Microalga‐ and yeast‐based astaxanthin production via nutrient recovery from wastewater for aquaculture practice: an emerging technology for sustainable development

Lu, Qian; Lu, Yujie

doi:10.1002/jctb.7164

Cited by 10 publications

(13 citation statements)

References 101 publications

(257 reference statements)

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“…Secondly, astaxanthin formation is accompanied with the encystment induced under the high ratio of C/N ( Kakizono et al, 1992 ; Li et al, 2022 ). Traditionally, to grow microalgae for astaxanthin production, low concentration of nitrate, ammonia, or organic nitrogen was added in artificial medium ( Lu and Lu, 2022 ). As shown in Table 3 , however, many FPEs, such as soybean processing effluent and meat processing effluent, contain high concentration of TN.…”

Section: Microalgae-based Nutrient Recovery In Food Processing Effluentmentioning

confidence: 99%

“…In a real-world application, however, high cost of natural astaxanthin production by microalgae cultivation has not been fully addressed. In the market, high sale price (US $2,000–2,500 per kilogram) of natural astaxanthin is hindering the wide application of this valuable bio-product in modern agriculture ( Liu et al, 2013 ; Lu and Lu, 2022 ).…”

Section: Introductionmentioning

confidence: 99%

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Cultivation of microalgae in food processing effluent for pollution attenuation and astaxanthin production: a review of technological innovation and downstream application

Zhang,

2024

Front. Bioeng. Biotechnol.

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Valorization of food processing effluent (FPE) by microalgae cultivation for astaxanthin production is regarded as a potential strategy to solve the environmental pollution of food processing industry and promote the development of eco-friendly agriculture. In this review paper, microalgal species which have the potential to be employed for astaxanthin in FPE were identified. Additionally, in terms of CO2 emission, the performances of microalgae cultivation and traditional methods for FPE remediation were compared. Thirdly, an in-depth discussion of some innovative technologies, which may be employed to lower the total cost, improve the nutrient profile of FPE, and enhance the astaxanthin synthesis, was provided. Finally, specific effects of dietary supplementation of algal astaxanthin on the growth rate, immune response, and pigmentation of animals were discussed. Based on the discussion of this work, the cultivation of microalgae in FPE for astaxanthin production is a value-adding process which can bring environmental benefits and ecological benefits to the food processing industry and agriculture. Particularly, technological innovations in recent years are promoting the shift of this new idea from academic research to practical application. In the coming future, with the reduction of the total cost of algal astaxanthin, policy support from the governments, and further improvement of the innovative technologies, the concept of growing microalgae in FPE for astaxanthin will be more applicable in the industry.

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Section: Microalgae-based Nutrient Recovery In Food Processing Effluentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Cultivation of microalgae in food processing effluent for pollution attenuation and astaxanthin production: a review of technological innovation and downstream application

Zhang,

2024

Front. Bioeng. Biotechnol.

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“…However, other studies have revealed that under high salt stress conditions, the fatty acids in membrane lipids become unsaturated, resulting in an increase in the proportion of unsaturated fatty acids and a decrease in that of saturated fatty acids (Atikij et al, 2019). Not only lipid but also carotenoid content increased under salinity stress, especially MgCl2, and NaCl (Kobayashi et al, 1997;Rad et al, 2011;Pourkarimi et al, 2020;Lu and Lu, 2022).…”

Section: Introductionmentioning

confidence: 96%

Effect of salt stress on the biomass productivity and potential bioenergy feedstock of Graesiella emersonii KNUA204 isolated from Ulleungdo Island, South Korea

Yeo

Suh

et al. 2023

Front. Energy Res.

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Microalgae are versatile, profitable, and promising sources of bioenergy and high-value products, having various applications in the biotechnology industry. Herein, G. emersonii KNUA204 was isolated from Ulleungdo Island, South Korea, and exposed to stressors, i.e., MgCl2 (75 and 150 mM) and NaCl (200 and 400 mM), to investigate improvement in its biomass productivity and feasibility of the application of biomass. Treatment with mild MgCl2 (75 mM) afforded the highest specific growth rate (μ = 0.13 d−1), dry cell weight (3 g L−1), and total carbohydrate content (29.87%). Although all salt treatments decreased chlorophyll and carotenoid contents, treatment with high NaCl concentration (400 mM) afforded the highest zeaxanthin content (0.3 mg g−1). The proximate and ultimate analyses of biomass following treatment with 150 mM MgCl2 revealed 93.85% volatile matter and 22.55 MJ kg−1 calorific value, respectively, indicating that Graesiella emersonii KNUA204 can be potentially used as bioenergy feedstock. The biodiesel quality was established based on the fatty acid methyl ester profiles, and MgCl2 treatment increased the cetane number more than the control. Therefore, the treatment of G. emersonii KNUA204 with MgCl2 during cultivation could provide a microalgae-based bioenergy feedstock with high productivity.

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“…Firstly, microalgae could remove/reduce nutrients, organic pollutants, heavy metals, chemical oxygen demand (COD), and biological oxygen demand (BOD) in wastewater effectively ( Song et al, 2022 ). Secondly, algal biomass cultivated in wastewater could be used as a potential source of precious products that could be utilized in biofuels, cosmetics, pharmaceuticals, and nutraceuticals fields ( Li et al, 2021 ; Lu and Lu, 2022 ; Lu and Xiao, 2022 ). Thirdly, the microalgae-driven wastewater treatment could help to realize the integration of wastewater treatment, industrial CO 2 sequestration and microalgal biomass valorization, and shift wastewater treatment from linear economy to circular economy ( Vaz et al, 2023 ).…”

Section: Introductionmentioning

confidence: 99%

Challenges and potential solutions of microalgae-based systems for wastewater treatment and resource recovery

Gao

Yang

et al. 2023

Front. Bioeng. Biotechnol.

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Microalga‐ and yeast‐based astaxanthin production via nutrient recovery from wastewater for aquaculture practice: an emerging technology for sustainable development

Cited by 10 publications

References 101 publications

Cultivation of microalgae in food processing effluent for pollution attenuation and astaxanthin production: a review of technological innovation and downstream application

Cultivation of microalgae in food processing effluent for pollution attenuation and astaxanthin production: a review of technological innovation and downstream application

Effect of salt stress on the biomass productivity and potential bioenergy feedstock of Graesiella emersonii KNUA204 isolated from Ulleungdo Island, South Korea

Challenges and potential solutions of microalgae-based systems for wastewater treatment and resource recovery

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