Introduction To Fermentation PDF

Summary

This document provides an introduction to fermentation, covering topics like alcoholic and lactic acid fermentation, glycolysis, and anaerobic respiration. It also details the process and applications of fermentation in food production. The document is likely intended for an advanced biology course.

Full Transcript

FERMENTATION
ALCOHOLIC AND LACTIC ACID FERMENTATION

SBT1053
 The Overall Pathway of Glycolysis

Glycolysis is the first stage of glucose metabolism.
Glycolysis is activated when energy is required.
One molecule of glucose is converted to 2 molecules of pyruvate.
It plays a key role in the way organisms extract energy from
nutrients.
The production: 2 ATP and 2 NADH for each glucose.
Once pyruvate is formed, it has one of several fates.
The Reactions of Glycolysis
 Fates of Pyruvate
Under aerobic condition (O2
present):
pyruvates are converted to
acetyl-CoA
(aerobic metabolism)

Under anaerobic condition (No
O2 present):
pyruvates are converted to
lactate or alcohol
(anaerobic metabolism)
Anaerobic Respiration
 If no oxygen is available, cells can obtain energy through the
process of anaerobic respiration.

A common anaerobic process is fermentation.

Fermentation is not an efficient process and results in the formation
of far fewer ATP molecules than aerobic respiration.

There are two primary fermentation processes:

1. Lactic Acid Fermentation
2. Alcohol Fermentation
 LACTIC ACID FERMENTATION
❑ Occurs when oxygen is not available.

❑ For example, in muscle tissues during rapid and vigorous exercise, muscle
cells may be depleted of oxygen. They then switch from respiration to
fermentation.
The pyruvic acid formed during glycolysis each gain a hydrogen
from NADH.

The new hydrogen turn the pyruvate into lactic acid and energy is
released (which is used to form ATP).

Glucose → Pyruvic acid → Lactic acid + energy
 The process of lactic acid fermentation replaces the process of
aerobic respiration so that the cell can have a continual source of
energy, even in the absence of oxygen.

However, this shift is only temporary and cells need oxygen for
sustained activity.
 When you exercise
vigorously, lactic acid builds
up in the tissue causing a
burning, painful sensation.

You must breathe in more
oxygen to replenish the O2 in
your muscles.
 ALCOHOLIC FERMENTATION
Alcohol fermentation occurs in yeasts and
some bacteria. Ex: Saccharomyces cerevisiae

Pyruvic acid formed during glycolysis is
broken down to produce alcohol and carbon
dioxide and is released (which is used to
form ATP).

The yeast is used in fermentation because it
contains enzymes like zymase that can
metabolize the carbohydrate molecules
without oxygen. It results in the production
of ethanol and carbon dioxide molecules.
In fermentation the pyruvate made during glycolysis loses another carbon
making carbon dioxide.

The two sets of carbons left each gain a hydrogen from NADH. This turns the
two carbon chains into ethyl alcohol.

Glucose → Pyruvic acid → alcohol + carbon dioxide + energy
YEAST GROWTH PHASES
During the lag phase, microbes are growing
and adapting to the new environment so the
biomass does not increase significantly.

During the exponential phase, the cells are at
their most active and consume large amounts
of nutrients, hence maximum biomass is
achieved.

The limited amount of nutrients will eventually
lead to nutrient depletion and growth rates
will decrease and become zero.

When the number of dying cells is greater than
the number of cells generated, the biomass
will decrease. This is the death phase.
https://byjus.com/neet/types-of-fermentation/
 Fermentation is used in food production.
– Yogurt - Soy Sauce
– Cheese - Vinegar
– Bread - Olives/Pickles

– Beer/ Meade - Wine/ Ale

– Sauerkraut - Malt
The range
There are fiveof fermentation
major process.important fermentations:
groups of commercially

Those that produce microbial cells (or biomass) as the product.

Those that produce microbial enzymes.

Those that produce microbial metabolites.

Those that produce recombinant products.

Those that modify a compound which is added to the fermentation - the
transformation
FROM SHAKE FLASK TO BIOREACTOR

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Bioreactor
The main vessel where the fermentation process takes
place. It provides a controlled environment for microbial
growth and product formation.

Bioreactor Components:

1. Agitator (Agitation system): Stirring mechanism to
ensure uniform mixing of nutrients, microorganisms,
and gases within the bioreactor.
2. Sparger (Air) : Device for introducing gases, typically
oxygen or air, into the culture medium to maintain
adequate dissolved oxygen levels for microbial
respiration.
3. Sensors (Sensors Probes): Various sensors for
monitoring key parameters such as temperature, pH,
dissolved oxygen concentration, and agitation speed.
4. Sterile Inlet (Feeding Pump): Port for introducing
sterile media, nutrients, and inoculum into the
bioreactor while maintaining sterility.
5. Product Outlet (Effluent): Port for harvesting the A diagram of a stirred-tank biorector
desired product from the bioreactor once fermentation
is complete.
https://byjus.com/biology/bioreactor-obtaining-foreign-gene/
 FLOW OF FERMENTATION PROCESS
(1) The formulation of media to be used in culturing the process organism during the development of the
inoculums and in the production fermenter.

(2) The sterilization of the medium, fermenters and ancillary equipment.

(3) The production of an active, pure culture in sufficient quantity to inoculate the production vessel.

(4) The growth of the organism in the production fermenter under optimum conditions for product
formation.

(5) The extraction of the product and its purification.

(6) The disposal of effluents produced by the process.