Oeste do Paraná – UNIOESTE, Mal. Cândido Rondon, PR, Brasil. samanthasunahara@yahoo.com.br; 2. 
Universidade Estadual Paulista Júlio de Mesquita Filho, UNESP, Botucatu, SP, Brasil; 3. Universidade Estadual de Maringá, UEM – 

Maringá, PR, Brasil. 
 

ABSTRACT: This study aimed to evaluate the fractionation of carbohydrates and protein of grass hay Tifton 85 
bermudagrass under two cutting heights in relation to ground level (0.04 and 0.08 m) during 120 days of storage. Samples 
were collected in the baling and hay stored in shed at 30, 60, 90 and 120 days of storage, after, it was subjected to 
laboratory procedures, in which the levels of soluble carbohydrates were determined, carbohydrate fractionation and 
protein fractionation. The results were studied in a randomized complete block design with split plot with two treatments 
allocated the plots: cutting height of 0.04 to 0.08 m from the ground and five times in the subplots: baling, 30, 60, 90 and 
120 days of storage hay, with five repetitions. The soluble carbohydrate concentration hay responded in a quadratic 
manner to the storage time for cutting heights of 0.04 and 0.08 m above soil level; minimum values of 11.53 and 10.70 g 
kg-1 of DM were estimated for 93.44 and 91.16 storage days, respectively. The carbohydrate fraction A + B1 responded 
negatively linear to periods of storage evaluated in both cutting heights. The contents of the carbohydrate fraction B2 and 
proteins A and C exhibited a positive linear response to storage time for a cutting height of 0.04 m and a quadratic effect 
for hay cutting height at 0.08 m above soil level, with an opposite behavior for both cutting heights for the B1 protein 
levels and C carbohydrate fraction. The B2 fraction showed a negative linear response as a function of storage time, with a 
reduction in the fraction of 0.09 and 0.11 percentage units for each day of storage, for hay cutting height of 0.04 and 0.08 
m, respectively. The B3 fraction responded quadratically to the storage time, the two studied cutting heights. The storage 
of Tifton 85 hay cut at 0.04 m above soil level for 120 days leads to a decrease in fractions of rapid ruminal degradation 
and increase of the indigestible fraction in carbohydrate and protein fractions. Based on the results obtained it is 
recommended the cutting of the Tifton 85 bermuda grass forage to produce hay at 0.08 m and its storage up to 30 days 
provided that under ideal conditions. 

 

KEYWORDS: Forage conservation. Haymaking. Nitrogen compounds. Starch. 
 

INTRODUCTION 
 
Food is responsible for most animal 

production costs. Therefore, for the best 
productivity, feed formulations must be carefully 
adjusted. As such, it is important to understand the 
behavior of food in the digestive tract (PEREIRA et 
al., 2007). To estimate animal performance more 
accurately and improve nutrient efficiency, all 
information about an animal's food, including 
carbohydrate and protein fractions, is required. 

With the Cornell Net Carbohydrate and 
Protein System (CNCPS), foods were subdivided by 
their chemical and physical characteristics, ruminal 
degradation, and post-rumen digestibility 
(SNIFFEN et al., 1992). Using the estimation of 
these fractions in the gastrointestinal tract, it is 
possible to adjust the feed supply, with the goal of 
maximum efficiency of microbial protein synthesis. 

With the best formulated diets, it is possible to 
reduce energy and nitrogen losses caused by 
ruminal fermentation and to maximize the 
synchronization of nitrogen and carbohydrate 
degradation in the rumen (SILVA, SILVA, 2013). 

Milk production in western Parana is based 
on the use of tropical grasses in pastures or 
conserved in the form of silage or hay. The use of 
forage preserved in the form of hay is a very 
common practice used by farmers as an alternative 
to solve the problem of the seasonality of fodder, 
and to allow the best use of the surplus; however, 
the storage of forage for long periods of time may 
cause changes in nutritional value (CASTAGNARA 
et al., 2011) and the growth of undesirable 
microorganisms that influence the chemical 
composition, intake, and digestibility of forage. 
Nevertheless, Pasqualotto et al. (2015) did not 
observe changes in the chemical composition of 

Received: 11/09/17 
Accepted: 15/08/18 



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Tifton 85 bermudagrass hay stored up to 90 days in 
a covered shed. 

The cutting height of the forage for haying 
can influence the nutritional value of the forage by 
affecting dry matter production, since cutting 
heights closer to the ground increase mass 
production, but these also include senescent parts 
that contribute to reduced nutritional value of the 
hay. Moreover, higher cuts increase the nutritional 
value of forage because of the higher percentage of 
green leaf blades captured, but reduce the dry matter 
yield per unit area. The hay conditioners currently 
used to cut forage for hay follow the irregularities of 
the terrain and the adjustment of the cutting height 
is based on the extension or retraction of the arm of 
the machine when coupled to a tractor. The 
technology available today in the mowers allows 
uniform cuttings that accompany the roughness of 
the terrain.  

The objective of this study was to evaluate 
the carbohydrate and protein fractionation of Tifton 
85 bermudagrass hay (Cynodon spp. cv. Tifton 85) 

under two cutting heights in relation to the soil level 
(0.04 and 0.08 m) during 120 days of storage in a 
closed shed. We test the following hypothesis: 
cutting height at 0.04 m from the ground will 
produce a lower quality hay at 0.08 m and storage 
up to 90 days will not cause significant decreases in 
the more soluble fractions of carbohydrates and 
proteins. 

 
MATERIAL AND METHODS 
 

The experiment was conducted in Marechal 
Cândido Rondon, Paraná, Brazil under field 
conditions at a farm dedicated to the production of 
hay, with a total area of hay production of 20 ha. 
The farm was located at latitude 24°32′49.7″S, 
longitude 54°01′46.4″O and altitude of 392 m. The 
local climate, classified according to Köppen, is of 
type Cfa, subtropical, with rains well distributed 
throughout the year and hot summers. The climatic 
data for the experimental period are shown in Figure 
1. 

 
Figure 1. Maximum and minimum air temperature (°C), mean relative air humidity (%) and rainfall (mm) 

during the months of cutting, baling, and storage of hay.  
 

The soil of the experimental area is 
classified as Eutroferric Red Latosol (EMBRAPA, 
2013), or Rhodic Acrudox (SOIL SURVEY STAFF, 
2010), with 650 g kg−1 of clay and the following 
chemical characteristics: pH in water = 5.22; P 
(Mehlich) = 46,08 mg dm−3; K (Mehlich) = 0.11 
cmolc dm−3; Ca²+ (KCl 1 mol L−1) = 6.37 cmolc 
dm−3; Mg²+ (KCl 1 mol L−1) = 2.05 cmolc dm−3; 
H+Al (calcium acetate 0.5 mol L−1) = 4.50 cmolc 
dm−3; CTC = 13.03 cmolc dm−3, V = 65.49%; Cu = 
28.48 mg dm−3; Zn = 33.37 mg dm−3; Mn = 226.70 
mg dm−3; and Fe = 20.31 mg dm−3. 

The Tifton 85 bermudagrass area was 
planted 10 years ago and is exclusively intended for 
hay and haylage, and used water waste swine 
biofertilizer as the sole source of fertilization. This 
was applied on the surface of the hay and haylage 
production area by spraying, with coupled 
equipment, at 7 and 14 days of forage regrowth, 
averaging 60 m³ ha−1 per application.  

The grass was cut on March 22, 2014, at 
3:30 p.m., when the Tifton 85 bermudagrass had 
grown for 60 days, using a conditioning mower with 
iron-free toe pickers, regulated to cut to 0.04 and 
0.08 m from the ground. Turns were performed 1, 



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19, and 44 h after cutting. Baling took place on 
March 24, 2014 at 3:30 p.m., with total drying time 
in the field of 48 h, and climatic conditions 
favorable to dehydration. 

Rectangular 12 kg bales were produced and 
stored in a masonry shed covered with side walls 
and windows for ventilation. Bales were arranged 
on wooden pallets to avoid direct contact with the 
soil for 120 days. Samples were collected on the 
bale day (time 0) and from hay stored in the shed at 
30, 60, 90, and 120 days of storage. After drying in 
a forced air circulation oven at 55°C for 
approximately 72 h, the samples were ground in a 
Willey type mill with a 1 mm sieve screen and 
submitted for laboratory procedures, in which the 
soluble carbohydrate and fractionations of 
carbohydrate and protein were determined. 

The dry matter (DM), crude protein (CP), 
mineral matter (MM), and ethereal extract (EE) 
were determined according to AOAC (1990), 
neutral detergent fiber (NDF) and acid detergent 
fiber (ADF) according to van Soest, Robertson, and 
Lewis (1991), and lignin according to the 
methodology developed by van Soest (1965) with 
sulfuric acid, as described by Silva and Queiroz 
(2006). Estimates of the fractions that make up total 
carbohydrates (TC) were determined according to 
Sniffen et al. (1992), calculated as follows: TC = 
100 - (%CP + %EE + %MM). The fraction of C was 
estimated by the equation: 100 * [NDF (%DM) * 
0.01 * Lignin (%NDF) * 2.4]/ TC (%DM) and the 
fraction B2 was calculated by the equation: 100 * 
[NDF (%DM) – PIDN (%CP) * 0.01 * CP (%DM) – 
NDF (%DM) * 0.01 * Lignin (%NDF) * 2.4]/ TC 
(%DM), where PIDN represents the neutral 
detergent insoluble protein. The carbohydrate 
fractions with high ruminal degradation rates (A + 
B1) were determined by the difference between 100 
- (C + B2 fraction). The determination of soluble 
carbohydrates was done according to the 
methodology described by Johnson et al. (1966), 
with a spectrophotometer reading at a wavelength of 
480 nm. 

To determine the fractionation of crude 
protein, the recommendations of Licitra, Hernandez 
and van Soest (1996) were followed. Fraction A was 
determined from the treatment of a 0.5 g sample 
with 50 mL of water for 30 min, then adding 10 mL 
of trichloroacetic acid (TCA) for another 30 min. 
Next, the sample was filtered using filter crucibles 
and the residual nitrogen was measured by the 
Kjeldahl method. Fraction A was obtained from the 
difference between total nitrogen content and 
insoluble nitrogen in TCA.  

Total soluble nitrogen was obtained by 
incubating 0.5 g of sample with 50 mL of borate-
phosphate buffer (BPB) and 1 mL of 10% sodium 
azide. After three hours of incubation, the sample 
was filtered and the residue analyzed for BPB 
insoluble nitrogen. The nitrogen soluble in BPB was 
determined from the difference between the total 
nitrogen content and the nitrogen insoluble in BPB. 
The fraction B1, in turn, was determined from the 
difference between the nitrogen content soluble in 
BPB and the soluble nitrogen in TCA. Neutral 
detergent insoluble nitrogen (NIDN) and acid 
detergent insoluble nitrogen (NIDA) were measured 
by the NDF and ADF residues, respectively. 
Fraction B3 was obtained from the difference 
between NIDN and NIDA. Fraction C constituted 
NIDA and fraction B2 was determined from the 
difference between insoluble nitrogen in BPB and 
the NIDN. The protein content was obtained by 
multiplying the nitrogen content by a factor of 6.25. 

The experimental design was a randomized 
block design with two subdivided plots with two 
treatments allocated in the plots: 0.04 and 0.08 m of 
soil cutting height and five sampling times in the 
subplots: baling, 30, 60, 90 and 120 days of hay 
storage each with five replicates. 

We analyzed data using analysis of variance 
in SISVAR 5.0 software (FERREIRA, 2011), and 
when the F test result was significant, the variable 
storage periods (0, 30, 60, 90, and 120 days) were 
assessed using regression analysis, with the choice 
of the model that presented a minimum significance 
of 5% by the Student’s t-test, and with a higher 
coefficient of determination (R). 

 
RESULTS AND DISCUSSION 

 
The total carbohydrate content (TC) of the 

Tifton 85 bermudagrass hay responded negative 
linearly to the storage time at the cutting height at 
0.04 m from the soil, and in a quadratic form with 
storage time at the cutting height at 0.08 m from the 
soil. There was a difference between heights after 
60 days of storage (Figure 2). The reduction in TC 
observed with the increase in hay storage time was 
related to the higher levels of crude protein and 
ether extract registered in the hays after 30 days of 
storage. 

The values of TC obtained in the study 
(between 76.52% and 80.82% dry matter) were 
close to those of van Soest (1994), constituting 50 to 
80% of the dry matter of the forage plants. 

 



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Figure 2. Mean total carbohydrate (TC) percentage in Tifton 85 bermudagrass hay, at the cutting height at 0.04 

m (◆) and 0.08 m (■) from the soil in relation to storage time in days.  
 

In tropical grasses, TC represents the 
highest proportion of dry matter in plants and the 
variation in the quality of this fraction directly 
interferes with the availability of energy to the 
ruminant. 

The non-fibrous carbohydrates of the rumen 
degradation, represented by fraction A + B1, 
responded in a negative linear way to the storage 
periods evaluated at the two cutting heights (Figure 
3), with no differences between the heights. The 
reduction in the A + B1 fraction in the hay, cut at 
heights of 0.04 m and 0.08 m, was 0.10 and 0.11 
percentage points for each storage day, respectively. 
This decrease can be explained by the age of the 
forage cutting and the effect of temperature, as high 

temperatures cause rapid metabolic activity in the 
plant, and are associated with a decrease in 
metabolites of the cellular contents and 
photosynthetic products, which are quickly 
converted into structural components (VAN 
SOEST, 1994). Foods with high fraction A + B1 are 
a good energy source for increasing the content of 
ruminal microorganisms that use non-fiber 
carbohydrates (CARVALHO et al., 2007) and for 
the synchronism between the digestive rate of 
proteins and carbohydrates, which may have an 
important effect on the final products of 
fermentation and animal production (NOCEK; 
RUSSELL, 1988). 

 
Figure 3. Mean percentage of non-fibrous carbohydrates (A + B1) of Tifton 85 bermudagrass hay at a cutting 

height of 0.04 m and 0.08 m in relation to storage time in days. 
 

The levels of fraction B2 ranged between 
74.06 and 87.21% TC, and exhibited a positive 
linear response as a function of the storage time, for 
a cutting height of 0.04 m above soil level, and 

quadratic behavior for a cutting height of 0.08 m 
above soil level (Figure 4). Differing between the 
cutting heights only at 90 days of storage. This 
increase in the values obtained for the B2 fractions 



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during hay storage can be explained by the high 
NDF content, with a mean of 703.73 kg ha−1 and 

812.08 kg ha−1 at the baling and after 120 days of 
storage, respectively. 

 
Figure 4. Mean percentage content of available components corresponding to the potentially degradable 

fraction (B2) of Tifton 85 bermudagrass hay, at a cutting height of 0.04 m (◆) and 0.08 m (■) in 
relation to storage time in days. 

 
Bulk foods with higher NDF content have a 

higher proportion of the carbohydrate fraction B2. 
Because it provides energy in the rumen more 
slowly, it can affect the efficiency of microbial 
synthesis and animal performance. In addition, 
consumption may be limited by a high indigestible 
fraction (fraction C) of fodder. Thus, forage must be 
supplemented with energy sources that are readily 
available in the rumen, when there is no protein 
limitation in quantity and quality. The results 
obtained in this study differ with those of Souza et 
al. (2012), which consisted of mean values of 
57.62% TC for hay of four cassava varieties. 
Although fraction B2 is potentially digestible, 

Russell et al. (1992) emphasized that carbohydrates 
rich in fraction B2 require non-protein nitrogen to 
meet the nitrogen requirements of microorganisms 
fermenting structural carbohydrates. 

A proportion of indigestible carbohydrates 
of the cell wall (fraction C) of the Tifton 85 
bermudagrass hay responded linearly to the storage 
time at the cutting height of 0.08 m from the soil, 
with a fractional increase of 0.02 percentage points 
per storage day, and in a quadratic form to storage 
time at the cutting height of 0.04 m from the soil. 
There was a difference between the heights at 90 
and 120 days of storage (Figure 5). The levels of 
fraction C were between 5.42 and 9.97% TC. 

 

 
Figure 5. Mean percentages of the indigestible fraction of the cell wall (C) of the Tifton 85 bermudagrass hay, 

at a cutting height of 0.04 m (◆) and 0.08 m (■) in relation to storage time in days. 



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The variation in the values of fraction C is 
related to the lignin content present in the plant, 
which confers important differences because it is the 
basis for higher or lower digestibility of the fibrous 
carbohydrates (MELLO et al., 2006). The increase 
in fraction C and the reduction of the A + B1 
fractions, implies a reduction in energy availability 
for the microorganisms that ferment fibrous and 
non-fibrous carbohydrates, which may limit the 
efficiency of microbial protein synthesis and 
additionally lead to nitrogen losses in the rumen, if 
protein supplements of medium or rapid degradation 
are used (SILVA; SILVA, 2013). These results were 
lower than those obtained by Ribeiro et al. (2001), 
who evaluated Tifton 85 bermudagrass hay at 
different regrowth ages and found indigestible 
carbohydrate values of 13.59 and 17.87% TC for 
hay with 28 and 56 days of regrowth, respectively. 

The soluble carbohydrate (CS) 
concentration of the Tifton 85 bermudagrass hay 
responded in a quadratic manner to the storage time, 
for cutting heights of 0.04 and 0.08 m above soil 
level; minimum values of 11.53 and 10.70 g kg-1 of 

DM were estimated at 93.44 and 91.16 days of 
storage, respectively (Figure 6). There was no 
difference between heights. The values found for 
this variable in the present study were lower than 
those found by Ribeiro et al. (2001), who when 
evaluating Tifton 85 bermudagrass at different 
cutting ages, found a mean of 40.36 g kg−1 DM, 
where as in the present the mean at the time of 
baling was 26.44 g kg−1 DM. Our values are 
considered low, but common for tropical grasses 
that are naturally low in soluble carbohydrates. 
Morgado et al. (2009), evaluated different feed 
sources for horses when estimating CS levels of 
Coast-Cross grass and also found higher values of 
41.00 g kg−1 DM. 

The decrease in the levels of soluble 
carbohydrates was expected because during the 
process of dehydration of plants, cellular respiration 
occurs and causes the consumption of these 
carbohydrates. Changes in the concentrations of 
these can also occur during storage, because the 
action of microorganisms and moistening of the hay 
can lead to a reduction of the contents. 

 
Figure 6. Soluble carbohydrate concentration of Tifton 85 bermudagrass hay at the cutting height of 0.04 m 

and 0.08 m in relation to storage time in days. 
 

The non-protein nitrogen (NNP), 
represented by fraction A, presented quadratic 
behavior over the storage time evaluated, at a 
cutting height at 0.08 m above soil level and a 
positive linear relationship for cutting heights at 
0.04 m above soil level (Figure 7). Differences were 
detected between heights only at 90 days of storage. 
Low levels of fraction A at 30 days of storage can 
be attributed to the high levels of dry matter 
recorded in hays (mean of 876.62 kg ha-1), an 
indication of the occurrence of less proteolysis 
during storage. The main alteration in the chemical 

composition of hay occurs in the first 30 days of 
storage, which may have affected the A fraction 
(CASTAGNARA et al., 2011). 

Nunes Irmão et al. (2008), working with hay 
from the upper third of cassava shoots harvested 
eight months after planting obtained a value of 
36.89% CP for fraction A, which was higher than 
that found in the present study. According to Russell 
et al. (1992), the sources of NNP are fundamental 
for good ruminal functioning because the 
fermentative ruminal microorganisms of 
carbohydrates preferentially use ammonia as a 



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source of nitrogen. However, the high proportion of 
fraction A will promote large losses of nitrogen 
through ammonia, which can be recycled to the 
rumen; however, a part must be metabolized and 
removed from the body. This process has an energy 
expenditure that is known as the cost of urea 
(OWENS, ZINN, 1988). The higher the values of 

protein fractions A and B1, the greater the need to 
supply rapidly degrading carbohydrates to obtain an 
adequate synchronism in the fermentation of 
carbohydrates and proteins in the rumen, which 
leads to better animal performance (RIBEIRO et al., 
2001). 

 
Figure 7. Percentage values of protein fraction A of hay of Tifton 85 bermudagrass at cutting heights of 0.04 m 

(◆) and 0.08 m (■) in relation to storage time in days. 
 

The proportion of soluble proteins, rapidly 
degradable in the rumen (fraction B1), presented 
quadratic behavior  for 0.04 m cutting heights and a 
positive linear behavior for a cutting height of 0.08 
m, and did not differ between the heights (Figure 8). 

According to Balsalobre et al. (2003), the B1 
fraction is of little importance in forage grasses 
because it normally represents values lower than 
10% of total crude protein. 

  

 
Figure 8. Percentage values of the B1 protein fraction of Tifton 85 bermudagrass hay at cutting heights of 0.04 

m and 0.08 m in relation to storage time in days. 
 
Because of the rapid rumen degradation rate 

relative to the B3 fraction, fraction B1 tends to be 
extensively degraded in the rumen, contributing to 

the N requirements of the microorganisms of this 
compartment (SNIFFEN et al., 1992). 

The values of insoluble protein, with 
intermediate degradation rates (fraction B2), 



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exhibited a negative linear response as a function of 
the storage time, with a reduction of the fraction of 
0.09 and 0.11 percentage units for each day of 

storage, for a hay cut 0.04 and 0.08 m above soil 
level, respectively, and did not differ between the 
cutting heights (Figure 9).  

 
Figure 9. Percentage values of the protein fraction B2 of hay of Tifton 85 bermudagrass at a cutting height of 

0.04 m and 0.08 m in relation to storage time in days. 
 

The insoluble protein content with slow 
degradation rate, represented by the fraction B3, 
exhibited quadratic behavior during the storage 
period evaluated, for the two cutting heights, but 
values did not differ between cutting heights (Figure 

10). The values in the present study were similar to 
those obtained by Sá et al. (2010), who found the 
average value of 32.7% CP for the nitrogenous 
fraction B3 in Tifton bermudagrass 85. 

 
Figure 10. Percentage values of the B3 protein fraction of Tifton 85bermudagrass  hay at cutting heights of 

0.04 m and 0.08 m in relation to storage time in days. 
 

The protein fraction B3 constituted 
approximately 1/3 of the crude protein of the hay 
and presented lower digestion rates, which would 
consequently cause greater leakage into the 
intestines (RIBEIRO et al., 2001). 

The proportion of insoluble non-digestible 
proteins in the rumen and intestines (fraction C) 

exhibited quadratic for 0.08 m cutting height and a 
positive linear relationship for cutting heights of 
0.04 m above soil level (Figure 11). There was no 
difference between the heights with values ranging 
from 9.36 to 21.94% CP. This shows that an 
expressive protein portion from hay is used for 
microbial growth or even as a true protein source in 



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the post-ruminal digestive tract. According to van 
Soest (1994), 5 to 15% of the total nitrogen in the 
fodder is connected to lignin and is completely 
unavailable. The values found were above the range 
considered ideal. 

Fraction C corresponds to unavailable 
nitrogen, and consists of proteins and nitrogen 

compounds associated with lignin, tannin-protein 
complexes, and Maillard products, which are highly 
resistant to the attack of enzymes of microbial and 
host origin (SNIFFEN et al., 1992; VAN SOEST, 
1994). 

 
Figure 11. Percentage values of the protein fraction C of Tifton 85 bermudagrass hay at cutting heights of 0.04 

m and 0.08 m in relation to storage time in days. 
 
 

CONCLUSION 
 

It is recommended the cutting of the Tifton 
85 bermudagrass forage to produce hay at 8 cm and 

its storage up to 30 days provided that under ideal 
conditions. 

 
 

RESUMO: Este trabalho objetivou avaliar o fracionamento de carboidratos e proteína do feno de capim Tifton 
85 sob duas alturas de corte em relação ao nível do solo (0.04 e 0.08 m), durante 120 dias de armazenamento. Foram 
coletadas amostras no enfardamento e no feno armazenado em galpão aos 30, 60, 90 e 120 dias de armazenamento. Após 
foram submetidas a procedimentos laboratoriais, onde foram determinados os teores de carboidratos solúveis, 
fracionamento de carboidrato e fracionamento de proteína. Os resultados foram estudados sob o delineamento em blocos 
casualizados com parcelas subdivididas no tempo com 2 tratamentos alocados nas parcelas: altura de corte de 0.04 e 0.08 
m do solo e cinco tempos nas subparcelas: enfardamento, 30, 60, 90 e 120 dias de armazenamento do feno, com cinco 
repetições. A concentração de carboidratos solúveis respondeu de forma quadrática ao tempo de armazenamento, para 
altura de corte de 0.04 e 0.08 m do solo, estimando-se valores de mínima de 11.53 e 10.70 g kg-1 de MS aos 93.44 e 91.16 
dias de armazenamento, respectivamente. A fração de carboidrato A + B1, respondeu de forma linear negativa aos 
períodos de armazenamento avaliados nas duas alturas de corte, não diferindo entre as alturas. Os teores da fração de 
carboidratos B2 e de proteína A e C apresentaram resposta linear positiva em função do tempo de armazenamento para 
altura de corte a 0.04 m e efeito quadrático para altura de corte do feno a 0.08 m do solo, sendo observado comportamento 
inverso em ambas as alturas de corte para os teores protéicos B1 e de carboidratos fração C. A fração proteica B2 
apresentou resposta linear negativa em função do tempo de armazenamento, com redução da fração de 0,09 e 0,11 
unidades percentuais a cada dia de armazenamento, para altura de corte do feno a 0.04 e 0.08 m, respectivamente. A fração 
B3 respondeu de forma quadrática ao tempo de armazenamento, nas duas alturas de corte estudadas. O armazenamento do 
feno de capim Tifton 85 cortado a 0.04 m de altura do solo, durante 120 dias, ocasiona diminuição das frações de rápida 
degradação ruminal e aumento da fração indigestível, nos fracionamentos de carboidratos e de proteína. Recomenda-se o 
corte da forrageira Tifton 85 para produção de feno a 0.08 m e seu armazenamento até 30 dias em condições ideais. 

 
PALAVRAS-CHAVE: Conservação de forragem. Fenação. Compostos nitrogenados. Amido. 
 



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