Bio-surfactants (BS), which are created by microorganisms, have a wide range of structural and functional variations, which makes it necessary to research them using a variety of approaches. In order to better understand the numerous surface-active product extraction methods, microbiological screening procedures, and analytical terminologies used in this industry, this review aims to compile knowledge on these topics. There is also discussion of the advantages and disadvantages of various methods for analysing microbial culture broth or cell biomass for the production of surface-active compounds.

Additionally, the most well-liked methods for BS purification, structural characterisation, and detection are introduced. Solvent extraction, ultrafiltration, ion exchange, dialysis, lyophilization, isoelectric focusing (IEF), and thin layer chromatography are only a few of the simple methods that are covered in depth (TLC). Protein digestion and amino acid sequencing are also described along with other more complex techniques such as nuclear magnetic resonance (NMR), fast atom bombardment mass spectroscopy (FAB-MS), gas chromatography-mass spectroscopy (GC-MS), high-pressure liquid chromatography (HPLC), and infrared (IR) (FAB-MS).

Properties

Thermal Stability and ionic strength:Several biosurfactants can be used at high temperatures and pH ranges between 2 and 12. Temperature, pH, and Ionic Strength Tolerance Biosurfactants may withstand salt concentrations of up to 10%, unlike synthetic surfactants that need to be inactivated by 2% NaCl.
Interfacial activity and Surface Tension: It is essential for a surfactant to be both effective and efficient. Efficiency is measured by the CMC, whereas effectiveness is related to surface and interfacial tensions. The CMC of biosurfactants ranges from 1 to 2000 mg/L, whereas the surface tension (oil/water) and interfacial (oil/water) tensions are around 1 and 30 mN/m, respectively. A good surfactant may reduce the surface tension of water from 72 to 35 mN/m and the interfacial tension of n-hexadecane from 40 to 1 mN/m.

Specificity, biocompatibility, and digestibility: Because biosurfactants are complex compounds with distinctive functional groups, they typically behave in a specific way. The detoxification of various pollutants, the de-emulsification of industrial emulsions, and specific food, medicinal, and cosmetic purposes are of particular interest in this. Because of their biocompatibility and digestible properties, biomolecules can be used in a variety of industries, but they are especially useful in the food, pharmaceutical, and cosmetic industries.
Biosurfactants are suitable for bioremediation and waste treatment because microorganisms in soil and water can quickly break them down.

Low Toxicity: Biosurfactants can be employed in foods, cosmetics, and medications due to their low level of toxicity. Applications in the environment also require low toxicity. Biosurfactants can be produced from a number of readily accessible source materials, including industrial waste.
Biofilms are a buildup of bacteria or other organic materials that have colonised or collected on a surface.

Biofilms are resistant to several anti-adhesive agents.Bacterial adherence to a surface is the first step in the formation of a biofilm.
This process is influenced by a wide range of variables, including the kind of microorganism, the hydrophobicity and electrical charges of the surface, the atmospheric conditions, and the capacity of the microorganisms to produce extracellular polymers that facilitate cell attachment to surfaces.

The hydrophobicity of a surface can be altered by the use of biosurfactants, which in turn affects how effectively bacteria stick to it. A surfactant from Streptococcus thermophilus slows down the colonisation of other thermophilic strains of Streptococcus over the steel that induce fouling. A biosurfactant from Pseudomonas fluorescens also inhibited Listeria monocytogenes from sticking to steel surfaces.
Emulsion breaking and framing:
Biosurfactants have emulsifying and de-emulsifying properties. The impermeable liquid droplets that make up an emulsion typically have a diameter greater than 0.1 mm and are dispersed over another liquid. The two most popular types are water-in-oil (w/o) and oil-in-water (o/w) emulsions.

It is commonly accepted that biosurfactants have the potential to be used in the production of commercial goods. The widespread use of these chemicals favours novel inquiries on various technical fronts. Biosurfactants are utilised in a wide range of commercial sectors, from the oil business for the recovery of oils and habitat bioremediation to the medical and pharmaceutical industries, due to their surface-active, antibacterial, anti-adhesive, and anti-biofilm properties. The ability to create metabolites in sufficient numbers for product production and commercialization has only been demonstrated by a small number of species of bacteria that produce biosurfactants of the glycolipid class. Low yields and high production costs continue to be the main obstacles to large-scale manufacturing.

By-products from the agro-industrial sector are used to simplify production, reduce costs, and enhance environmental sustainability. The relevance of increasing productivity and yields brought about by bioengineering techniques, adjustments to fermentation processes, and statistical experiment design has been underlined in research breakthroughs. The financial viability of biosurfactant production can therefore be improved by using low-cost substrates, optimising the environment for the production of different bioproducts, developing new purification techniques, obtaining high-yield strains, and producing refined products for larger niche markets.

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