Fermentation Technology PDF

Summary

This document provides an overview of fermentation technology, covering topics such as the different types of fermentations, the importance of microorganisms in industrial processes, and the various applications of fermentation technology in industry. It includes details on the techniques used for isolation, screening, and preservation of microorganisms. It also offers information concerning downstream processing and bioreactor designs.

Full Transcript

FERMENTATION TECHNOLOGY

BY

DR. ADEBAYO ISMAIL ABIOLA
(PhD USM Penang)
INTRODUCTION
 Fermentation is a chemical process where by organic macromolecules
such as glucose are broken down to give a desired end products.
For examples, antibiotics, wine, yoghurt, and beer are produced by
fermentation process.
A fermenter is needed for fermentation to take place industrially.
The main function of a fermenter is to provide a suitable environment
for microorganisms to yield or produce the desired products metabolites
and cell biomass.
 The performance of any fermenter depends on many physical and
chemical factors.
Laboratory fermentation can be performed in bottles or conical flasks,
which are usually shaking for aeration.
These vessels are usually cover with cotton wool to prevent
contamination
However, this can lead to restriction in exchange of gases and evaporation
loss.
Hence, vessels specifically constructed for fermentation are usually
preferred.
In industries, fermenters with capacities to contain several thousands of
litters are used.
INDUSTRIALLY IMPORTANT MICROORGANISMS
The microorganisms that are used in industry for the production of certain useful and
important products have some characteristics which are essential for them to be used in the
industry. The characteristics are:

1. They grow vigorously and rapidly in the medium.
2. they must not produce toxic end-products or undesirable materials, especially when the
products are meant for human consumption.
3. they must have significant physiological and genetic stability.
4. they should be able to use carbon sources that are cheap and readily available for
growth.
5. it is desirous when the microorganisms have their optimum productivity at low pH and
high temperature environment where there is less competition for growth medium.
6. the organisms should be able to produce agents that are inhibitory to competitors.
7. the organisms should be resistant to predators such as bacteriophages.
Examples of some microorganisms that are
used in Industry
microorganisms Products Uses
Antibiotic productions
Penicillium chrysogenum, Penicillin Anti-fungal
Penicillium griseofulvum
Bacillus polymyxa Polymyxin B Anti-Gram-negative bacterial
Streptomyces erythreus Erythromycin Anti-Gram-positive bacterial
Streptomyces fradiae Neomycin Broad spectrum antimicrobial
Streptomyces griseus Streptomycin Anti-Gram-negative bacterial
Streptomyces rimosus Tetracycline Broad spectrum antimicrobial
Streptomyces mediterranei Rifamycin Anti-tuberculosis
Organic Acids production
Microorganisms Organic acids
Lactobacillus delbrueckii Lactic acid
Acetobacter with ethanol solution Acetic acid
Rhizopus nigricans in sugar-based Fumaric acid
medium
Aspergillus niger in molasses-based Citric acid
medium
Aspergillus niger in glucose-mineral salts Gluconic acid
medium
Biosurfactant Production
Biosurfactants are agents or chemicals that are used for emulsification, solubilization and phase dispersion of
solutions. They are used in food, beverages and soap industries. These biosurfactants are produced by
bacteria, yeasts and fungi extracellularly and they form parts of their cell membrane where they perform vital
functions. Examples of biosurfactants are fatty acids, phospholipids, glycolipids, and lipopeptides. Below are
examples of biosurfactants that are produced by microorganisms:

Microorganisms Surfactant produced
Candida bombicola, Candida apicola Sophorolipids
Pseudomonas aeruginosa Rhamnolipids
Bacillus subtilis Surfactin
Acinetobacter calcoaceticus Emulsan
Other microorganisms that are used in Industry
Microorganisms Uses
Saccharomyces cerevisiae (yeast) Production of bread, beer, cheese, wine,
spirits and other diary products
Acetobacter species Production of vinegar
Brevibacterium lactofermentum Production of lysine (amino acid)
Bacillus subtilis Production of α-amylase
Pseudomonas denitrificans Production of Vitamin B12
(cyanocobalamin)
Salmonella typhi Production of vacine
Isolation and screening of industrially important
microorganisms from the environment
The microorganisms that are industrially important are usually isolated by two methods:
the ‘shotgun method’ and the ‘objective method. In the shotgun method, microorganisms
are isolated from samples from biofilms, free living organisms and other microflora
communities in plants and animals, water, sewage, soil, natural and man-made habitats
and environments. In the objective approach, microorganisms are isolated from a specific
and definite sites where they are considered to be the likely natural habitat of the target
microorganisms. For example, samples can be taken from oil spillage environment or field
to search for and isolate microorganisms that can biodegrade the oil and its by products.
Once the microorganisms have been purely isolated by repressing the growth or killing the
common microorganisms to allow the uncommon and target microorganisms to thrive, the
microorganisms should be screened. The microbial isolates will be primarily screened for
certain desired properties which is the production of the specific products such as
antibiotics, inhibitory compound, enzymes etc.
There will also be secondary screening for the microorganisms which will include the
screening for the stability and non-toxicity of the microorganisms and their end-products.
Preservation of cultures
The cultures of industrially important microorganisms are generally preserved in culture
collections. These culture collections housed microorganisms that are of past, present, and
future interest. In the UK, the most common culture collection is the Nation Culture Collection
(UKNCC) and in the US, the most common culture collection is the American Type Culture
Collection (ATCC). These two collections hold and preserved all type of known microorganisms
and they could supply any research institution the microorganisms if needed.
The common methods of culture preservation are the cryopreservation, freeze drying, and a
more convenient and better method which involves adsorption of cells in to glass beads.
Cryopreservation involves the preservation of the microorganism in cryovial in a frozen
condition.
Freeze drying involves the act of freezing the microorganisms into dryness such that their
biochemical activities are inactivated.
The adsorption method involves the adsorption of microorganisms in to beads in a glass such
that when the microorganisms are needed, 1-2 beads could be taking for thawing rather than
thawing the whole sample.
Strain improvement
To maximise the production of desirable end-product by the
microorganisms, the essential characteristics of the industrial
microorganisms earlier stated could be enhanced or improved. The
major approach employed is the use genetic manipulations which are
the natural DNA recombination, mutagenesis, and genetic engineering.

DNA recombination
Mutagenesis
Genetic engineering
Media formulation
Carbon source
Carbon is an essential element for biosynthetic reactions that lead to
reproduction, cell maintenance, and product formation. In fermentation, it is
the primary energy source. The carbon requirements for growth and
production of desired end products vary from one microorganisms to
another.
Traditionally, carbohydrate is the energy and carbon source for microbial
fermentation, however, other sources such as alkanes, alcohol, organic acids,
plant oils and animal fat could be used as the main carbon source or
supplements.
Molasses are preferred to pure glucose and sucrose as carbon source in
fermentation industry because the two latter carbohydrates are relatively
expensive. Molasses is a by-product of beet and cane sugar production
which is cheaper. It is a viscous syrup with dark colour. It has about 60 %
(w/w) carbohydrates which are majorly sucrose, 2 % (w/w) nitrogenous
substances, and the remaining composition are vitamins and minerals.
Another similar carbon source is hydro molasses, which is the by-product of
maize starch processing and it primarily contains glucose.
Yeast, filamentous fungi and actinomycetes are usually cultured in an
industrial scale using malt extract as carbon source. The malt extract is
a form of syrup that are made from aqueous extract of malted barley.
The malt extract composed of 90 % carbohydrates, of which 55 % are
disaccharides (maltose and sucrose), 20 % are hexoses (glucose and
fructose), and 10 % are trisaccharide (maltotriose). The malt extract
also contains amino acids, peptides, proteins, nitrogenous substances
and vitamins.
It should be noted that malt extract must not be over-heated during
sterilization as it could results to loss of fermentable products,
inhibition of microbial growth and change in colour of growth
medium.
Filamentous fungi that are amylase-producing microorganisms can
directly metabolize polysaccharides such as starch and dextrins to
produce a mixture of monosaccharides and disaccharides (maltose,
glucose and maltotriose) which can then be used as carbon sources.
Sulphite waste liquor which has hexoses and pentoses are also used
for the yeast cultivation in industry.
In solid-state fermentation, cellulose are used as substrate for
mushrooms production. Cellulose is found in plant cell wall and it is
usually gotten from industrial, agricultural, forestry and domestic
waste.
Lactose can also be sourced for from whey. Whey is the by-products of
diary industry. However, fewer microorganisms such as Saccharomyces
cerevisiae can use lactose as carbon source.
Long chained Alkanes and methanol, ethanol are readily metabolized
by certain microorganisms as carbon sources, however, they are very
expensive and not cost effective for industrial scale production. Ethanol
can be bio-transformed by Lactic acid bacteria to acetic acid and the
method is still in use in the industry.
Fat and Oils
In antibiotic productions, plant oils from maize, linseed, cotton seed,
rape seed, palm and soya, and also fish oil could be used as primary or
supplementary source of carbon. The oils contains oleic and linoleic
acids and they have more energy per weight than carbohydrates.
Nitrogen sources
Both organic and inorganic nitrogen sources are used by industrial
microbes for getting nitrogen. Nitrogen sources that are used in
industry are usually supplied in crude forms, and they are by-products
of other industries. The nitrogen sources are yeast extracts, soya meal,
corn steep liquor and peptones. Purified amino acids are only used in
special, exceptional situation as precursors for specific products.
Water
All fermentation processes with the exception of the solid-substrate
fermentations, need a large quantity of water. Sometimes, trace
elements are supplied into the growth media through the water. Prior
to use, colloids, suspended solid materials and microorganisms must be
removed from the water. If the water is hard, salts such as calcium
carbonated should be removed. The water must be well-treated such
that it meets the standards to be used in the fermentation process.
Other substances and chemicals needed in the media includes
minerals, vitamins, growth factors, inducers and elicitors, inhibitors,
oxygen and cell permeability modifiers etc.
Fermentation and its types
In the context of industrial microbiology, fermentation is the process of
growing large quantities of cells under aerobic or anaerobic conditions,
within a bioreactor or fermenter. Fermentation can be aseptic or non-
aseptic. The aseptic and non-aseptic fermentations can also be aerobic
and non-aerobic.
An example of aseptic, aerobic fermentation is the antibiotic
production by microorganisms while the production of lactic acid by
lactic acid bacteria is an aseptic, anaerobic fermentation process.
Mushroom production is a non-aseptic, aerobic fermentation process
and microbial diary fermentation is a non-aseptic, anaerobic
fermentation process.
The two major types of
fermentations are the solid-
substrate fermentation and
submerged fermentation
Solid state fermentation
Solid state fermentation is a fermentation process that involves growing of
microorganisms on solid materials, which are normally organic but could be
inorganic, in the presence of little or no free water. It is a common method
that is used for fermentation of foods in Asian countries. The substrates that
are commonly used for this type of fermentations are legumes, bran, cereal
grains and lignocellulosic materials such as straw and wood. This type of
fermentation can be used for the production of cheese and mushrooms.
Ethanol, enzymes and organic acids can also be produced by solid-substrate
fermentation process. Even though, solid-substrate fermentation has its
advantages and disadvantages, in certain cases, the method is inevitable. For
instance, in the production where fungi sporulation is required, solid-
substrate fermentation must be used because fungi can not form spores in
submerged fermentation. The method is employed in the production of
Coniothyrium minitans spores for the biocontrol of Sclerotinia sclerotiorum
(a fungal plant pathogen).
 Advantages and disadvantages of solid-substrate
fermentation
Advantages Disadvantages
Cheap media usage Bacterial contamination
Simple technology Difficulty in controlling substrate
moisture level
It has the ability to provides better Problems with heat build-up
productivity
Low-capital cost Difficulty often encountered on a scale-
up
Relatively low energy requirements
Low waste-water output
Absence of foaming problem
Step-by-step process of solid-substrate
fermentation
Solid-substrate fermentation is usually performed in a sequential
multistep processes, which are:
1.Pretreatment of a substrate by chemical, biological or mechanical
processing
2. Hydrolysis of primarily polymeric substrates. E.g. proteins and
polysaccharides
3. Utilization of the hydrolysis products
4. separation and purification of end-products.
Environmental parameters that influence
solid-substrate fermentation
The environmental parameters that influence or affect solid-substrate
fermentation are water activity, temperature, and aeration.
Water is lost during fermentation through metabolic activity and
evaporation. This water is usually replaced by addition of water or
humidification. If excess water is added such that the moisture level is
too high, the porosity of the substrate will be reduced, the diffusion
rate of the oxygen will be lowered, rate of gaseous exchange will also
be reduced, the rate of substrate degradation will be decreased, and
there will be high risk of microbial contamination. On the other hand, if
the moisture level is too low, the substrate does not swell and becomes
less accessible, thus, it will results to reduction of microbial growth.
Temperature level in solid-substrate fermentation is largely controlled
by substrate agitation and aeration. Heat generated during the process
can be more problematic and it has a major influence on the humidity
within the fermentation.

Aeration: most solid-substrate fermentations are aerobic but the
oxygen requirements depends on the specific process and
microorganisms used. The rate of oxygen transfer is determined by the
size of substrate particles.
Bioreactors used for solid-substrate
fermentations
The solid-substrate fermentations are usually batch processes, they are
not continuous. Some processes do not require a bioreactor, in such
processes, substrates are simply spread onto a suitable surface or floor.
The bioreactors that are used in the solid state fermentation include:
rotating drum fermenter, bed systems, tray fermenter, fluidized bed
reactor, and column bioreactor.
Rotating drum fermenter
It comprises of a 100L capacity cylindrical vessel. Attached to the sides
of vessel are two rollers that support and rotate the vessel. The
fermenter is used in microorganisms biomass and enzyme production.
The major demerit is that the drum can only be filled to 30 % capacity
for efficient agitation. (the figure below was adopted from Waites et al.,
2001)
Tray fermenter
Tray fermenter is used for the production of enzymes and fermented
oriental foods. The substrates are spread onto each tray and the trays
are stacked in aerated chamber that allows the circulation of
humidified air. (the figure below was adopted from Waites et al., 2001)
Bed system
This type of fermenter is used in koji production. It consists a 1 m deep
bed of substrate. Humidified air is continuously forced into the system
from below the system. (the figure below was adopted from Waites et
al., 2001)
 A Typical Bioreactor/ Fermenter

(the figure below was adopted from Waites et al., 2001)
Wine production
The alcoholic fermentation of the sugars of juices of fruits especially
grapes produce wine. This alcoholic fermentation depends on
microorganisms to occur. The varieties of several flavours and aromas
of wine that are available are as a result of microbial transformation
and processing that occur during fermentation and ageing.
Ethanol Production
In 1970s, Brazil and other countries used to produce ethanol by
employing Saccharomyces cerevisiae to ferment sucrose to ethanol.
Other substrates that can be fermented to produce ethanol are the
simple sugars from diary by-products and plants. Hydrolysed starch
from rice, maize, wheat, potato and cassava can serve as simple sugar
substrate sources for fermentation to produce ethanol. Substrates can
also be derived from lignocellulosic materials of plants.
In maize processing, milling processing are used to separate starch
from corn. The separated starch undergoes gelatinization, then
saccharification, whereby heat-resistant amylases such as
glucoamylases were used to convert starch to simple fermentable
sugars such as glucose. S. cerevisiae ferments the sugars at pH of 4.5-
5.0 and temperature of 32-38 ˚C.
The Gram-negative bacterial species that belong to the genus
Zymomonas like Zymomonas mobilis are alternative microorganisms
that can be used to ferment simple sugars such as sucrose, fructose
and glucose to produce ethanol. They generate higher ethanol yield
than S. cerevisiae but they are less tolerant to ethanol.
Downstream processing
The downstream processing after fermentation involves 5 key steps:
Release of intracellular products (if needed)
Solid-liquid separation
Concentration of the separated liquid
Chromatographic purification
Formulation
Release of intracellular products (if needed)

Some products such as enzymes and vitamins are located within the
cells. They are intracellular products that must be released out of the
cells into the solution before they are isolated.
To release these products, the microbial cells or other cells must be
disrupted or disintegrated by chemical, physical or enzymatic
methods.
The suitable method to be used for the cell disruption depends on
the nature of the cells because each of the methods has its merits
and demerits.
Solid-liquid separation

The step involves the separation of the solid, insoluble substances
and ingredients, including the cell biomass from the liquid culture
broth.
The several methods employs in this process include;
1. Filtration
2. Centrifugation
3. Flocculation
4. Flotation
 Concentration
The desired products are minor constituents of the filtrate. Usually, over 80%
of the filtrate is water, therefore, the water must be removed to get the
desired products in concentrated form.
The methods of concentration that are used in the process are:
1. Membrane filtration
2. Liquid-liquid extraction
3. Adsorption
4. Precipitation
5. Evaporation

The factors that determine the adequate method to be selected for the
concentration process are the qualitative and the quantitative nature of the
desired products, and the cost of the method.
Chromatographic separation
Formulation

Formulation basically means the maintenance of the activity, efficacy
and stability of the products during distribution and storage.
For instance, the formulation of citric acids and antibiotics can be
achieved by crystallization using salt.
Proteins are formulated by adding stabilizers such as sucrose, lactose,
glycerol, and sodium chloride etc.
Proteins can be formulated in form of solution or powder.
Thank you for
listening