Industrial fermentation

Composition and origin

Depending on the type of microorganisms and its genetic modifications, a various range of feedstocks can be used. The most commonly used feedstocks are listed.

Lignocellulose and cellulose

Lignocellulose is present in garden and park waste. Cellulose is present in food waste such as fruit and vegetable waste. Via hydrolysis, which is usually performed through enzymatic or thermal treatment, fermentable sugars can be obtained from lignocellulose and cellulose.

Starch

Starch is present in food waste such as potatoes, corn, wheat or cassava. Starch can directly be utilized by amylase-producing microorganisms, particularly filamentous fungi. However, to allow its use in a wider range of fermentations, starch is usually converted into glucose or dextrins by enzymatic hydrolysis.

Oils and Fat

Oils and fats are present in food waste such as gravy, used cooking oil and grease. They can directly be used as fermentation substrate. As they are not water soluble, extensive mixing is required to allow a good contact between the liquid droplets and the fermentation water phase.

Dairy waste

Whey, the liquid by-product of cheese manufacturing, is used as a source of fermentable carbohydrate and nitrogen.

Sugars

Sugar-rich waste streams can be derived from food industry waste, f.e. from the candy industry.

Pre-treatment

Depending on the type of feedstock and its purity, specific pre-treatment technologies are required to provide fermentable substrates to the microorganisms. Generally, this first involves a size reduction step, after which the milled biomass can be processed to separate the desired substrate by f.e. centrifugation, filtration, evaporation or crystallization.

In addition, it should be taken into account that some of the mentioned feedstocks only provide the carbon source (which compose about 50% of the weight of most microorganisms), in that case also other nutrients such as nitrogen, phosphate and potassium need to be added.

Microorganisms

Microorganisms used in industrial fermentations include: bacteria, yeast, fungi or algae. In practice, these are well-known, productive and harmless (GRAS - Generally Regarded As Safe) production organisms, equipped with the new genetic information, that are used to produce the desired products in high yield and efficiency. A major advantage is that these often 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.

Equipment

A typical industrial fermenter consists of an CSTR equipped with:

• an aeration and agitation system: to provide good mixing and availability of oxygen for the cell culture
• a temperature and pH control system: to assure optimal conditions for growth or production
• a foam control system: to avoid excessive foam formation
• sampling ports
• addition ports
• a cleaning and sterilization system: to avoid contamination with other, undesired microorganism

Operating conditions

As it involves living organisms, a fermentation process is typically conducted under mild conditions (pH and temperature). As a result, the energy consumption is relatively low as well as the capital and operating costs. However, fermentation technologies are complex and sensitive requiring careful control of quality and safety of the raw materials, process parameters, contamination, etc.

Industrial fermentations may be carried out as batch, fed-batch, or continuous culture systems. 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.

Depending on the type of microorganisms and its genetic modifications, a various range of products can be synthesized. The most common products are listed and divided over two categories: (1) biomass, (2) bioproducts. In case of the latter, some products require complex genetic modifications.

Biomass

• Single Cell Protein
• Single Cell Oil
• Baker's yeast
• Lactic acid bacteria

Bioproducts

Enzymes

• Proteases
• Lipases
• Amylases
• Cellulases
• Peroxidases

Biopolymers

• Poly-hydroxyalkanoates (PHA)
• Polysaccharides: xanthan gum, dextran

Organic acids

• Acetic acid
• Lactic acid

• Citric acid
• Tartaric acid
• Fumaric acid

Alcohols

• Ethanol
• Butanol
• Glycerol
• Butanediol

Solvents

• Acetone

Pharmaceuticals

• Vitamins: vitamin C, B2, B12 ...
• Antibiotics: aminoglycosides, penicillins, cephalosporins, tetracyclines ...
• Hormones

Biocolorants

• cartenoids
• astaxanthins

Biosurfactants and bioemulsifiers

• glycolipids
• rhamnolipids

Amino-acids

• monosodium glutamate (MSG)
• Lysine
• Tryptophan
• Phenylalanine

The first step in the post-treatment of fermentation broths cultures, also known as downstream processing (DSP), is 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. The choice of purification technology is depending on the characteristics of the desired products.

AmphiStar

AmphiStar has developed a proprietary technology platform for the cost-efficient and ecological production of biosurfactants. We are a founders-led spin-off company established in July 2021 that is the result of 15 years joint development between Ghent University (Inbio.be) and the Bio Base Europe Pilot Plant. We derisk the early development stage for biosurfactant production, guide and support technology transfer to industrial manufacturers and collaborate intensely for further development and improvement of the licensed technology.

Our technology platform is initially based on the fermentative production with the yeast Starmerella bombicola, producing many different biosurfactants at a high volumetric productivity. Our biosurfactants are made from sustainable, renewable feedstocks and waste streams. Microbial fermentation is a clean production technology that is safe for people and the environment. Our biosurfactants are environmentally friendly, palm oil-free, sulfate-free, mild, non-toxic and non-irritant.

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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!

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