These factors are also believed to

These factors are also believed to influence the biofunctional activity of laminarin (Rioux et al., 2010). The structural features of laminarin vary with algal species, for example, with respect to the M:G ratio (in some cases M chains are absent), to the degree of branching and polymerisation (maximum of up to fifty carbohydrate residues, usually approximately twenty-five) and to the ratio of β-(1,3) and β-(1,6)-glycosidic bonds. Laminarins extracted from different sources have been shown to have structures quite distinct from that originally suggested for the commercially available preparations from Laminaria sp. (Chizhov et al., 1998). For example, laminarin, extracted from Sargassumfusiforme, is composed of 1,3:1,6-β-D–glucans. Jin et al. (2014) carried out structural analysis of lamanarin and observed that the laminarin obtained fromS. fusiforme is composed of nonreducing terminal glucopyranose (15.3%), 3-linked β-D-glucopyranose (66.4%), 6-linked β-D-glucopyranose (4.1%) and 3,6-linked β-D-glucopyranose (14.2%) with β-D-glucose at terminal ends. The content of laminarin from brown algae varies with species, season, habitat and method of extraction; it also can vary up to 35% of dry weight (Kraan, 2012). Lamanarin content of some commonly used macroalgae is outlined in Table 1. Laminarin is absent during the period of fast growth in spring, but in autumn and winter, it may represent up to 35% of the dried weight of the fronds (Rinaudo, 2007). This variation presents particular challenges to seaweed processors in the production of consistent seaweed products.