Biosurfactants for a Sustainable Future. Группа авторов

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Название Biosurfactants for a Sustainable Future
Автор произведения Группа авторов
Жанр Биология
Серия
Издательство Биология
Год выпуска 0
isbn 9781119671053



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molecules in the vicinity of nonionic surfactant monolayers by using vibrational sum frequency spectroscopy, thus allowing the study of the hydration shell around the head groups. Compounds such as dodecanol, sugar surfactants (n‐decyl‐β‐D‐glucopyranoside and n‐decyl‐β‐D‐maltopyranoside), and polyoxyethylene surfactants (C12E4 and C12E8) were studied. For all the surfactants, it was detected that the water molecules located in proximity to the surfactant hydrocarbon tail phase have both hydrogen atoms free from forming hydrogen bonds. For the two sugar surfactants, the strength of the hydrogen bonds in the hydration shell was found to be similar to those observed for tetrahedrally coordinated water molecules in ice. Despite being itself disordered, the polyoxyethylene head group induces a significant ordering and structuring of water at the surface. The orientation of the C12E5 molecules changes with concentration from lying on the surface with their hydrocarbon tails close to the surface plane (the observed results being consistent with the formation of disk‐like “surface micelles” with a flat orientation of the amphiphiles at low surface concentrations) to a more upright configuration as the surface covering liquid layer is formed [187].

      The formation of surface micelles was discussed in another paper [188] in which surface tension measurements were used to study the adsorption isotherms for sugar surfactants (n‐decyl‐β‐D‐glucopyranoside (Glu), n‐decyl β‐D‐maltopyranoside (Mal), and n‐decyl‐β‐D‐thiomaltopyranoside (S‐Mal)). A gradual change in molecular areas is observed when the surfactant concentration is increased. As the area/molecule is comparatively large, the resulting surface phase cannot be a coherent hydrocarbon film and should include a large portion of unperturbed air–water interface. The formation of surface micelles can account for this observation. A hard‐disk simulation allowed the calculation of the number of molecules per micelle as a function of bulk surfactant concentration for Mal (values in the interval 9–12) and Glu (values in the interval 10–14), the surfactant molecules strongly favoring an orientation in the plane of the surface.

Chemical structures of the acidic and lactonic C18:1 sophorolipids.

      Ashby et al. [180] have obtained other derivatives by fed‐batch fermentation of Candida bombicola on glucose and several fatty acids as palmitic acid (SL‐p), stearic acid (SL‐s), oleic acid (SL‐o), and linoleic acid (SL‐l). The cmc values obtained by these authors are shown in Table 1.2. The exact composition can vary with the type of hydrocarbon substrate used in the sophorolipid production and the production conditions [178], and correspondingly different cmc values have been published. For a pure diacetylated C18:1 LS, Otto et al. [178] have reported a cmc value of 2.8 × 10−5 M (Table 1.2). Higher values have been published by Chen et al. [179] for diacetyl LS, diacetyl AS, and nonacetyl AS.

      where Γ and Γ max are the adsorbed amounts and the maximum adsorption, C is the surfactant concentration, and k is the adsorption coefficient. AS and LS have similar k values (2.2 × 10−6), suggesting that both sophorolipids have similar affinities for the air–water interface. Above cmc, the thickness is around 23 Å while the area/molecule is around 74 Å2. For the less hydrophobic AS, the authors obtained a value of 85 Å2. These results for the adsorbed amount are in good agreement with the values obtained from surface tension data.

      Studies by Manet et al. [192] have shown that the micellar morphology of no acetylated C18:1 AS is a prolate ellipsoid. Depending on experimental conditions (the salts cause an increase of the aggregation number and an elongation of the micellar aggregates), the equatorial radius of the ellipsoid varies between 6.1 and 8.0 Å, the axial core ratio varies between 4.7 and 9.4, and the aggregation number between 24 and 73. The fraction of CH2 groups inserted in the dry core of the micelle is in the interval 0.5–0.7, meaning that the core/shell interface is located far from the sugar head group. However, the equatorial shell thickness is almost constant (12.0 ± 0.5 Å). The shell thickness that best describes the sophorolipid micelles is a variable one from the equatorial value given above to zero, i.e. the hydrophilic shell has a nonhomogeneous distribution of matter containing carboxylic groups, sophorose, salt, water, and part of the aliphatic chain. This is an atypical result since most of surfactant systems are described by a homogeneous shell thickness. The area per sophorolipid between the alkyl chain and the sugar/carboxylate head group has been estimated between 102 and 141 Å2 for the most ionized micelles. For nonacetyl AS, Chen et al. [179] reported a value of 104 ± 8 Å2 for the area at the air−water interface.

      Previously, Cecutti et al. [193] had noticed that the sugar rings represent a major part of the molecular volume for glycolipids and, consequently, they differentiate between the micelle‐solvent interface and the hydrophobic core‐sugar head group interface. The best result for interpreting neutron and X‐ray small‐angle scattering intensity curves for ‐dodecyl maltoside in water (6% w/v, 310 K) is by a short ellipsoid model with an ellipticity of 1.2. The difference between the total short radius of the micelle (24 Å), and the short radius of the apolar hydrophobic core (18 Å) allows enough space for the sugar head groups. Other obtained parameters are the areas per surfactant head at the water‐micelles interface (87 Å2), and at the chain‐head group interface (50 Å2), the aggregation number (82) and the number of water molecules per surfactant molecules (10).