Quantification of Lactic Acid as Secondary Metabolite of Lactic Acid
Bacteria Isolated from Milk and Its Derivatived Products
Fifi Afiati
1
, Fitri Setiyoningrum
1
, Gunawan Priadi
1
and Vania Qyasaty
2
1
RC Biotechnology – LIPI, Jl. Raya Bogor, Km. 46 Cibinong 16911, Indonesia
2
Brawijaya University, Malang, Indonesia
Keywords: Lactic Acid, Lactic Acid Bacteria, Total Acid Test, Secondary Metabolite.
Abstract: Lactic acid is a widely used secondary metabolite product. Titrated Total Acid (TTA) analysis is one of
method to learn quantification process of lactic acid as a secondary metabolite of Lactic Acid Bacteria (LAB).
The TTA test was carried out on 158 isolates from 11 samples with 2 replications using culture supernatant.
The test was started with preparing growth media then rejuvenating the culture. NaOH 0.1 N, oxalic acid 0.1
N, and PP 1% indicator were prepared as reagents for analysis. As the result, the smallest TTA value is shown
in the 1-Sa-L sample with a TTA value of 0.41% and the largest TTA value is shown in the KGL-5 sample
with a TTA value of 1.56%.
1 INTRODUCTION
Lactic acid bacteria (LAB) is common used bacteria
as starter to produce food product such as yoghurt,
cheese, and sausage. LAB has food equivalent safety
(food grade). LAB could reproduce in digestive tract,
affect balance of digestive tract bacteria which
provide a healthy effect, as probiotic. LAB is isolated
from various sources and explored functional
potential effect to enhance human health. Milk is rich
of protein, fat, carbohydrate (mainly lactose), and
vitamin and mineral (Park et al., 2007), and become
ideal habiTTA for microorganism growth. Lactose, as
main carbohydrate compound in milk, is fermented
with microorganism, especially LAB group to
produce lactic acid as major metabolite, creating milk
with sour taste. Lactic acid is secondary metabolite
product, could be produced in two ways which are
using chemical synthesis and microbiological
fermenTTAion.
Lactic acid production using microbiological
fermenTTAion has some advantages, one of the
advantage is the high purity (90 – 95 %)
(Kotzamanidis et al., 2002) of optical L(+) lactic acid
with high crystallinity and melting point. In the other
hand, chemical synthesis of lactic acid produce mix
result in D-L configuration. FermenTTAion in
producing lactic acid has some disadvantages such as
bacteria growth medium is not economical since it
contains some expensive composition like yeast
extract and peptone. FermenTTAion process
produces primary and secondary metabolite. Primary
metabolite is chemical compound produced and used
by microbes to regenerate which are lactic acid and
alcohol. Secondary metabolite is compound produced
by microbes but not used for physiological activity
like bacteriocin. Kefir fermenTTAion is done with
LAB and yeast. LAB is used to produce lactic acid
from glucose and triggered yeast’s growth. In kefir
making process, yeast has function to produce ethanol
and flavor component as specific kefir taste. (Usmiati,
2007)
Whey contains high nutrition and has benefit for
health such as controlling body metabolism,
probiotic, animal antitumor, and antibacterial
(Farnworth, 2003). Whey is defined as serum or the
water portion of the milk that remains after separation
of curd (cheese) and is the result of coagulation of
milk protein with acids and proteolytic enzymes
(Usmiati, 2007). One kilogram of cheese produced
will produce as much as 8 to 10 liters of whey
(Farnworth, 2003). Whey in Indonesia is generally
underutilized, thus polluting the environment. Whey
cheese has a Biochemical Oxygen Demand (BOD)
and Chemical Oxygen Demand (COD) content which
does not meet the permitted safe limits, namely
50,000 mg / L (BOD) and a COD level of 80,000 mg
/ L (Guimaraes et al., 2010). Environmental pollution
can be reduced by utilizing whey as a basic ingredient
132
Afiati, F., Setiyoningrum, F., Priadi, G. and Qyasaty, V.
Quantification of Lactic Acid as Secondary Metabolite of Lactic Acid Bacteria Isolated from Milk and Its Derivatived Products.
DOI: 10.5220/0010546700003108
In Proceedings of the 6th Food Ingredient Asia Conference (6th FiAC 2020) - Food Science, Nutrition and Health, pages 132-136
ISBN: 978-989-758-540-1
Copyright
c
2022 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
in the manufacture of probiotic functional drinks such
as yogurt or kefir. Whey kefir is the latest innovation
in whey processing which is fermented by a number
of microbes, namely lactic acid-producing bacteria
(LAB), acetic acid-producing bacteria, and yeast.
Inhibition zone produced by the metabolite
compound L. plantarum against Gram-negative and
positive pathogenic bacteria is a result of the presence
of primary metabolite such as lactic acid, ethanol,
diacetyl, and carbon dioxide and secondary
metabolites such as bacteriocins and hydrogen
peroxide.
Inhibition zone produced by the metabolite
compound L. plantarum against Gram-negative and
positive pathogenic bacteria is a result of the presence
of primary metabolite such as lactic acid, ethanol,
diacetyl, and carbon dioxide and secondary
metabolites such as bacteriocins and hydrogen
peroxide.
Logarithmic phase is 15-24 hours on incubation
period. Metabolite compounds from L. plantarum can
inhibit Gram-positive and negative pathogenic
bacteria which are often found in foodstuffs of animal
origin, especially meat and milk, so that it has a good
enough potential to be studied in more depth
regarding its use directly in foodstuffs of animal
origin. The process of producing bio preservation
materials for food from the metabolism of L.
plantarum has the potential to be developed and
applied to foodstuffs of animal origin, especially milk
and meat.
2 MATERIALS AND METHODS
2.1 Preparation of Growth Media and
LAB Culture Growth
The growth media for Lactic Acid Bacteria (LAB) are
MRS-agar and MRS-broth. Sterile Lactobacillus
MRS Broth (HIMEDIA, M369) was used. Pre-culture
stage was needed to refresh isolates which used to be
stored at -80 °C before use, then isolates were
incubated for 24 hours at 37 °C, characterized by a
white sediment and the growing medium becomes
cloudier. After that, isolates were homogenized and 5
µL was regrown in sterile MRS Broth media to be
incubated for 18 hours (overnight) at 37 °C
2.2 Total Titrated Acid Test (TTA)
One of the reagents in the Titrated Total Acid (TTA)
test is 0.1 N NaOH. Volume of NaOH needed
showing the acid present in isolates because NaOH
would neutralize the acid and was indicated by a
change in color to pink.
The amount of NaOH and distilled water used in
order to get the desired normality follows the
following formula:
N
NaOH =
g
ram/MR × 1000/(v (mL)) (1)
2.3 Preparation of 0.1 N Oxalic Acid
Preparation of 0.1 N Oxalic Acid solution aims to
standardize and determine the normality of NaOH
precisely. Weighed 0.9 gram of powdered oxalic acid
and dissolved in 100 mL of distilled water then stirred
until the solids and solution were completely mixed
to form a 0.1 N oxalic acid solution. The calculation
of the amount of powdered oxalic acid with a relative
molecular mass value of 90 (Mr = 90) and the distilled
water used in order to obtain the desired normality
follows the following formula:
N
oxalic acid =
g
ram/MR × 1000/(v (mL)) (2)
2.4 Standardization of NaOH
NaOH standardization is carried out to determine the
normality value of NaOH in more detail. NaOH
standardization is carried out by using the titration
principle. The 0.1 N oxalic acid solution was put into
a 100 mL erlenmeyer, while the NaOH solution was
put into a burette. The 0.1 N oxalic acid solution was
then titrated with NaOH solution until it turned pink.
Titration is carried out three times so that the results
can be more accurate. At each titration, the volume of
NaOH used was recorded. The volume of NaOH
obtained is then averaged so that the final volume will
be used in the calculation. The standardized value of
NaOH concentration is 0.1135 N. Calculation of the
NaOH concentration follows the following formula:
N NaOH = (Volume oxalic acid × N oxalic
acid)/(Volume NaOH)
(3)
2.5 Preparation of PP (Phenolphtalein)
Indicator 1%
The PP indicator is used as a color indicator in the
titration process both in the total acid test and when
standardizing NaOH. The PP indicator serves to
determine the exact equivalence point in a solution
marked by a change in color. 0.5 grams PP in powder
form is weighed using a digital scale, then dissolved
with 96% ethanol 50 mL in a beaker glass until well
blended. The finished PP indicator solution is then put
Quantification of Lactic Acid as Secondary Metabolite of Lactic Acid Bacteria Isolated from Milk and Its Derivatived Products
133
in a dark glass bottle to keep the concentration
unchanged.
TTA test was carried out on 80 samples with twice
analysis each sample. Repetition is purposed to obtain
more accurate results. If the standard deviation
between repetitions does not exceed 10%, the results
obtained can be used as final data. The TTA test was
carried out to determine the acid content found in
LAB isolates. The measurement of the total titrated
acid (TTA) is the determination of the total acid
concentration. Total Titrated Acid (TTA) relates to
the measurement of the total acid contained. The TTA
value includes the measurement of total dissociated
and undissociated acid. The results of TTA
measurement are used to determine the amount of
organic acids in fruits and vegetables.
TTA test is carried out only on the supernatant
part of the culture so that before the TTA test is
carried out, the sample is centrifuged first. The
sample to be used is put into a microtube for
centrifuge. The centrifuge was carried out at a speed
of 9000 rpm for 2 minutes.
TTA test basically uses the titration principle. 1
ml sample is pipetted into a 100 mL erlenmeyer, then
diluted up to 10 times by adding 9 mL of sterile
distilled water. To show the equivalence point in the
solution, the PP indicator is added so that the solution
will turn pink when it reaches the equivalence point.
When it reaches the equivalence point, the titration is
stopped and the initial volume and final volume of
NaOH are recorded which will be used in the
calculation to obtain the final data.
3 RESULTS
The following are the results of the TTA analysis for
each sample:
Table 1: Total Titrated Acid (TTA) value from milk and
its derivated products.
Isolates TTA (%)
K. Kam 1 0.996 ± 0.04
B
K. Kam 2 1.468 ± 0.09
C
K. Kam 3 1.124 ± 0.04
B
K. Kam 4 0.562 ± 0
A
K. Kam 5 1.660 ± 0.07
D
K. Kam 6 0.562 ± 0.07
A
Table 2: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
W.K. Sapi 1 1.532 ± 0
C
W.K Sapi 2 1.545 ± 0.02
C
W.K Sapi 3 1.162 ± 0.05
A
W.K Sapi 4 1.328 ± 0.04
B
W.K Sapi 5 1.187 ± 0.02
A
W.K Sapi 6 1.315 ± 0.09
B
Table 3: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
KGG - 1 0.664 ± 0
C
KGG - 2 0.6 ± 0.02
AB
KGG - 3 0.626 ± 0.05
BC
KGG - 4 0.613 ± 0
ABC
KGG - 5 0.562 ± 0
A
KGG - 6 1.622 ± 0.02
D
KGG - 7 1.609 ± 0.04
D
KGG - 8 0.626 ± 0.02
BC
Table 4: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
KGP - 1 0.562 ± 0.04
A
KGP - 2 0.6 ± 0.05
A
KGP - 3 1.2 ± 0.07
BC
KGP - 4 0.626 ± 0.02
A
KGP - 5 1.302 ± 0.07
C
KGP - 6 1.111 ± 0.09
B
KGP - 7 1.124 ± 0
B
KGP - 8 1.175 ± 0.07
BC
KGP - 9 0.702 ± 0.09
A
Table 5: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
KGB - 1 0.702 ± 0.02A
KGB - 2 0.753 ± 0.02AB
KGB - 3 0.728 ± 0.02AB
KGB - 4 0.766 ± 0.04AB
KGB - 5 1.251 ± 0.07F
KGB - 6 1.149 ± 0EF
KGB - 7 0.958 ± 0.09CD
KGB - 8 1.047 ± 0DE
KGB - 9 0.856 ± 0.09BC
6th FiAC 2020 - The Food Ingredient Asia Conference (FiAC)
134
Table 6: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
KGL - 1 1.468 ± 0.02A
KGL - 2 1.073 ± 0B
KGL - 3 1.085 ± 0.05B
KGL - 4 0.741 ± 0.04A
KGL - 5 1.558 ± 0.07A
KGL- 6 1.047 ± 0.04B
KGL- 7 0.729 ± 0.04A
KGL- 8 1.366 ± 0.02C
KGL- 9 1.302 ± 0.07C
Table 7: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
SS - 1 1.353 ± 0.04E
SS - 2 1.047 ± 0D
SS - 3 0.843 ± 0.04C
SS - 4 0.536 ± 0A
SS - 5 0.779 ± 0.02B
Table 8: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
1-Sa-A 0.511 ± 0.04A
1-Sa-B 0.677 ± 0.09B
1-Sa-E 0.485 ± 0.04A
1-Sa-F 0.447 ± 0.02A
1-Sa-G 0.421 ± 0.02A
1-Sa-H 0.498 ± 0.09A
1-Sa-I 0.421 ± 0.05A
1-Sa-J 0.498 ± 0.02A
1-Sa-
K
0.409 ± 0.04A
1-Sa-L 0.409 ± 0.04A
Table 9: Total Titrated Acid (TTA) value from milk and its
derivated products.
Isolates TTA (%)
2-Sa-A 0.562 ± 0.07A
2-Sa-B 0.715 ± 0B
2-Sa-C 1.073 ± 0.07C
2-Sa-D 0.434 ± 0.04A
Table 10: Total Titrated Acid (TTA) value from milk and
its derivated products.
Isolates TTA (%)
2-JR-A 0.485 ± 0A
2-JR-B 0.498 ± 0.02A
2-JR-C 0.524 ± 0.02AB
2-JR-D 0.511 ± 0.04AB
2-JR-E 0.562 ± 0.04BC
2-JR-F 0.536 ± 0.04ABC
2-JR-G 0.587 ± 0C
Table 11: Total Titrated Acid (TTA) value from milk and
its derivated products.
Isolates TTA (%)
1-PE-A 1 0.69 ± 0.04C
1-PE-C2 0.664 ± 0BC
1-PE-D3 0.447 ± 0.05A
1-PE-E4 0.562 ± 0.07AB
1-PE-G5 0.549 ± 0.02AB
1-PE-I 6 0.932 ± 0.05D
According to Kusumawati et.al (2008), lactic acid
bacteria produce compounds that are antimicrobial
such as organic acids, hydrogen peroxide and protein
compounds (bacteriocin). Lactobacilli species which
produce sufficiently large amounts of hydrogen
peroxide can inhibit growth and kill pathogenic
microbes. The accumulation of these compounds in
cells occurs because lactobacilli does not produce the
enzyme catalase.
Lactic acid bacteria will convert carbohydrates
into lactic acid under anaerobic conditions and this
process can be divided into three stages. In the early
stages, starch from carbohydrate sources will be
hydrolyzed into maltose by α and β amylase, then this
maltose molecule will be broken down into glucose
by maltase and in the final stage lactic acid bacteria
will convert glucose into lactic acid and other
materials such as acetic acid and alcohol.
Secondary metabolites are compounds that are
synthesized by microbes but are not a basic
physiological requirement. One of the secondary
metabolites that can function as antibacterial is
bacteriocin (a protein compound that exhibits
antibacterial activity and is able to prevent the growth
of disease-causing bacteria). Bacteriocin produced in
the decay or stationary phase, which is the phase
when the substrate starts to run out, will stimulate the
formation of enzymes that play a role in the formation
of secondary metabolites.
Lactic acid bacteria (LAB) are a group of bacteria
that have been widely used as a starter to produce
food ingredients such as yogurt, cheese and sausages.
Based on a long history of safety in the consumption
of food produced using LAB, this class of bacteria is
recognized as having food-grade safety. LAB isolates
were characterized morphologically and
physiologically based on Gram characteristics, gas
production from glucose and catalase production.
Only Gram positive and catalase negative isolates
were further identified. Catalase testing is done by
dropping one drop of LAB culture over 30% H2O2
solution. Positive catalase is characterized by the
formation of foam (bubbles / foam). Gram staining
was carried out to see cell morphology and
Quantification of Lactic Acid as Secondary Metabolite of Lactic Acid Bacteria Isolated from Milk and Its Derivatived Products
135
characteristics of Gram. Gas formation from glucose
is carried out using hot loops and gas formation is
characterized by the formation of froth. Lactic acid
bacteria also produce other metabolites that function
as anti-microbes such as acetic acid, hydrogen
peroxide, and bacteriocins. The increase in lactic acid
from secondary metabolites of lactic acid bacteria is
caused by the increasing number of cell biomass that
ferments the substrate into lactic acid and energy.
According to Yusmarini and Efendi (2004), the sugar
contained in the media is used by lactic acid bacteria
as a carbon source to produce lactic acid and energy
through the glycolysis process.
According to Farnworth (2003), fermentation of
milk into kefir produces metabolites that are
beneficial to health, namely exopolysaccharides and
bioactive peptides. Both of these compounds will
stimulate the immune system. The polysaccharides
formed in kefir also act as anti-tumor agents.
Antibacterial components are also produced during
kefir fermentation such as organic acids (lactic and
acetic acids), carbon dioxide, hydrogen peroxide,
ethanol, diacetyl, and peptides (bacteriocins) which
are not only useful for inhibiting the growth of
pathogenic bacteria and spoilage bacteria during food
processing and storage, but can also be used for the
prevention of some digestive disorders and infections.
The composition and taste of kefir will differ
significantly depending on several factors. The main
factor that can distinguish is the source of milk used
whether it comes from cow's milk or goat's milk.
Other factors that play a role are the fat content of the
milk used, the composition of the kefir seeds and
starter used, and the accompanying technological
process. Traditionally kefir is produced by adding
kefir seeds to some milk.
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