Difference between revisions of "Industrial fermentation"
| [checked revision] | [checked revision] |
Lars Krause (talk | contribs) |
(added post treatment, started on product section) |
||
| Line 1: | Line 1: | ||
{{Infobox technology}}<onlyinclude>'''Industrial fermentation''' is a biotechnological process which uses microorganisms (genetically modified or not), in particular bacteria, yeasts, fungi or algae, to make useful products. The cells are real "cell factories" for the industrial conversion of renewable feedstocks to bulk chemicals, fine chemicals, platform chemicals, pharmaceutical ingredients, bio-fuels, bio-plastics ... It is a multidisciplinary technology and includes the integrated application of disciplines such as biochemistry, microbiology, molecular genetics and process technology to develop useful processes and products.</onlyinclude> | {{Infobox technology}} | ||
<onlyinclude>'''Industrial fermentation''' is a biotechnological process which uses microorganisms (genetically modified or not), in particular bacteria, yeasts, fungi or algae, to make useful products. The cells are real "cell factories" for the industrial conversion of renewable feedstocks to bulk chemicals, fine chemicals, platform chemicals, pharmaceutical ingredients, bio-fuels, bio-plastics ... It is a multidisciplinary technology and includes the integrated application of disciplines such as biochemistry, microbiology, molecular genetics and process technology to develop useful processes and products.</onlyinclude> | |||
== Feedstock == | == Feedstock == | ||
| Line 13: | Line 14: | ||
==Process and technologies== | ==Process and technologies== | ||
=== Microorganisms === | |||
In practice, well-known, productive and harmless production organisms are used that, equipped with the new genetic information, will produce the desired products in high yield and efficiency. These are the so-called GRAS organisms (Generally Regarded As Safe) and belong to the genera Bacillus, Aspergillus, Penicillium, Saccharomyces, etc. A major advantage is that these genetically modified microorganisms do their work under controlled conditions in a fermenter or bio-reactor, carefully contained and separated from the outside world (contained environment). They cannot escape from the factory so that ecological problems or concerns regarding the release of genetically modified organisms in the environment are avoided. | |||
=== Fermentation mode === | === Fermentation mode === | ||
| Line 27: | Line 31: | ||
# Mixed acid fermentation. | # Mixed acid fermentation. | ||
==Products== | ==Products== | ||
=== Biomass === | |||
Single cell protein (SCP) | |||
=== Bio-products === | |||
==== Enzymes ==== | |||
==== Biopolymers ==== | |||
==== Bio-colorants ==== | |||
==== Organic acids ==== | |||
'''Lactic acid''' can further be converted into polylactic acid (PLA), a bioplastic. | |||
'''Citric acid''' a feed additive | |||
==== Bio-ethanol ==== | |||
==== Vitamins ==== | |||
Vitamin C | |||
Vitamin-B12 | |||
==== Antibiotics ==== | |||
Amino-acids | |||
Several products possible, examples | Several products possible, examples | ||
| Line 41: | Line 76: | ||
* advanced fuels | * advanced fuels | ||
== Post-treatment == | |||
The first step in the post-treatment of fermentation broths cultures, also known as '''downstream processing (DSP)''', to remove the cells from the medium. This is typically performed by a solid-liquid separation technology, such, as [[centrifugation]] or [[membrane filtration]]. Each fraction can then undergo further processing, depending on whether the product is the biomass itself or an intra- or extracellular product. While intracellular products require cell disruption to release the products, extracellular products are solubilized in the depleted fermentation medium. Cell disruption techniques can be divided into mechanical methods (f.e. [[homogenisation]], [[Sizing|grinding]], [[Ultrasonication|sonication]], [[microwave treatment]], [[steam explosion]]) and non-mechanical methods (f.e. osmotic or temperature shock, [[Enzymatic processes|enzymatic destruction]]). To further purify and concentrate the products several methods can be used including [[chromatography]], [[solvent extraction]], [[Crystallisation and precipitation|crystallization]], [[distillation]], [[drying]] etc. | |||
== Technology providers == | == Technology providers == | ||
Revision as of 10:31, 30 November 2021
| Technology | |
| |
| Technology details | |
| Name: | |
| Category: | |
| Feedstock: | |
| Product: | |
Industrial fermentation is a biotechnological process which uses microorganisms (genetically modified or not), in particular bacteria, yeasts, fungi or algae, to make useful products. The cells are real "cell factories" for the industrial conversion of renewable feedstocks to bulk chemicals, fine chemicals, platform chemicals, pharmaceutical ingredients, bio-fuels, bio-plastics ... It is a multidisciplinary technology and includes the integrated application of disciplines such as biochemistry, microbiology, molecular genetics and process technology to develop useful processes and products.
Feedstock
Origin and composition
First generation feedstocks, such as: corn, wheat, sugarcane, potato, sugar beet, rice and plant oil.
Second generation feedstocks, such as: lignocellulosic biomass or woody crops, agricultural residues or waste.
Third generation feedstocks: gas fermentation
Pre-treatment
Process and technologies
Microorganisms
In practice, well-known, productive and harmless production organisms are used that, equipped with the new genetic information, will produce the desired products in high yield and efficiency. These are the so-called GRAS organisms (Generally Regarded As Safe) and belong to the genera Bacillus, Aspergillus, Penicillium, Saccharomyces, etc. A major advantage is that these genetically modified microorganisms do their work under controlled conditions in a fermenter or bio-reactor, carefully contained and separated from the outside world (contained environment). They cannot escape from the factory so that ecological problems or concerns regarding the release of genetically modified organisms in the environment are avoided.
Fermentation mode
Industrial fermentations may be carried out batchwise, as fed-batch operations, or as continuous cultures. Batch and fed-batch operations are quite common, continuous fermentations being relatively rare [1]
Scale-up of industrial fermentations
Typically, a pure starter culture (or seed), maintained under carefully controlled conditions, is used to inoculate sterile petri dishes or liquid medium in the shake flasks. After sufficient growth, the preculture is used to inoculate the seed fermenter. Because industrial fermentations tend to be large (typically 1–250 m3), the inoculum is built up through several successively larger stages, to 5–10% of the working volume of the production fermenter. However, scale-up of a fermentation process is not straightforward as an increase in fermenter size affects the various process parameters in different ways. Therefore, ample expertise is required to find a compromise between all process parameters.
Types of fermentation[2]
- Alcoholic fermentation
- Lactic acid fermentation
- Propionic acid fermentation
- Butyric acid — butanol Fermentation
- Mixed acid fermentation.
Products
Biomass
Single cell protein (SCP)
Bio-products
Enzymes
Biopolymers
Bio-colorants
Organic acids
Lactic acid can further be converted into polylactic acid (PLA), a bioplastic.
Citric acid a feed additive
Bio-ethanol
Vitamins
Vitamin C
Vitamin-B12
Antibiotics
Amino-acids
Several products possible, examples
- Speciality carbohydrates,
- Industrial enzymes
- surfactants
- organic acids
- solvents
- flavours and fragrances
- biostimulants
- polymers
- protein concentrates
- nutraceuticals
- advanced fuels
Post-treatment
The first step in the post-treatment of fermentation broths cultures, also known as downstream processing (DSP), to remove the cells from the medium. This is typically performed by a solid-liquid separation technology, such, as centrifugation or membrane filtration. Each fraction can then undergo further processing, depending on whether the product is the biomass itself or an intra- or extracellular product. While intracellular products require cell disruption to release the products, extracellular products are solubilized in the depleted fermentation medium. Cell disruption techniques can be divided into mechanical methods (f.e. homogenisation, grinding, sonication, microwave treatment, steam explosion) and non-mechanical methods (f.e. osmotic or temperature shock, enzymatic destruction). To further purify and concentrate the products several methods can be used including chromatography, solvent extraction, crystallization, distillation, drying etc.
Technology providers
Company 1
| General information | |||
| Company: |
| ||
| Country: | |||
| Contact: | |||
| Webpage: | |||
| Technology and process details | |||
| Technology name: | Technology category: | Conversion (Biochemical processes and technologies) | |
| TRL: | Capacity: | kg·h-1 | |
| Aeration: | Agitator: | ||
| Biosafety level: | Controlled parameters: | ||
| Microorganism: | Reactor material: | ||
| Other: | |||
| Feedstock and product details | |||
| Feedstock: | Product: | ||
Bio Base Europe Pilot Plant (BBEPP)
Bio Base Europe Pilot Plant (BBEPP) is a flexible and diversified pilot plant for the development and scale up of new, bio-based and sustainable processes. It is capable of development of new bioprocesses, optimization of existing processes and scale up of a broad variety of bio-based processes up to an industrial level (from 5L to 50m3 scale, depending on the process). It can perform the entire value chain, from the green resources up to the final product. BBEPP intends to close the gap in the innovation chain of the bio-based economy, bridging science and industrial production. It is located in Ghent, Belgium.
The activities of BBEPP can be categorized in:
• Development of bio-based and sustainable processes (TRL 2-4)
• Scale up (TRL 5-6)
• Pilot and demo production to allow market introduction (TRL 7-8)
BBEPP has more than 10 years of experience in optimizing, scaling and transferring your fermentation protocol from the lab to commercial production. We count on an entire team of well-trained and highly motivated fermentation experts both with academic and industrial backgrounds to take your process to the next level!
Open access pilot and demo facility providers
Patents
References
- ↑ Y. Chisti, 2014: Encyclopedia of Food Microbiology (Second Edition). Science Direct, {{{place}}}.
- ↑ , 2021: 5 Main Types of Fermentations 30/08/2021, Last access 30/08/2021. https://www.biologydiscussion.com/organism/metabolism-organism/5-main-types-of-fermentations/50854