2022
DOI: 10.1039/d1se01740c
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Algal biorefinery: a potential solution to the food–energy–water–environment nexus

Abstract: Despite the great potential in wastewater treatment, CO2 bio-fixation, food, and bioenergy production, microalgae are not economically viable on a large commercial scale and, as a unifying solution to all...

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Cited by 13 publications
(4 citation statements)
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“…19 Some of the commonly cultivated commercial microalgae composition in comparison with plant and animal products are given in Table 2. 20 Algal cell wall comprised of cellulose, pectin, and sulfated polysaccharides, starch in plastids (20-50%), lipids, and proteins. The composition of these components depends on the species types and culture media used to produce them and growth conditions.…”
Section: Biological Methods Of Sequestering Comentioning
confidence: 99%
“…19 Some of the commonly cultivated commercial microalgae composition in comparison with plant and animal products are given in Table 2. 20 Algal cell wall comprised of cellulose, pectin, and sulfated polysaccharides, starch in plastids (20-50%), lipids, and proteins. The composition of these components depends on the species types and culture media used to produce them and growth conditions.…”
Section: Biological Methods Of Sequestering Comentioning
confidence: 99%
“…The rigid cell wall of Haematococcus lacustris (~2.2 µm) is made up of algaenan, biopolymers and thick polysaccharides [ 96 , 97 ]. Since, cell disruption in downstream processes such as pulse electric field current, microwaves, sonication, enzyme treatment, chemical solvents, high pressure homogenizers and bead millers, are expensive at large scale, they tend to increase the cost of extraction of astaxanthin [ 98 , 99 ] ( Figure 6 I). However, if among these, an economically viable technique is optimized that can lead to harvesting of astaxanthin from the cells, astaxanthin can become an important ingredient in all affordable diets and supplements [ 100 , 101 ].…”
Section: Astaxanthin Harvesting and Its Bioavailabilitymentioning
confidence: 99%
“…CCU should contribute even to negative net emissions [49]. CCU with the use of microalgae is a biological process in which CO 2 is assimilated in the photosynthesis process [50], and the produced biomass replaces non-renewable resources in the production of chemicals, fuels, plastics, building materials, dyes, dietary supplements, cosmetics, pharmaceuticals, feed, and fertilizers [51]. An example is their use in the production of cement [52] or biochar, which, when introduced into the soil, allows for long-term storage of CO 2 and promotes sustainable agriculture [53].…”
Section: Changes In Microalgal Biomass Concentration and Characteristicsmentioning
confidence: 99%