Biosurfactants for a Sustainable Future. Группа авторов

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Biosurfactants for a Sustainable Future - Группа авторов


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      Source: Peresypkin and Menger [153].

      Dynamic light scattering experiments suggest that only the C8–C8 derivative originates micelles exclusively, while others (for example, C8–C12, C12–C8, C14–C8, C10–C14, and C10–C16) self‐assemble in structures such as tubules or vesicles of different sizes, forming also coacervate droplets (C8–C10).

      Although phospholipids or bile acids are of a biological origin, the term “biosurfactant” concerns those amphiphilic derivatives that are produced by microorganisms. In general, they have excellent surface‐active properties.

      Different classifications have been purposed for biosurfactants [154–156]. For instance, Otzen indicates that, based on their overall structure, biosurfactants fall into four classes: glycolipids, lipopeptides, saponins, and all the rest. Glycolipids can be subdivided into rhamnolipids, sophorolipids, trehalolipids …, in which the head group are different saccharides (rhamnose, sophorose, trehalose, …). Similarly, lipopeptides can be divided into several families as surfactin, iturin or fengycin [157, 158], some of them having a peptide‐cycle structure. Gemini type biosurfactants are also common [159]. The hydrophobic part is commonly one or more unsaturated or saturated hydrocarbon chains. The saponin Aescin or glycyrrhic acid are examples of biosurfactant complex structures [159, 160].

      Previous naturally found biosurfactants and similar derivatives will all together show a broad range of physicochemical properties. Let us analyze some significant examples.

Chemical structure of viscosin.

      Source: Saini et al. [164]. Reproduced by permission of the American Chemical Society.

      General rules observed in classical surfactants are also observed for biosurfactants. Figure 1.5 shows a linear relationship between the aggregation number and the alkyl chain volume in classical surfactants. This is just an example of linear relationships for different properties in a series of homologous surfactants. For instance, Garofalakis et al. [161] have observed a reduction in the critical aggregation concentration (cac) of the surfactants when increasing the carbon chain length for a series of monoesters of xylose, galactose, sucrose, and lactose with different hydrophobic chain lengths (C12–C16). These authors also observed that the more hydrophilic head groups, the higher is cac, though this trend was moderated by the alkyl chain length. Some observed differences between maltose and glucose derivatives have been ascribed to a higher degree of hydration of maltose compared to that of the glucose head group as molar heat capacities for these two sugars suggest [167]. Another example corresponds to the standard free energy change. For n c‐alkyl‐D‐maltosides (n c , number of carbon atoms of the alkyl chain, = 8, 10, 12, and 14), Varga et al. [168] have shown that the dependence of the standard free energy change (and from here the cmc as well) with the length of the alkyl chain for these sugar surfactants is parallel to the one for alkyltrimethylammonium bromides and sodium alkylsulfates.

Chemical structure of biosurfactants monorhamnose and dirhamnose rhamnolipids (R1 -left- and R2 right).
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