Enhancing Physical-chemical Quality and Palatability of
King Grass (Pennisetum Hyrid) Silage Treated by Combination of
Water Soluble Carbohydrate and Legume Sources
Mugi Miralestari
1*
, Asep Sudarman
1
, Sri Suharti
1
, Ahmad Sofyan
2
1
Graduated School of Animal Science
Bogor Agricultural University (IPB), Bogor, Indonesia
2
Laboratory of Bio-Feed Additive Technology, Research Unit for Natural Product Technology (BPTBA)
Indonesian Institute of Sciences (LIPI), Yogyakarta, Indonesia.
Keywords: King grass, legumes, palatability, silage, WSC
Abstract: Silage is alternative technology is needed in the preservation of feed that is easily applied by farmers to needs
forage in the dry season. The grass silage combined with WSC and legume are expected a solution in the
provision of forages that can available throughout the year and improve silage quality. This study was
conducted to examine the effect of combining the addition of various WSC and local legume sources on
physical-chemical quality and palatability of king grass (Pennisetum hybrid) silage. The observed variables
were physical-chemical quality (color, flavor, texture, fungal contamination, DM, OM, pH, and lactic acid),
lactic acid bacteria population and palatability of silage. The experiment was arranged on a completely
randomized of factorial design (4x5) with a treatment factor of king grass with addition of 5% WSC source
(control, molasses, cassava flour, sweet potato flour) and addition of legume source (control, Cassava leaves,
Bauhinia leaves, Leucaena leaves, Gliricidia leaves) and each treatment consisting of 3 replications. The
results showed that the combination of water-soluble carbohydrate and legume source improved the color,
flavor, and silage texture. The addition of legume source had significant effect (P <0.01) on the decrease of
pH silage followed by increasing lactic acid concentration. The combination of WSC and legume had
significant effect (P<0.01) on organic matter. The conclusion of this research is that the addition of WSC and
legume source can improve the physical-chemical quality and can be used as a solution for the farmers in the
provision of forage throughout the year.
1 INTRODUCTION
Currently, Indonesia’s problem are decline in
population and livestock productivity, scarcity of feed
quality and quantity, and still weak farmers about
technology. Low quality of feed and availability of
fluctuating feed were resulted to low of cattle
productivity. The one of forage was used by farmers
is king grass. King grass is easy to grow in high and
low land, and higher production than elephant grass
(Budiman and Djamal, 1994). The availability of king
grass is currently affected by the season. When the
rainy season arrives, the availability of forage is very
high while in the dry season the availability of forage
is very low. So that, the alternative technology is
needed in the preservation of feed that is easily applied
by farmers for fulfill their requirement in the dry
season is silage technology. According to Despal et al.
(2011), silage is anaerobic forage preservation with
spontaneous work of lactic acid fermentation by
epiphytic lactic acid bacteria (LAB). Lactic acid
bacteria will convert water-soluble carbohydrates to
organic acids especially lactate (Chen and Weinberg,
2009). The addition of water-soluble carbohydrate
sources such as molasses is used in silage to increase
dry matter content, lactic acid content, and reduce pH
silage (Tjandraatmadja et al., 1994; Bilal, 2009).
Research conducted by Hidayat (2014), king grass
(Pennisetum purpurepoides) silage with the addition
of molasses 1-3% can maintain the characteristics and
nutrient content. Cassava and sweet potatoes are can
be used as local feed ingredients because they contain
highly fermentable carbohydrates that can be used as
a source of water-soluble carbohydrates in silage
process but, they are low in protein, while protein is
needed in the silage process to increase the crude
270
Miralestari, M., Sudarman, A., Suharti, S. and Sofyan, A.
Enhancing Physical-chemical Quality and Palatability of King Grass (Pennisetum Hyrid) Silage Treated by Combination of Water Soluble Carbohydrate and Legume Sources.
DOI: 10.5220/0010041602700275
In Proceedings of the 3rd International Conference of Computer, Environment, Agriculture, Social Science, Health Science, Engineering and Technology (ICEST 2018), pages 270-275
ISBN: 978-989-758-496-1
Copyright
c
2021 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
protein content and increase the nutritional value of
silage. Therefore, protein sources need to be added in
silage process such as the addition of a legume source.
Tree legumes supplementation such as Lamtoro
(Leucaena leucocephala), Gamal (Gliricidia sepium),
Tayuman (Bauhinia purpurea), and Cassava leaves
(Manihot esculenta Crantz) can be used in silage
process based on availability and easy to find by
farmers. According to Copani et al. (2014), the
addition of legumes to improve the quality of grass
silage with increased protein and WSC content.
Research conducted by Halim (2000) shows that king
grass given an additional of more than 30% legume
can have a beneficial effect on king grass silage
quality. Combination of grass with leguminous and
water-soluble carbohydrate (WSC) on silage making
has the potential to used as a silage that can improve
the nutritional quality. This is supported by Jusoh et
al. (2016), inclusion of molasses and legumes in
silage grass can increase the nutritional value of
silage, improve the quality of silage, can supply a
good quality for animal feed, and lower the cost of
concentrate on animal feed. Thus, the grass silage
combined with WSC and leguminous sources is
expected to be a solution for farmers in the provision
of forages that can be available throughout the year.
This study aims to examine the effect of combining
the addition of water soluble carbohydrate sources
and legume trees sources to physico-chemical quality
and palatability of king grass silage.
2 MATERIALS AND METHODS
This research was conducted at the Laboratory of the
Research Unit for Natural Product Technology
(BPTBA), the Indonesian Institute of Sciences (LIPI)
in Yogyakarta and Food and Nutrition Laboratory,
Faculty of Agricultural Technology, Gadjah Mada
University in September 2017 until January 2018.
2.1 The Procedure of Making Silage
The procedure of making silage consisted of 3 stages
was preparing raw materials, mixing, packing and
incubation. King grass (Pennisetum hybrid) was
harvested at 60 days, which was planted in the forage
collection field of the Research Unit for Natural
Product Technology (BPTBA), the Indonesian
Institute of Sciences (LIPI) in Yogyakarta. King grass
was chopped by chopper in 1-3 cm. Sample of legume
like cassava leaves, Leucaena leaves, Bauhinia
leaves, and Gliricidia leaves was wilted for 24 hours
in room temperature.
Cassava and sweet potatoes
peeled and then cut and put into 55
º
C oven to dry.
After dried, cassavas and sweet potatoes are ground
into flour.
King grass was thoroughly mixed with either 5%
water soluble carbohydrate sources and 5% tree
legume sources. After the ingredients mixed
homogeneously, the mixture silage put into a 1.5 liter
capacity of jar and silage incubated for 21 days at
room temperature. Anaerobic condition was made by
removing free air with manually pushed and
strengthfully tied by a transparent tape. After 21 days
of fermentation, the jars were opened and quality of
silages were assessed.
2.2 Physical Assessment of Silage
The physical characteristics of the silage include
texture, color, flavor, and fungal contamination. The
level of silage flavor was measured by the method of
assessment has been done by Sofyan et al. (2017) :
off-flavor (score 0), less fragrant (score 1), medium
fragrant (score 2), and heavy fragrant (score 3).
Observations level of fungal contamination in silage
was conducted by observing at the presence of mold.
The percentage of fungal contamination on the
surface area by categories : no contamination (0%),
mild (<5%), medium (5-15%), and severe (> 15%).
2.3 Chemical Assessment of Silage
The chemical characteristics of the silage include dry
matter, organic matter, pH and lactic acid
concentration. Dry matter (DM) and organic matter
(OM) according to the procedure of AOAC (2005).
Measurement of acidity degree (pH) by using a pH
meter. The concentration of lactic acid was
determined by acid titration method (AOAC, 2005).
Sample of silage was taken 10 g from each treatment,
added by sterile aquadest (90 ml) then stirred until
homogeneously. The supernatant of samples was
taken (10 ml) to measure pH and lactic acid
concentration. The concentration of lactic acid as
followed the equation :
%LA
Vts Vto
x N x MW x Df
Vs x 1000
x 100%
Note :
LA = concentration of crude lactic acid
Vts = volume of sample titrant (ml)
Vto = volume of blank titrant (ml)
N = normality of titrant (NaOH = 0,097 N)
MW = molecular weight of lactic acid = 90 (g/mol)
Df = dilution factor = 10x
Vs = volume of sample (ml)
Enhancing Physical-chemical Quality and Palatability of King Grass (Pennisetum Hyrid) Silage Treated by Combination of Water Soluble
Carbohydrate and Legume Sources
271
2.4 Microbiological Assessment of
Silage
The number of colonies of lactic acid bacteria was
calculated by the Total Plate Count (TPC) method.
Sample of silage was taken 10 g from each treatment,
added by sterile aquadest (90 ml) then stirred until
homogeneously in aseptic condition. The supernatant
of samples was taken 1 ml and homogenized in
aseptic conditions. Supernatant was grown on
selective media MRSA with serial dilution at 10
2
, 10
3
,
10
4
, 10
5
, and 10
6
in which incubated at 37 ºC for 24
hours and 48 hours.
2.5 Palatability Test of Silage
Palatability test of silage using previous method by
Sofyan et al. (2017). Amount 1000 g of silage which
was harvested, was taken and given to cows that are in
the farms. Each sample of the silage given to the cow
is randomized sample position to minimize the bias in
the sample sequence. Silages that were consumed
more were considered to be more palatable.
2.6 Data Analysis
Data analysis for physical characteristics of silage
were analyzed descriptively. Data of chemical
characteristic such as pH, lactic acid concentration,
lactic acid bacteria population and palatability were
analyzed by ANOVA (analysis of variance), if among
treatments showed significant difference followed
with Duncan test performed by the CoSTAT
statistical software (Cohort, 2008)
3 RESULT AND DISCUSSION
3.1 Silage Quality
The physical qualities of the silage include color,
aroma, texture, and fungal contamination are shown
in Table 1. King Grass silage on the combination of
5% C + LL and 5% MS + 5% LL showed a yellowish
green, while others showed a brownish green. This is
due to the lack of compaction on silos so that there is
still air. According Reksohadiprodjo (1988), the color
changes that occur in the ensilage process caused by
aerobic respiration process that lasts for oxygen
supply is still there until the sugar contained in the
plant runs out. Sugar will oxidize to CO
2
and water
and heat up until the temperature rises. The fragrant
test showed the treated silage 5% C + GL and 5% MS
+ 5% GL had a slightly fragrant compared to other
treatments. Heavy fragrants showed the treated silage
combination 5% CF + 5% CL and 5% CF + 5% LL.
Contrasthy, other study (Sudarman et al., 2016), the
combination of cassava leaves with addition of 5%
cassava flour (tapioca flour) showed mild sour flavor
on silage. Gallaher and Pitman (2000) reported that
good silage has a characteristic yellowish green up to
brownish green color, depending upon silage material
and has pleasant, sour, and sweet smell (Kaiser et al.,
2004). Silage texture showed soft texture except for
5% C + CL and 5% CF + 5% LL silage combination
showed fresh texture. Most numerous fungal
contamination in silage are treatment combinations
5% MS + 5% BL and 5% CF + 5% BL than other
treatments. This may be due to presence of air in the
silo that causes silage contaminated by fungi. Silage
treated by the 5% LL and 5% GL not found fungal
contamination. In this study, generally fungal
contamination on the surface of the silo. According to
Johnson et al. (1998), the level of silage damage
below 5% can still be classified as a good silage.
Table 1: Physical characteristic of king grass silage with
combination of water soluble carbohydrate and legumes
WSC
1
Varia
bles
Legumes
2
C CL BL LL GL
C Color Browni
sh green
Brownish
green
Browni
sh green
Yellowi
sh green
Brownish
green
Flavo
r
Fragran
t
Fragrant Fragran
t
Fragran
t
Slightly
fragrant
Textu
re
Soft Fresh Soft Soft Soft
LFC Slightly
++
Slightly + Slightly
+
Not
foun
d
Not found
MS Color Browni
sh green
Brownish
green
Yellowi
sh green
Yellowi
sh green
Brownish
green
Flavo
r
Fragran
t
Fragrant Fragran
t
Fragran
t
Slightly
fragrant
Textu
re
Soft Soft Soft Soft Soft
LFC Slightly
+
Slightly + Mediu
m +++
Slightly
++
Not found
CF Color Browni
sh green
Brownish
green
Browni
sh green
Browni
sh green
Brownish
green
Flavo
r
Fragran
t
Heavily
fragrant
Fragran
t
Heavily
fragrant
Fragrant
Textu
re
Soft Soft Soft Fresh Soft
LFC Slightly
++
Slightly ++ Mediu
m +++
Not
foun
d
Not found
SPF Color Browni
sh green
Brownish
green
Browni
sh green
Browni
sh green
Brownish
green
Flavo
r
Fragran
t
Fragrant Fragran
t
Fragran
t
Fragrant
Textu
re
Soft Soft Soft Soft Soft
LFC Not
foun
d
Not found Slightly
++
Not
foun
d
Slightly
++
LFC: Level of Fungal Contamination
1
WSC Sources: C (Control); MS (Molasses); CF (Cassava
flour); SPF (Sweet potato flour).
2
Legume Sources : C (Control); CL (Cassava leaves;
Manihot esculenta Crantz); BL (Bauhinia purpurea
leaves); LL (Leucaena leucocephala leaves); GL
(Gliricidia sepium leaves)
ICEST 2018 - 3rd International Conference of Computer, Environment, Agriculture, Social Science, Health Science, Engineering and
Technology
272
Figure 1. Colour of silages with combination of WSC and
legume sources after 21 days ensilage
Table 2. Chemical composition of silages treated by WSC
and legume sources after 21 days ensilage
WS
C
1
Legumes
2
Averag
e
C CL BL LL GL
-------------------- Dry Matter (%) ------------------
C 88.29 89.61 88.62 89.99 88.94 89.09
MS 89.95 89.98 89.25 90.03 89.42 89.72
CF 89.73 90.02 89.85 89.20 89.06 89.57
SPF 89.63 89.48 89.68 88.98 89.36 89.43
Ave
rag
e 89.40 89.77 89.35 89.55 89.19
-------------------- Organic Matter (%) --------------
C 84.17e
f
84.76c
de
f
84.43d
e
f
85.67b
c 84.05
f
84.62c
MS 84.19e
f
84.02
f
84.41d
e
f
85.56b
c
84.72c
de
f
84.58c
CF 85.33b
c
d
87.03a
84.89c
de
f
86.13
b
85.68b
c 85.81a
SPF 84.96c
de
f
85.60b
c
85.08c
de
85.24b
c
d
84.85c
de
f
85.15
b
Ave
rag
e 84.66
b
85.35a 84.70
b
85.65a 84.82
b
Different supersscript in same coloumn or row showed a
significant difference (P<0.01)
1
WSC Sources: C (Control); MS (Molasses); CF (Cassava
flour); SPF (Sweet potato flour).
2
Legume Sources : C (Control); CL (Cassava leaves;
Manihot esculenta); BL (Bauhinia purpurea leaves); LL
(Leucaena leucocephala leaves); GL (Gliricidia sepium
leaves)
Chemical characteristics of silage include dry matter,
organic matter, pH value and lactic acid
concentration, whereas biological characteristics of
silage ie population of lactic acid bacteria are shown
in Table 3. Silage added by WSC and legume sources
was not significant difference (P>0.01) with dry
matter content. This shows the king grass silage with
the addition of WSC and legumes had no effect on
dry matter content. Addition of WSC and legume
sources had significant effect (P<0.01) on organic
matter content. Addition of 5% CF higher organic
matter content than other WSC sources. The content
of theorganic matter is high with the addition of 5%
CF probably due to the high ash content in the sample.
Addition of 5% CL and 5% LL higher organic matter
content than other legume sources. The highest
content of organic matter in the treatment of silage
combination 5% CF + 5% CL.
The addition of legume sources significantly
(P<0.01) on the pH and lactic acid concentration. The
pH value of king grass silage without legume
(control), silage given 5% BL and 5% LL was lower
than silage given 5% CL and 5% GL. The addition of
legume sources increases the pH value compared to
without the addition of legume. According to Heinritz
et al. (2012) that the pH of the leguminous plant
silage after a 92 day fermentation ranged from 4.3 to
6.3. Even if legumes present higher buffering power
in relation to grasses, tending to maintain the pH at
higher values (McDonald et al., 1991). The highest
pH value occurred in the silage combination 5% CF
+ 5% GL compared to other treatments. The pH of
silage in this study was within the normal range of
McDonald et al. (1991), good quality silage has a pH
<4.2. For Kung and Shaver (2001), the pH of legume
silages with 30% DM and perennial temperate grass
silage ranges from 4.3 to 4.7.
Decreasing pH silage value is followed by
increasing the concentration of lactic acid produced.
Decreased pH is accelerated due to the increasing
number of lactic acid produced by lactic acid bacteria.
According to Henderson (1993), the acidity of the
silage is very important in the success of making
silage will prevent forage from spoilage by microbial
spoilage. Total lactic acid in silage with addition of
legume source gave a very significantly (P<0.01).
The highest concentration of lactic acid in the
combination treatment of 5% MS + C and 5% SPF +
C. It is caused by molasses and sweet potato flour to
be a source of water-soluble carbohydrates which is a
substrate source for LAB. In accordance with the
opinion of Sofyan et al. (2017), increased lactic acid
indicated that soluble carbohydrates may support
microbial growth. Other study reported that
concentration of lactic acid in king grass silage with
addition of WSC source (rice bran) resulted in lactic
acid was 7.59-13.40% (Sofyan et al., 2017) and Li et
al. (2014) observed that king grass silase with
addition of WSC sources (molasses, sucrose, and
glucose) resulted in lactic acid was 4.36-4.56%.
Compared those studies, concentration of lactic acid
in this study lower than other studies. Increased lactic
acid followed by a decrease in pH and an increase in
the population of lactic acid bacteria. Ridwan et al.
(2005), the content of lactic acid in silage will affect
the amount of LAB and the degree of acidity.
The population of lactic acid bacteria was
calculated after 21 days ensilage. The addition of
water soluble carbohydrate and legume sources to the
Enhancing Physical-chemical Quality and Palatability of King Grass (Pennisetum Hyrid) Silage Treated by Combination of Water Soluble
Carbohydrate and Legume Sources
273
king grass silage did not significantly affect the
population of lactic acid bacteria. Increased LAB
population occurs from 24-hour incubation to 48-
hour incubation. The addition of WSC and legume
sources has a higher LAB population than controls.
According to Ridwan et al. (2005) that the activity of
lactic acid bacteria is strongly influenced by the
availability of WSC sources in plants because WSC
is a substrate source for bacteria growth. In the
legume itself the source of WSC is low so that in
addition to the source of legume will decrease the
population of LAB and low activity that cause
additive does not give positive effect to activity of
lactic acid bacteria.
Table 3. pH, crude lactic acid, and lactic acid population of
silage with combination of WSC and legume sources
WSC
1
Legumes
2
A
verage
C CL BL LL GL
-------------------
p
H (%) ------------------
C 3.81b 4.15b 3.93b 3.89b 3.85b 3.92ab
MS 3.64b 4.66ab 3.81b 3.74b 3.94b 3.96ab
CF 3.69b 3.89b 4.05b 3.80b 3.92b 3.87b
SPF 3.74b 4.09b 3.88b 3.97b 4.77a 4.09a
Average 3.72c 4.20a 3.92bc 3.85c 4.12ab
-------------------- Crude lactic acid (%) --------------
C 2.34ab 1.79
b
c 1.71
b
c 2.13abc 2.01
b
c 1.99a
MS 2.93a 0.82
d
2.41ab 2.45ab 1.88
b
c 2.10a
CF 2.25ab 2.16abc 1.65
b
c 2.47ab 2.40ab 2.19a
SPF 2.90a 1.72de
f
2.19abc 1.92
b
c 1.38c
d
2.02a
Average 2.60a 1.62
d
1.99
b
c 2.24
b
1.92c
------------ Lactic acid bacteria population 24 hours (Log CFU ml
-
1
)-------------
C 6.68 6.86 6.94 6.52 6.31 6.66a
MS 6.62 6.74 6.47 6.49 7.13 6.69a
CF 6.67 6.38 6.29 7.10 7.02 6.69a
SPF 7.09 6.42 6.77 7.20 7.07 6.91a
Average 6.76a 6.60a 6.62a 6.83a 6.88a
------------ Lactic acid bacteria population 48 hours (Log CFU ml
-1
)
-------------
C 6.94 6.96 6.95 6.74 6.62 6.84a
MS 6.72 6.93 6.53 6.73 7.20 6.82a
CF 6.79 6.78 6.52 7.11 7.06 6.85a
SPF 7.12 6.60 6.86 7.21 7.16 6.99a
Average 6.89a 6.82a 6.71a 6.95a 7.01a
Different supersscript in same coloumn or row showed a
significant difference (P<0.01)
1
WSC Sources: C (Control); MS (Molasses); CF (Cassava
flour); SPF (Sweet potato flour).
2
Legume Sources : C (Control); CL (Cassava leaves;
Manihot esculenta Crantz); BL (Bauhinia purpurea
leaves); LL (Leucaena leucocephala leaves); GL
(Gliricidia sepium leaves)
3.2 Palatability of Silage
Palatability is an illustration of the attraction of
livestock and stimulation of smell, taste and texture
to consume the feed. According to Scharenberg et al.
(2007), feed palatability involves feedstuffs
characteristics that stimulate sensorial acceptance by
olfactory, gustatory, and tactile stimuli in animal.
Palatability test silage to cattle is shown in Table 4.
King grass silage treated with addition of WSC
significantly (P<0.05) on palatability level.
Influenced without addition of WSC source (control)
was not different from the addition of 5% MS but
higher consumtion than the addition of 5% SPF and
5% CF. It shows that without the addition of WSC
(control) and 5% MS has a high level of palatability.
The addition of WSC and legume sources improved
the physical quality by improving silage flavor. In
accordance with the physical parameters in Table 1.
The silage with the addition of 5% MS has a sweet
smell and flavor making it was more palatable.
According Keady (1996) that used molasses as silage
additive improve silage preservation and silage dry
matter intake.
Table 4. Palatability of silage treated by combination of
WCS and legume sources (%)
WS
C
1
Legumes
2
Average
C CL BL LL GL
C 33.24 40.87 38.02 39.32 29.59 36.21a
MS 36.67 33.87 22.50 36.59 17.82 29.49ab
CF 17.28 8.23 23.41 17.99 20.47 17.48c
SPF 19.10 26.26 11.40 16.41 25.30 19.69
b
c
Ave
rag
e 26.57a 27.31a 23.83a 27.58a 23.30a
Different supersscript in same coloumn or row showed a
significant difference (P<0.05)
1
WSC Sources: C (Control); MS (Molasses); CF (Cassava
flour); SPF (Sweet potato flour).
2
Legume Sources : C (Control); CL (Cassava leaves;
Manihot esculenta Crantz); BL (Bauhinia purpurea
leaves); LL (Leucaena leucocephala leaves); GL
(Gliricidia sepium leav
4 CONCLUSIONS
The addition of a water-soluble carbohydrate and legume
sources improve the physical characteristics of king grass
silage. Therefore, adding water soluble carbohydrate can be
practiced by the farmers to enhance the quality of feed
based on king grass silage. Futher study is needed conduct
to evaluate fermentability of silage.
ACKNOWLEDGEMENTS
The authors would like gratefully appreciate to the
Biofeed Additive Research Group, Research Unit for
Natural Product Technology (BPTBA), the
Indonesian Institute of Sciences (LIPI) for supporting
the experiment.
ICEST 2018 - 3rd International Conference of Computer, Environment, Agriculture, Social Science, Health Science, Engineering and
Technology
274
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