The Chronological Development of the Fermentation Industry PDF

Summary

This document details the chronological development of the fermentation industry. It covers key stages, from traditional practices to modern biotechnology. The document also touches on advancements in fermentation processes, including the growing of microorganisms, product extraction, and purification.

Full Transcript

The Chronological Development of
the Fermentation Industry.
Stage 1: Prior to 1900
Primary Products: Potable alcohol (beer, wine, spirits) and vinegar.
Beer Brewing:
Emergence of large-scale breweries in the early 1700s.
Use of wooden vats and process control innovations such as thermometers and
heat exchangers.
Mid-1800s: The role of yeasts in fermentation was demonstrated by scientists like
Cagniard-Latour, Schwann, Kutzing, and Pasteur convinced the scientific world.
Hansen's development of pure yeast cultures using single-cell isolation techniques
at Carlsberg brewery.
Britishers still use mixed culture fermentation for ale.
Vinegar Production:
Initial production by natural flora in shallow bowls or barrels.
The introduction of the "generator," an early aerobic fermenter, improved
efficiency by trickling wine or beer over inert materials like charcoal, wood
shavings etc.
During 1800s to early 1900s, 10% old vinegar was added to pasteurized medium
as process control.
Stage 2: 1900-1940
New Products: Yeast biomass, glycerol, citric acid, lactic
acid, acetone, and butanol.
Bakers’ Yeast Production:
Recognition of the importance of oxygen in aerobic processes.
Development of fed-batch culture to avoid oxygen limitation.
Improvement in aeration in the yeast growing medium with
steam-cleaned sparging tubes.
Acetone-Butanol Fermentation:
Developed by Weizmann during WWI, it required aseptic operation
standards.
Influenced later aseptic aerobic processes and use fermenters
made of vertical cylinders with hemispherical tops and bottoms
constructed from mild steel. They could be steam sterilized under
pressure and were constructed to minimize the possibility of
contamination.
Solvent fermentations were later defeated by petrochemical
feedstock processes.
Stage 3: 1940s Onward
Penicillin Production:
Driven by WWII needs, submerged culture techniques were developed for
it being an aerobic fermentation process it was highly prone to
contamination.
Challenges included sparging with sterile air and mixing viscous broths.
Strain-improvement programs and pilot-plant facilities became crucial.
Expansion of Antibiotics and Other Products:
Screening for microbial products became sophisticated, leading to the
production of other antibiotics, vitamins, gibberellin, amino acids,
enzymes, and steroid transformations.
Bioethanol Initiatives:
Started in the mid-1970s by Brazil and the USA to reduce petroleum
dependency.
Carbohydrates converted by fermentation to ethanol by microbes.
The United States of America produced 56 billion liters of bioethanol in
2015
Ongoing efforts to improve processes using cellulose and lignin
feedstocks.
Stage 4: 1960s-1980s
Microbial Biomass Production:
Investigated as a protein source for animal feed.
Cheaper protein source.
Exploration of continuous culture techniques.
The pressure jet and pressure cycle fermenters that eliminated the
need for mechanical stirring were developed.
Development of large fermenters (ICI process), up to 3,000,000 dm³
for culture of Methylophilus methylotrophus with methanol as carbon
source
Economic Challenges:
The ICI Pruteen process was technologically advanced but failed
economically due to competition from cheaper protein sources like
soybean and fishmeal.
Stage 5: 1980s Onward
Establishment of very high-value, low-volume products; a stage often referred as “new biotechnology.”

Recombinant DNA Technology:
Enabled the production of human and mammalian proteins in microorganisms and cultured animal
cells, to be used as therapeutics.
Classified products as biopharmaceuticals like vaccines, requiring precise production processes.
Therapeutic Proteins:
The first approved recombinant protein was human insulin in 1982.
Approvals followed for human growth hormone, interferons, monoclonal antibodies, recombinant
vaccines-hepatitis B, tissue plasminogen activator, and erythropoietin.
Monoclonal Antibodies:
Initially used for analytical purposes, now established as therapeutic agents
produced by both mammalian and microbial cell cultures.
Industry Expansion:
New microbial products started reaching the marketplace in the late 1980s and early 1990s through
conventional process development.
During 1980s, four sec.metabolites launched-cyclosporine (immunoregulant) imipenem (a wide
spectrum antibiotic) lovastatin, and ivermectin, an antiparasitic drug used to prevent “African River
Blindness” as well as in veterinary practice.
By 2012, around 220 biopharmaceuticals were approved.
Significant contributions from E. coli(31%), yeast(15%), mammalian cell cultures(43%) and 11%
other cells. One of the 2012 recombinant products was Elelyso-Gauchers disease.
2005–12 period were dominated by antibody-based products and engineered proteins.
Stage 6: Synthetic Biology
Advancements in Genomics, Proteomics and Metabolic flux:
The sequencing complete genomes, development of computerized systems
to store and access the data has enabled the comparison of genomes and
the visualization of gene expression in terms of both mRNA and protein
profiles, the transcriptome and proteome respectively.
Metabolic flux analysis examines the flux of intermediates through
pathways and enables the construction of mathematical models.
Led to a holistic view of organisms, enabling synthetic biology to optimize
fermentation processes.
E.g. Corynebacterium glutamicum-lysine overproduction, synthetic strain
E.coli – 1,4-butanediol.
Systems Biology:
Combines molecular biology, biochemistry, and physiology to manipulate
entire organism functions.
Goal-maximize the yield of the desired product while minimizing that of
unwanted metabolites
Economic Competitiveness:
Synthetic biology aims to make fermentation processes competitive with
petrochemical processes for bulk chemical production.
 Key Components of a Fermentation Process

1.Media Formulation: Developing suitable media for culturing
the process organism.
2.Sterilization: Ensuring sterility of media, fermenters, and
ancillary equipment.
3.Inoculum Production: Producing an active, pure culture for
inoculation.
4.Fermentation: Growing the organism under optimal
conditions for product formation.
5.Product Extraction and Purification: Efficiently extracting
and purifying the product.
6.Effluent Disposal: Managing waste produced by the process.
Schematic representation of
fermentation process
 Research and Development

Continuous Improvement: Ongoing efforts to improve the
process organism, culture medium, and extraction methods.
Isolation and Modification: Isolating and modifying producer
organisms to enhance productivity.
Cultural Requirements: Determining the cultural requirements
of organisms for optimal growth and product formation.
Production Plant Design: Designing production plants to meet
the specific needs of the fermentation process.