Polysaccharides. Группа авторов

Polysaccharides - Группа авторов


Скачать книгу
by which the integrated water is simply removed by applying high pressure. In Japan it was used mainly in extraction of semi-refined agar from Gracilaria. Stone blocks were used to press the gel packs of agar, removing water. Afterwards, it is pressed with miniature hydraulic presses to remove the remaining water. In 1964, Prona from France, developed modern syneresis technique of concentrating the extracted agar gel from all type of agarophytes. Later this company expanded its industry to Mexico, Chile, South Africa, and also modernised the plants in Spain, Morocco and Portugal. This improved company’s global headship in agar production. Prona only joint their business with INA of Japan and Algas Marinas of Chile.

      In syneresis method, the purity of agar is way better than freezing method. It is 20% higher than the freezing–drying method which was 11%. Which means agar, produced by freezing method, has more impurities like water and other soluble impurities, than the syneresis method.

      Treatment: alkaline solution is used to extract polysaccharide from the cell wall of seaweed. For example: for Gracilaria any stronger base is required to extract agar from its cell wall. Strong base helps in alkaline hydrolysis of the sulfates resulting stronger agar gel strength.

      Extraction: Extracted agar is later dissolved into boiling water above atmospheric pressure and on a high pH to obtain a high yield.

      Filtration: Most standard filtration techniques can be used in this step.

Schematic illustration of the chemical structure of agarobiose (the fundamental repeating unit of agar).

      Figure 5.1 Chemical structure of agarobiose (the fundamental repeating unit of agar). Source: Europian Food Cunsumption Database.

      Modern alkaline treatment method helps in increasing the anhydrous bridges within molecule, thus increasing gel strength. Methoxy levels in agar determine the gel setting temperature. The level of methoxy content in gel is directly proportion to its strength. Thus higher level of methoxy in agar leads to the higher gel setting temperature and vice versa.

      The classical ‘freeze–thaw’ example of fractionating the agar is the oldest known fractionation method of agar. The gelling counterparts of polysaccharides (agarose) were broken up from their non gelling counterparts (agaropectin), purely by freezing, thawing and then pressing the agar gel. In 1979 Usov [14] and his team recognised this non-gelling counterpart as agaropectin. In old times, to exhibit the heterogeneity of agar and separate agarose (Polysaccharide fraction with highest gelling capacity) from agaropectin (the charged polysaccharide counterpart of poor or non-gelling quality), the differential solubility of agar polysaccharide was used. In 1946 Yanagawa [15] extracted polysaccharide fractions with sulfate content by mixing agar of G. amansii at 3, 50–55 and at 75–80 °C in water. As well as he acquired different yields of agar from Gloiopeltis, Gracilaria, Ceramium, Gelidium and Acanthopeltis species of agarophytes, simply by boiling them at 70, 60, 50% of alcohol. In 1970 Guiseley [16] developed a method to precipitate polysaccharides. Since methylated agar polysaccharide is soluble in hot ethanol, in 1970 Guiseley used this property of agar to precipitate polysaccharide. In 1986 Lahaye developed a procedure to extract agar. In this method water is added to the different boiling ethanol-water solutions at different temperatures to get a sequential solvent of agar. Izumi [17] and Yaphe’s group studied the differences in charges densities of agar polysaccharide by using anion exchange chromatographic techniques.

      The ability to gel and solubilize for agar polysaccharides solely depends upon the comparative hydrophobicity of structural repeating units of agarobiose. Gelling property of agar also alters when the 1,4-linked 3,6-anhydro-α-L-galactopyranoses gets substituted with hydrophobic groups like methoxyl and polar groups like sulfates and pyruvates.


Скачать книгу