A sustainable cultivation of microalgae using dairy and fish wastes for enhanced biomass and bio-product production

Vidya, D.; Nayana, K.; Sreelakshmi, M.; Keerthi, K. V.; Mohan, Kiran; Sudhakar, M.; Arunkumar, K.

doi:10.1007/s13399-021-01817-y

Cited by 25 publications

(10 citation statements)

References 43 publications

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“…Microalgae, including Chlorella sp., H. pluvialis , and C. saipanensis , grew well in fish waste and accumulated intracellular nonpolar storage lipids and pigments . The various methods of both biomass harvesting and lipid extraction for biofuel production from microalgae have been discussed . There has been a growing focus on biodiesel production from various recalcitrant wastes for the cultivation of oleaginous yeasts.…”

Section: Green Extractions Of Ingredients From Seafood Side Streamsmentioning

confidence: 99%

“…128 The various methods of both biomass harvesting and lipid extraction for biofuel production from microalgae have been discussed. 129 There has been a growing focus on biodiesel production from various recalcitrant wastes for the cultivation of oleaginous yeasts. The metabolic pathways that facilitate the conversion of recalcitrant waste into single-cell oil (SCO) have been pointed out.…”

Section: Carotenoidsmentioning

confidence: 99%

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Green Chemistry to Valorize Seafood Side Streams: An Ecofriendly Roadmap toward Sustainability

Venugopal,

Sasidharan,

Rustad

2023

J. Agric. Food Chem.

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A major challenge facing sustainable seafood production is the voluminous amounts of nutrient-rich seafood side streams consisting of by-catch, processing discards, and process effluents. There is a lack of a comprehensive model for optimal valorization of the side streams. Upcoming green chemistry-based processing has the potential to recover diverse valuable compounds from seafood side streams in an ecofriendly manner. Microbial and enzymatic bioconversions form major green processes capable of releasing biomolecules from seafood matrices under mild conditions. Novel green solvents, because of their low toxicity and recyclable nature, can extract bioactive compounds. Nonthermal technologies such as ultrasound, supercritical fluid, and membrane filtration can complement green extractions. The extracted proteins, peptides, polyunsaturated fatty acids, chitin, chitosan, and others function as nutraceuticals, food supplements, additives, etc. Green processing can address environmental, economic, and technological challenges of valorization of seafood side streams, thereby supporting sustainable seafood production. Green processing can also encourage bioenergy production. Multiple green processes, integrated in a marine biorefinery, can optimize valorization on a zero-waste trade-off, for a circular blue economy. A green chemistry-based valorization framework has the potential to meet the Sustainable Development Goals (SDGs) of the United Nations.

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Section: Green Extractions Of Ingredients From Seafood Side Streamsmentioning

confidence: 99%

Section: Carotenoidsmentioning

confidence: 99%

Green Chemistry to Valorize Seafood Side Streams: An Ecofriendly Roadmap toward Sustainability

Venugopal,

Sasidharan,

Rustad

2023

J. Agric. Food Chem.

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“…There are several examples of cultivation of microalgae from fish-side streams. Venugopal and Sashidharan [43] discussed microalgae cultivation from fish by-catch and side streams as a future protein source, while Vidya et al [44] combined processing side streams from dairy and fish as substrates for microalgae with the production of lipids and high-value pigments and Tropea et al [45] combined fermented fish side streams with lemon peel for production of aquafeed. These are just a few examples and researchers claim that we only see the start of the full potential of using fermentation for new food ingredients [46].…”

Section: Fermentation For Upcyclingmentioning

confidence: 99%

Biotechnology for Increased Resource Utilization of Fish Side-Streams

2023

Nutr Res Food Sci J

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“…Melo et al (2018) and Silva et al (2017) showed that microalgae growth can be enhanced by utilizing free or inexpensive carbon organic substrates in mixotrophic or heterotrophic conditions. The use of wastewater in microalgae cultivation has gained considerable attention because it salvages unused nutrients, reduces freshwater demand, and avoids or reduces wastewater treatment costs, making it a green production system with simultaneous production of biomass or other value-added products (Zanette et al, 2019;Vidya et al, 2021). Agro-industrial by-products or wastewater can be used as a sustainable source to improve cell productivity and reduce production costs and pollutants discharged in the environment (Melo et al, 2018;Markou, Wang, Ye, & Unc, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…For example, dairy wastewater has been used as an energy and carbon source under mixotrophic conditions for the growth of some microalgae species, such as Chlorella vulgaris, Chlorella protothecoides, Chlorella sp., Chlamydomonas polypyrenoideum, Chroococcus sp., Coelastrella saipanensis, Haematococcus pluvialis, Scenedesmus obliquus, Dunaliella sp., and Arthrospira platensis (Abreu, Fernandes, Vicente, Teixeira & Dragone, 2012;Kothari, Prasad, Kumar, & Singh, 2013;Girard et al, 2014;Vieira Salla et al 2016;Melo et al, 2018;Patel, Joun, Hong, & Sim, 2019;Vidya et al, 2021). Other microalgae species are obligate phototrophs owing to the lack of efficient sugar uptake mechanism or an incomplete tricarboxylic acid cycle for efficient absorption of organic carbon sources (Chen & Chen, 2006).…”

Section: Introductionmentioning

confidence: 99%

Microalgal production under mixotrophic conditions using cheese whey as substrate

Andrade

Silva

Melo

et al. 2022

Acta Sci. Biol. Sci.

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Microalgae are known for producing various biotechnological products. Moreover, they absorb nutrients from dairy wastewater, grow well, and accumulate valuable compounds faster. In this study, photoautotrophic and mixotrophic cultivation with different initial lactose concentrations present in cheese whey (CW) were established to investigate their effect on cell concentration (Xm, mg L-1), cell productivity (Px, mg L-1day-1), and specific cell growth (µmax, day-1) of Chlorella vulgaris, Dunaliella tertiolecta, and Tetradesmus obliquus. The biomass production of C. vulgaris (Xm= 1,520 ± 30.3 mg L-1, Px = 147 ± 3.00 mg L-1, and µmax = 0.150 ± 0.00 mg L-1) in mixotrophic culture with 10.0 g L-1 of lactose, the main constituent of CW, was notably enhanced by 55% in comparison with their photoautotrophic cultures, whereas a lower effect of these lactose concentrations on cell growth was observed in T. obliquus and D. tertiolecta. Thus, mixotrophic cultivation of C. vulgaris using CW as a carbon and energy source could be considered a feasible alternative to obtain high value-added biomass.

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A sustainable cultivation of microalgae using dairy and fish wastes for enhanced biomass and bio-product production

Cited by 25 publications

References 43 publications

Green Chemistry to Valorize Seafood Side Streams: An Ecofriendly Roadmap toward Sustainability

Green Chemistry to Valorize Seafood Side Streams: An Ecofriendly Roadmap toward Sustainability

Biotechnology for Increased Resource Utilization of Fish Side-Streams

Microalgal production under mixotrophic conditions using cheese whey as substrate

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