Polysaccharides. Группа авторов

Polysaccharides - Группа авторов


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      6.2.5 Biofuels

      As carbon-neutral and sustainable, biofuels (i.e., ethanol, biodiesel, and bio-jet fuel) are produced through contemporary biological processes, rather than geological processes [190, 191]. Because of the need for increased energy security, increased petroleum price, and negative impacts of fossil fuels on the environment, biofuels have been gaining increased public and scientific attention [191].

      Biofuels are classified into first, second and third-generation biofuels depending on the carbon source of feedstock. The first-generation feedstock is based on the starch obtained from wheat, corn, barley, etc. The second-generation feedstock includes biomass rich in lignin and cellulose such as rice wheat straw, straw, and sugarcane bagasse. Finally, the third-generation feedstock comprises polysaccharides, such as starch, laminarin, and floridean starch [190]. In the extracellular cell wall of plant cells, cellulose is generally embedded in a lignin matrix. This structure is called lignocellulose and it constitutes the essential part of the woody cell walls of plants. In addition to their other biological functions, such as providing resistance against the penetration of microorganisms or degrading enzymes, cellulose and lignin together provide the plant structure. Cellulose can be fermented by many microorganisms to produce biofuels, such as bioethanol. Lignin is a large 3D polymer of phenylpropanoid molecules and it is an abundant source of high energy because of having a high C/O ratio [192, 193]. Lignocellulose is not a part of the human diet as a food since it cannot be readily digested by the microorganisms reside in the human gut, so lignocellulose has been proposed to be used as a renewable source because of its availability and structural characteristics. However, it has been noticed that the production of lower-cost cellulosic biofuels was challenging because lignocellulosic residues are a complex of carbohydrates and polyphenol polymers usually associated with proteins. Consequently, the necessity of the use of several steps including pre-treatments and enzymatic digestions to extract fermentable carbohydrates from this complex network increases the cost of ethanol production drastically [193, 194].

      6.2.6 Wastewater Treatment

      Over the last years, the use of biocompatible and biodegradable renewable resources for the retaining of different pollutants from wastewaters has attracted the attention of many researchers [200]. Biosorbent abilities of natural polysaccharide matrices have been under investigation for an efficient and low-cost wastewater treatment.

      The use of polysaccharide-based materials as sorbents offers several advantages including low cost, versatility, abundance, high capacity and high rate of adsorption, and ease of modification. However, there are also limitations of using polysaccharides in wastewater treatment. For instance, the choice of the adsorbent depends on the nature of the pollutant, thus the extreme variability of industrial wastewater must be taken into account in the design of any polysaccharide-based platform [204]. Still, polysaccharide-based materials one of the most attractive biosorbents for wastewater treatment. Considerable efforts are now being made in the investigation and development of polysaccharides and their derivatives as the natural materials for the removal of pollutants with different structures.

      6.2.7 Textiles

      The natural fibers obtained from wood, hemp, cotton, jute, and flax contain a high amount of cellulose (more than 85%) and serve as raw materials for the paper and textile industries [207]. Cellulose accounts for more than half of all the carbon found in the vegetable kingdom; thus, it is the most abundant of all carbohydrates. About 95% of cotton fibrils is cellulose. In the field of textile production, although the use of noncellulose synthetic fibers has been increasing, cotton and rayon still account for more than 70% of the fabrication [208].

      Cotton (Gossypium sp.) fiber has been widely studied as the major natural fiber used in the textile industry. The fiber primary cell wall is mainly composed of cellulose, hemicelluloses, and pectins. Several of the non-cellulosic polysaccharides, such as xylan, xyloglucan and callose, appeared to be partially retained during textile processing, though they were still largely impacted by both bleaching/scouring and mercerization processes. These hemicelluloses can resist harsh treatments, possibly because they reside within the fiber structure during the textile processing treatments. Such investigations would be of the greatest value since the determination of the fates of non-cellulosic polysaccharides during the textile processing offers useful information for future functionalization studies of cotton by specifically targeting these non-cellulosic polysaccharides and for optimization of cotton treatments [209].


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