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in cosmetics and foods (e.g. bakery products and confectionery) to improve texture and moisture and prevent sugar crystallization. It is also used in pharmaceutical/biomedicine applications and formerly was applied for drug delivery and blood plasma polymer expander [7,103]. The potential of dextran‐based polymers is being evaluated to form nanofibers for controlled drug release [104], as anticancer therapeutics [105,106], and as hydrogels for wound healing [107]. Dextran is commercialized by some companies, such as Oregon Green and ATTO‐TEC.
2.3.5 Curdlan
Curdlan is a glucan produced by Alcaligenes, Rhizobium, and Bacillus species. It is alkaline‐soluble and water‐insoluble gel‐forming polymer, which limits its industrial applications [108,110]. Hence, curdlan has traditionally been used as a stabilizer, texturizer, and thickener in the food industry [111,112].
Further, some studies showed interest in converting curdlan into more soluble oligosaccharides, exhibiting notable biomedical functions (e.g. antitumor and immunological activities) [113,114]. Besides, the oligosaccharides may also have an efficient role in the improvement for sustainable agriculture since it can efficiently activate the plant innate immune defense system [115]. Research on curdlan and its derivatives are being performed to develop environmentally friendly alternatives to oil‐based plastics [111].
2.3.6 Gellan Gum
Industrially, gellan gum is produced by the bacterium Sphingomonas paucimobilis ATCC 31461 [116]. It is a heteropolysaccharide composed of L‐rhamnose, D‐glucose, D‐glucuronic acid, and D‐glucose monomers and side chains of acetyl and glyceryl substituents. Gellan gum have the ability to form gels, whose properties are dependent on the acyl group content: low acyl form produces rigid, nonelastic, brittle, and thermostable gels, while the high acyl gellan produces soft, elastic, non‐brittle, thermoreversible gels [117,118]. Gellan gum is mainly used in the food industry, namely, as a thickener, stabilizer, and binder agent. It is used in desserts and drinking jellies, as well as in low‐calorie (sugar‐free) jams, fruit preparations, yogurt, sauces, nonfat salad dressings, and films [119,120]. Gellan gum is commercialized as Kelcogel, a gelling agent in the food industry, and is marketed by CP Kelco.
Moreover, gellan is described as a multifunctional additive for various pharmaceutical products, especially for controlled release forms, including oral, ophthalmic, nasal, and other formulations [121,122]. It is already used in ophthalmic formulations (e.g. Timoptol). Recent reports suggest that gellan‐based materials can also be used in tissue engineering, regenerative engineering, or gene transfer technology [118,123,124].
2.3.7 Levan
Levan is a homofructan composed of fructose residues and can be secreted by several microorganisms (e.g. Acetobacter sp., Halomonas sp., Zymomonas sp., Lactobacillus sp.) or produced by plants [7,125,126]. Levan does not swell in water, and it has a very low intrinsic viscosity value. It is water and oil soluble, is compatible with salts and surfactants, and has emulsifying capacity, biological activity, and adhesive ability [127,128]. Its functional properties turn it suitable for use in food (e.g. prebiotic agent), cosmetics (e.g. dermal filler), and pharmaceuticals. The levan low viscosity promotes its use in pharmaceuticals to produce capsules or coatings and in several therapeutic applications. Levan nanoparticles have potential to delivery peptides and protein drugs. Further, levan is used in the green synthesis of silver and gold nanoparticles [126,129]. It is produced by Montana Polysaccharides Corp. in the United States.
2.3.8 Hyaluronic Acid
Hyaluronic acid (HA) is a linear polymer composed of repeating disaccharide units of glucuronic acid and N‐acetylglucosamine [130,131]. It is produced by S. zooepidemicus; however the concern about the pathogenicity of Streptococcus has driven the efforts toward transforming generally recognized as safe (GRAS) nonproducers (e.g. Lactococcus lactis, Bacillus subtilis) into HA producers [130]. HA shows a great swelling capacity, biocompatibility, non‐immunogenicity, biodegradability, and viscoelasticity. Its physicochemical and biological properties render HA potential for applications in cosmetics (e.g. dermal filler), pharmaceuticals, and medicine (e.g. osteoarthritis treatment, tissue engineering) [132,134]. Ongoing research on HA and its numerous modifications/blends shows the development of materials with improved properties for drug delivery and tissue engineering technologies [135,136].
2.4 Hydrogels Based on Microbial Polysaccharides
Among various physical structures such as films, fibers, and beads, microbial polysaccharides are biopolymers suitable to fabricate a half liquid‐like and half solid‐like material, known as hydrogel [137,139]. Hydrogel is a 3D crosslinked polymeric network capable of absorbing and retaining large amounts of water, commonly used in a wide range of applications in the most diversified fields [140,141].
Over recent decades, several polysaccharides including alginate, gellan gum, cellulose, dextran, hyaluronic acid, xanthan, and chitin/chitosan, either alone or in blends, all attainable through microbial production, have been used for the design and fabrication of hydrogels.
According to their preparation method and physical structure, hydrogels can be produced by physical or chemical crosslinking (Figure 2.1) [138,141]. Physically crosslinked hydrogels are reversible under specific conditions, and polymer chains are weakly stabilized by secondary forces such as ionic interactions, hydrogen bonding, or hydrophobic interactions. Despite their shape instability due to the reversibility of the formed bonds, physical hydrogels are generally harder than the chemical hydrogels [138]. A well‐known example of hydrogels formed by ionic interaction is the crosslinking of alginate using divalent cations as Ca2+ [143]. On the other hand, chemically crosslinked hydrogels are irreversible and stable, with strong covalent bonds involving reactions of polymeric backbone with a crosslinking agent. Chemical hydrogels can be produced by different techniques such as radiation and graft copolymerization or in the presence of a crosslinking agent. In the case of polysaccharides, the most common technique is the use of a crosslinking agent involving active reaction sites as –OH groups on its backbone [141].
Figure 2.1 Schematic representation of the fabrication of chemically and physically crosslinked hydrogels.
Source: Hoffman 2012 [142]. Reprinted with permission of Elsevier.
Depending on the types of monomers involved, hydrogels can be classified as homopolymer hydrogels, if composed by one single monomer unit; copolymer hydrogels, if constituted by two or more monomeric units, one of which must be hydrophilic; and interpenetrating polymeric network (IPN) hydrogels when two independent crosslinked networks intermesh each other in the presence of crosslinker. Therefore, hydrogels can be semi‐IPN if one of the components is a non‐crosslinked polymer [140].
Additionally, polysaccharide hydrogels can also be categorized on the basis of ionic charges as non‐anionic (neutral), ionic (cationic or anionic), and ampholytic hydrogels. Such classification refers to the overall charge, namely, no charge groups are present in neutral hydrogels, and cationic and anionic hydrogels are characterized by the presence of positively and negatively charged groups, respectively. In the presence of both negatively and positively charged groups, ampholytic hydrogels are produced [141,144]. Ionic and ampholytic hydrogels are also known as polyelectrolytes.
Considering their final application, hydrogels can be designed to be stimulus sensitive, responding distinctively toward the external condition such as temperature, pH, ionic strength, and magnetic or electric field [140,145]. In fact, the ability to respond to external stimuli