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FERMENTATION
By G. S. Olavario
What is
fermentation?
Fermentation is any
metabolic process in which
microorganisms’ activity
creates a desirable change in
food and beverages, whether
it’s increasing flavor,
preserving foodstuffs,
providing health benefits, or
more.
The word “ferment” comes
from the Latin verb “fervere,”
which means “to boil.”
Ironically, fermentation is
possible without heat.
Fermentation is an
enzyme catalysed,
metabolic process
whereby organisms
convert starch or sugar to
alcohol or an acid
anaerobically releasing
energy. The science of
fermentation is called
“zymology”.
How does fermentation
work?
Microorganisms survive using
carbohydrates (sugars, such as glucose) for
energy and fuel.
Organic chemicals like adenosine
triphosphate (ATP) deliver that energy to
every part of a cell when needed.
Microbes generate ATP using respiration.
Aerobic respiration, which requires oxygen,
is the most efficient way to do that. Aerobic
respiration begins with glycolysis, where
glucose is converted into pyruvic acid. When
there’s enough oxygen present, aerobic
respiration occurs.
Fermentation is similar to anaerobic
respiration—the kind that takes place when
there isn’t enough oxygen present.
However, fermentation leads to the
production of different organic molecules like
lactic acid, which also leads to ATP, unlike
respiration, which uses pyruvic acid.
Depending upon environmental conditions,
individual cells and microbes have the ability
to switch between the two different modes of
energy production.
Organisms commonly obtain energy
anaerobically through fermentation, but
some systems use sulfate as the final
electron acceptor in the electron transport
chain.
Process of Fermentation

In fermentation, the first
process is the same as
cellular respiration,
which is the formation
of pyruvic acid by
glycolysis where net 2
ATP molecules are
synthesized. In the next
step, pyruvate is
reduced to lactic acid,
ethanol or other
products. Here NAD+ is
formed which is
re-utilized back in the
glycolysis process.
Process of Fermentation
Fermentation occurs in the absence of oxygen (anaerobic
conditions), and in the presence of beneficial microorganisms
(yeasts, molds, and bacteria) that obtain their energy through
fermentation. If enough sugar is available, some yeast cells, such
as Saccharomyces cerevisiae, prefer fermentation to aerobic
respiration even when oxygen is abundant.
During the fermentation process, these beneficial microbes break
down sugars and starches into alcohols and acids, making food more
nutritious and preserving it so people can store it for longer periods of
time without it spoiling.
Fermentation products provide enzymes necessary for digestion.
This is important because humans are born with a finite number of
enzymes, and they decrease with age. Fermented foods contain the
enzymes required to break them down.
Fermentation also aids in pre-digestion. During the fermentation
process, the microbes feed on sugars and starches, breaking down
food before anyone’s even consumed it.
What Are the Advantages of
Fermentation?
Fermented foods are rich in probiotics, beneficial microorganisms that
help maintain a healthy gut so it can extract nutrients from food.

Probiotics aid the immune system because the gut produces
antibiotic, anti-tumor, anti-viral, and antifungal substances, and
pathogens don’t do well in the acidic environment fermented foods
create.

Fermentation also helps neutralize anti-nutrients like phytic acid,
which occurs in grains, nuts, seeds, and legumes and can cause
mineral deficiencies. Phytates also make starches, proteins, and fats
less digestible, so neutralizing them is extremely beneficial.

Fermentation can increase the vitamins and minerals in food and
make them more available for absorption. Fermentation increases B
and C vitamins and enhances folic acid, riboflavin, niacin, thiamin,
and biotin. The probiotics, enzymes, and lactic acid in fermented
foods facilitate the absorption of these vitamins and minerals into the
body.
What Are the Advantages of Fermentation?

Fermentation is suitable for all
kinds of environments. It is
one of the oldest metabolic
processes which is common
to prokaryotes and
eukaryotes. Fermentation is
widely used in various
industries.
Using suitable
microorganisms and
specified conditions different
kinds of fermentation
products are formed namely:-
Wine
Beer
Biofuels
Yoghurt
Pickles
Bread
Sour foods containing lactic
acid
Certain antibiotics and
What Are the Advantages of Fermentation?

Fermentation can make
food nutritious, digestible
and flavoured. There are
many benefits of
consuming fermented
food.
It improves digestion and
helps to maintain
intestinal bacteria
It has an anti-cancer
effect.
Improves immune system
Reduces lactose
intolerance
Other than the food
industry, there are many
other areas where the
fermentation process is
used. Methane is
produced by fermentation
in sewage treatment
plants and freshwater
Types of Fermentation
Lactic acid fermentation. Yeast strains and bacteria convert
starches or sugars into lactic acid, requiring no heat in
preparation. These anaerobic chemical reactions, pyruvic acid
uses nicotinamide adenine dinucleotide + hydrogen (NADH) to
form lactic acid and NAD+. (Lactic acid fermentation also occurs
in human muscle cells. During strenuous activity, muscles can
expend adenosine triphosphate (ATP) faster than oxygen can be
supplied to muscle cells, resulting in lactic acid buildup and sore
muscles. In this scenario, glycolysis, which breaks down a
glucose molecule into two pyruvate molecules and doesn’t use
oxygen, produces ATP.) Lactic acid bacteria are vital to producing
and preserving inexpensive, wholesome foods, which is especially
important in feeding impoverished populations. This method
makes sauerkraut, pickles, kimchi, yogurt, and sourdough bread.
Lactic Acid
Fermentation
Lactic acid is formed
from pyruvate
produced in glycolysis.
NAD+ is generated from
NADH. Enzyme lactate
dehydrogenase
catalyses this reaction.
Lactobacillus bacteria
prepare curd from milk
via this type of
fermentation. During
intense exercise when
oxygen supply is
inadequate, muscles
derive energy by
producing lactic acid,
which gets
accumulated in the
cells causing fatigue.
Types of Fermentation
Homo
fermentation: only
one type of product
formation
Hetero
fermentation: more
than one product
formed
Types of Fermentation
Ethanol fermentation/alcohol fermentation.
Yeasts break pyruvate molecules—the output
of the metabolism of glucose (C6H12O6) known
as glycolysis—in starches or sugars down into
alcohol and carbon dioxide molecules.
Alcoholic fermentation produces wine and
beer.
Alcohol Fermentation
This is used in the
industrial production of
wine, beer, biofuel, etc.
The end product is
alcohol and CO2.
Pyruvic acid breaks
down into acetaldehyde
and CO2 is released. In
the next step, ethanol is
formed from
acetaldehyde. NAD+ is
also formed from NADH,
utilized in glycolysis.
Yeast and some
bacteria carry out this
type of fermentation.
Enzyme pyruvic acid
decarboxylase and
 Types of Fermentation
Acetic acid fermentation. Starches and sugars from grains
and fruit ferment into sour tasting vinegar and condiments.
Examples include apple cider vinegar, wine vinegar, and
kombucha.
Vinegar is produced by this process. This is a
two-step process.
The first step is the formation of ethyl alcohol
from sugar anaerobically using yeast.
In the second step, ethyl alcohol is further
oxidized to form acetic acid using
acetobacter bacteria. Microbial oxidation of
alcohol to acid is an aerobic process.
Key Microorganisms in Food Fermentation
 Lactic Acid Bacteria
(LAB)
Lactic acid bacteria (LAB) are bacteria that
are common to the dairy industry; it is
assumed that LAB are organisms that produce
lactic acid as the principle byproduct of sugar
fermentations.
LAB are generally more tolerant of low pH
environments than are other bacteria
associated with milk and dairy products.
LAB are common in nature and are often
associated with plant materials. They can also
be found as part of the resident microflora of
humans and other mammals (e.g., oral cavity,
GI track, etc.).
LAB are most known in the dairy industry for
their use in “starter” cultures and dairy
fermentations. As starter cultures, they are
added to milk and allowed to grow under
controlled conditions in order to produce acid
and/or modify the flavor and texture for the
desired characteristics of a cheese or cultured
product.
LAB can also cause milk to “sour” while some
strains may produce gas in cultured products
or cheese that will influence package
appearance and cause product flavor defects.
Lactobacillus species:
These bacteria are
involved in lactic acid
fermentation, which is
critical for the production
of yogurt, sauerkraut, and
pickles. They convert
lactose and other sugars
into lactic acid, lowering
the pH and creating an
inhospitable
environment for spoilage
organisms.
The genera of lactic
acid bacteria

Lactics are classified by the
fermentation pathway used to
ferment glucose and by
their cell morphology. Lactobacill
us are rod shaped organisms
that can be either hetero- or
homofermentative. They are
widespread and can be isolated
from many plant and animal
sources. Lactobacilli are more
tolerant to acid than the other
genera of lactic acid bacteria
and this property makes them
important in the final phases of
many food fermentations when
other organisms are inhibited by
the low pH.
The genera of lactic
acid bacteria

Leuconostoc are ovoid
cocci, often in chains. All
bacteria of this genus have
a heterofermentative mode
of metabolism. When
grown in media containing
sucrose, copious amounts
of a slimy polysaccharide
(dextran) are produced.
Dextran has found uses in
medicine as
a plasma extender and in
biotechnology.
The genera of lactic
acid bacteria
Pediococcus are cocci often
found in pairs and tetrads that
are strictly homofermentative.
Their habitat is restricted mainly
to plants. P. cerevisiae has been
used as a starter culture for the
fermentation of some sausages
with great
success. Streptococcus are cocci
in chains that are distinguished
from the Leuconostoc by their
strictly homofermentative
metabolism. These organisms
can be isolated from oral cavities
of animals, the intestinal tract,
skin, and any foods that come in
contact with these environments.
While the other genera of lactic
acid bacteria rarely cause
disease, Streptococcus
pyogenes is a common,
troublesome pathogen, causing
strep throat and rheumatic fever.
The genera of lactic
acid bacteria
Enterococcus and Lactoco
ccus are two recent
taxonomic divisions of
lactic acid bacteria. These
were created to
reorganize the large and
divergent Streptococcus g
enus into smaller, more
related groups of bacteria.
Enterococcus are
gram-positive cocci that
form pairs or chains. They
are distributed widely in
the environment,
particularly in feces of
vertebrates. Strains can
grow in the presence of
6.5% NaCl and with 40%
bile present.
The genera of lactic
acid bacteria
Lactococcus includes strains that
are gram-positive, spherical cells
occurring in pairs or chains. They
have a strictly homofermentative
metabolism and are found in dairy
and plant products. For centuries
lactic acid bacteria have been used
to produce fermented food products
including pickles, sauerkraut,
sausage, yogurt, cheese, buttermilk,
soy sauce, and more. Some
examples include Streptococcus
thermophilus along
with Lactobacillus bulgaricus that
are used in the production of yogurt.
Also, Lactococcus lactis and S.
thermophilus are two strains often
used as starter cultures in the
production of cheese.
Finally, Lactobacillus and Leuconost
oc are useful in the fermentation of
cabbage to sauerkraut.
 YEAST
The scientific name “Saccharomyces” is derived from the Greek word
meaning “sugar fungus” while “cerevisiae” comes from Ceres the Roman
Goddess of the growth of food plants and crops.
Saccharomyces cerevisiae (S. cerevisiae) is a species of yeast or single-celled
fungus microorganism known since early times for its fermentation
properties and used in baking, brewing, and winemaking. Today, it is also
used as a unique probiotic to support gut health as well as being used for
a variety of other applications.
 YEAST
Saccharomyces cerevisiae is a unicellular fungus that reproduces by budding
from a pre-existing cell, and which presents the main components of a typical
eukaryotic cell. Its cell wall is a dynamic structure relatively rigid that provides
cell protection, and osmotic support and determines cell shape. S.
cerevisiae cells are round to ovoid and are approximately 5–10 micrometers in
diameter.(2)
All strains of S. cerevisiae can grow aerobically on glucose, maltose, and
trehalose. However, they fail to grow on lactose and cellobiose. S.
cerevisiae growth on other sugars varies. Galactose and fructose are shown to
be two of the best fermenting sugars. The ability of S. cerevisiae to use different
sugars can differ depending on whether it is grown aerobically or
anaerobically. Some strains cannot grow anaerobically on sucrose and
trehalose.(3)
In nature, S. cerevisiae is most commonly found on the skin of ripe fruits, such as
grapes. S. cerevisiae can also be found in the bark of some tree species, as well
as on some insects.
S. cerevisiae is one of the most intensively studied eukaryotic model organisms
in molecular and cellular biology.
The genera of lactic
acid bacteria
Lactococcus includes strains that
are gram-positive, spherical cells
occurring in pairs or chains. They
have a strictly homofermentative
metabolism and are found in dairy
and plant products. For centuries
lactic acid bacteria have been used
to produce fermented food products
including pickles, sauerkraut,
sausage, yogurt, cheese, buttermilk,
soy sauce, and more. Some
examples include Streptococcus
thermophilus along
with Lactobacillus bulgaricus that
are used in the production of yogurt.
Also, Lactococcus lactis and S.
thermophilus are two strains often
used as starter cultures in the
production of cheese.
Finally, Lactobacillus and Leuconost
oc are useful in the fermentation of
cabbage to sauerkraut.
 YEAST
Saccharomyces cerevisiae’s use in baking
During fermentation in bread-making, Saccharomyces cerevisiae as
yeast produces carbon dioxide and modifies the physical
properties of dough through the action of enzymes.
First, the yeast ferments sugars which it directly assimilates and
is naturally present in the flour. The second phase corresponds to
the fermentation of sugar found in flour called maltose. Glucose
is transformed by Saccharomyces cerevisiae into carbon dioxide
(which gives volume to bread and the honeycomb shape of the
crumb) and alcohol (evaporated when baked). Saccharomyces
cerevisiae yeast also produces aromatic compounds that
contribute to the aroma and taste of bread. Lastly, during baking,
fermentation is activated by heat and ends when the temperature
reaches 50°C.
 YEAST
Brewer and winemakers’ “secret ingredient”
In the absence of air, Saccharomyces cerevisiae cells transform sugars into
carbon dioxide and alcohol. This process is what changes simple barley or
wheat into beer and grapes into wine.
In beer brewing, saccharomyces cerevisiae is sometimes referred to as a
top-fermenting or top-cropping yeast. Yeast not only plays a major role in the
fermentation process, in brewing but also the aromatic qualities of the end
product. Different types of strains are often brewers’ “secret ingredient.”
Depending on the temperatures used in fermentation, the same strain can
produce different flavors.
Saccharomyces cerevisiae is also the main strain used in winemaking. Yeast in
winemaking is used for the fermentation process just like in brewing. As the
yeast makes alcohol through feeding, it also produces fermentation aromas
(fruity, peach, rose, etc.) and secondary aromas, known as varietal aromas,
associated with specific grape varieties. These secondary aromas can only be
revealed by using specific types of yeast during the fermentation process
(vanilla spice or toasty notes).
 YEAST
Nutritional yeast = saccharomyces cerevisiae
In recent years, many people have started consuming a specific type of
yeast called nutritional yeast or also known as NOOCH. In fact, most
nutritional yeasts are made with the yeast strain Saccharomyces
cerevisiae. It can be used in dietary supplements, seasonings, and
functional foods. Nutritional yeast can also provide appealing nutritional
contributions.

It is a valuable source of protein. These proteins contain all
the essential amino acids that people should get in a healthy
diet. Source of dietary fiber, Saccharomyces cerevisiae yeast
also contains several vitamins like thiamine (B1), riboflavin
(B2), niacin (B3), Pyridoxine (B6), and folic acid (B9). This
makes nutritional yeast a potentially interesting source of
vitamins for all, including vegans and vegetarians.
 MOLDS
There are relatively few molds in fermented food and beverages,
including Actinomycetes, Mucor, Rhizopus, Amylomyces, Monascus, Neurospora, Aspergillu
s, and Penicillium.

The main role of these molds in fermented food is to produce a variety of enzymes. For
example, protease (acidic, neutral, alkaline), amylase, glutamidase, pectinase,
hemicellulase, and cellulase can use starch, oligosaccharide and monosaccharide as
carbon source, and protein, amino acid and urea as nitrogen source.

Maltose can effectively induce Asp. oryzae to secrete various hydrolytic enzymes, such
as Asp. oryzae to secrete α-amylase, Asp. Niger, and Asp. nigrum to produce Glucoamylase
and so on. Starchy raw materials are degraded into small molecular sugars such as
dextrin, maltose and glucose under the action of amylase and glucoamylase.

On the one hand, they promote the growth of bacteria, yeasts and other microorganisms,
and further metabolize to produce alcohols, organic acids and other flavor substances.

On the other hand, some monosaccharides, oligosaccharides, and polysaccharides that
can’t be decomposed increase the nutritional value of the products. Protein raw
materials are decomposed into peptides, amino acids and other functional and flavor
substances by protease. At the same time, these small molecular substances also
contribute to the growth and metabolism of bacteria and yeast.
Stages and Conditions for Successful Fermentation
Inoculation and Lag Phase:
Introduce the initial stage of fermentation where microorganisms are
introduced to the substrate (e.g., milk, dough). Discuss the lag phase
where microorganisms adapt to the environment before active
fermentation begins.
Exponential Growth Phase:
Explain the phase where microorganisms rapidly multiply and metabolize
substrates, leading to significant biochemical changes. Emphasize the
importance of maintaining optimal conditions (temperature, pH, oxygen
levels) for this phase.
Stationary and Decline Phases:
Describe the stages where the growth rate slows due to nutrient
depletion and waste accumulation, eventually leading to the stabilization
of the product's characteristics.
Environmental Conditions:
Detail the specific environmental conditions required for different types of
fermentation, such as anaerobic conditions for alcoholic fermentation and
controlled temperatures for lactic acid fermentation.
Nutritional and Sensory Changes in Fermented Foods
Nutritional Enhancements:
Discuss how fermentation can increase the bioavailability of nutrients, produce
vitamins (e.g., B-vitamins), and reduce anti-nutritional factors in foods. Use
examples like increased folate in fermented vegetables and improved protein
digestibility in fermented dairy.
Sensory Changes:
Analyze how fermentation impacts the flavor, texture, and aroma of food
products. Explain how lactic acid contributes to the tangy taste of yogurt and how
alcohol and carbon dioxide influence the texture of bread.
Case Studies:
Present case studies of specific fermented foods (e.g., yogurt, sauerkraut) to
illustrate how fermentation enhances both nutritional and sensory qualities.
1. Feldmann, Horst (2010). Yeast. Molecular and Cell bio.
Wiley-Blackwell. Pg. 2. ISBN 978-3527326099.
2. https://www.researchgate.net/publication/2222445
79_Brewer’s_Saccharomyces_yeast_biomass_charact
eristics_and_potential_applications
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9041
164/
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https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4261
876/
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