Feasibility of Utilizing Wastewaters for Large-Scale Microalgal Cultivation and Biofuel Productions Using Hydrothermal Liquefaction Technique: A Comprehensive Review

Bagchi, Sourav Kumar; Patnaik, Reeza; Prasad, Ramasare

doi:10.3389/fbioe.2021.651138

Cited by 9 publications

(6 citation statements)

References 117 publications

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“…Biomass-based biorefineries have recently been considered as a potential strategy to mitigate environmental pollution and climate change by ensuring sustainable waste management (Venkata Hao et al, 2021;Wahab et al, 2022). Bio-based energy production is one sustainable alternative (Amulya et al, 2020;Kokkinos et al, 2021;Kopperi et al, 2021), accounting for 9-10% of the global energy supply (Bagchi et al, 2021). Using nature-inspired processes to design an efficient biorefinery system to produce environmentally-friendly biofuels and chemicals can help to build sustainable bio-refineries and carbon-neutral bioeconomies (Katakojwala and Venkata Mohan, 2021).…”

Section: Introductionmentioning

confidence: 99%

Integrated Waste Biorefineries: Achieving Sustainable Development Goals, 2nd edition

2024

Frontiers Research Topics

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The United Nations' Sustainable Development Goals (SDGs) are designed to revolutionize societies to prepare for the future challenges. However, the practical implementation of such goals in many domains is are yet to be achieved despite of unique essence. Sustainable energy production (aligned with SDG 7), clean water and sanitation (aligned with SDG 6), sustainable waste services (aligned with SDG 11), and mitigating climate change impacts (aligned with SDG 13) have been the prime focus of SDGs. Moreover, much attention is being paid to research and development activities on waste prevention, reduction, recycling, and reuse to achieve responsible consumption and production (aligned with SDG 12). Waste biorefineries have emerged as a sustainable environmental management solution to achieve not only the aforementioned SDGs, but also to accomplish no poverty (aligned with SDG 1) and zero hunger (aligned with SDG 2) and to maintain well-being and good health aligned with (SDG 3) and decent work and economic growth (aligned with SDG 8) worldwide. This is true because integrated waste biorefineries can efficiently and sustainably produce fuels, heat, energy, power, and multiple value-added products and chemicals. It can further facilitate the transition from linear to circular economies and mitigate the major challenges faced, including environmental pollution, climate change, and adverse effects on public health. This Research Topic will focus on different types of waste biorefineries, current status, practical implications, optimization of waste-to-energy technologies, detailed life assessment studies, and future opportunities with a vision to achieve SDGs in the areas of sustainable energy generation, waste management, circular economies, and climate change mitigation. The editorial team of this special issue, consisting of world-renowned scientists including Highly Cited Researchers, welcomes submissions of original research articles, review articles, short communications, industrial and/or country/region case studies that covers the following enlisted topics: • Waste biorefineries (e.g., organic waste biorefinery, agricultural and forestry waste biorefinery, etc.) • Integration of different types of biorefineries • Sustainable development goals • Waste to energy technologies • Energy and resource recovery from biomass and other waste • Renewable and sustainable energy systems • Biomass and waste supply chain • Sustainable waste management systems • Mitigation of environmental pollution and climate change • Life cycle assessment • Sustainable circular and bio-based economies.

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Section: Introductionmentioning

confidence: 99%

Integrated Waste Biorefineries: Achieving Sustainable Development Goals, 2nd edition

2024

Frontiers Research Topics

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“…Compared to terrestrial plants, microalgae grow up to ten times faster [32, 33] and photosynthesize about ten times as efficiently as plants do, owing to their energy efficient photosynthetic apparatus [34, 35]. Moreover, it is feasible to cultivate microalgae on wasteland using saline or waste water [36, 37] with the result that they do not compete with agricultural food production. These advantages make microalgae a suitable biotechnological tool to efficiently fix CO 2 and convert it into sustainable high-value products [38, 39].…”

Section: Introductionmentioning

confidence: 99%

Optimization of the glycerol production fromDunaliella tertiolectaandDunaliellaisolates

Keil,

Breitsameter,

Rieger

et al. 2023

Preprint

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The salt tolerant, marine microalgae Dunaliella tertiolecta is reported to generate significant amounts of intracellular glycerol as an osmoprotectant under high salt conditions. Several studies have identified light color and -intensity, nitrogen- and phosphate limitation, as well as salt concentration as the most inducing factors impacting glycerol productivity. This study aims to optimize glycerol production by investigating these reported factors singularly and in combination to improve the glycerol product titer. The reference strain D. tertiolecta as well as new Dunaliella isolates were evaluated in this study. The results demonstrate that cultivation with white light of an intensity between 500 and 2000 umol m-2 s-1 as opposed to 100 umol m-2 s-1 achieves higher biomass and thereby a higher product titer. Moreover, cultivation in 1.5 M NaCl followed by an increase to 3 M NaCl resulted in hyperosmotic stress conditions, providing the highest glycerol titer. Under these optimal light intensity and salt conditions, the glycerol titer of D. tertiolecta could be doubled to 0.79 mg mL-1. Furthermore, under the same conditions glycerol extracts from new Dunaliella isolates did provide up to 0.94 mg mL-1. Highly pure glycerol obtained under optimal production conditions has widespread applications e.g., in the pharmaceutical industry or the production of sustainable carbon fibers. Moreover, it can be labeled as halal.

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“…Circular bioeconomy of microalgae-based CO 2 biofixation and biorefinery can be analyzed through technical-economic assessment (TEA) and life-cycle assessment (LCA) [4][5][6]. However, one of the bottlenecks faced by microalgae-based CO 2 biofixation technology is the high cost of microalgal culture medium; the components in the culture medium are among the key factors that greatly affect the growth of microalgae and the production of various components [7,8]. Nutrient requirements in large-scale production can comprise up to 50% of the total cost of biomass production, and high-cost media limit the development of back-end products such as biofuels [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

A Low-Cost Fertilizer Medium Supplemented with Urea for the Lutein Production of Chlorella sp. and the Ability of the Lutein to Protect Cells against Blue Light Irradiation

et al. 2023

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This study aimed to investigate the use of organic fertilizers instead of modified f/2 medium for Chlorella sp. cultivation, and the extracted lutein of the microalga to protect mammal cells against blue-light irradiation. The biomass productivity and lutein content of Chlorella sp. cultured in 20 g/L fertilizer medium for 6 days were 1.04 g/L/d and 4.41 mg/g, respectively. These values are approximately 1.3- and 1.4-fold higher than those achieved with the modified f/2 medium, respectively. The cost of medium per gram of microalgal biomass reduced by about 97%. The microalgal lutein content was further increased to 6.03 mg/g in 20 g/L fertilizer medium when supplemented with 20 mM urea, and the cost of medium per gram lutein reduced by about 96%. When doses of ≥1 μM microalgal lutein were used to protect mammal NIH/3T3 cells, there was a significant reduction in the levels of reactive oxygen species (ROS) produced by the cells in the following blue-light irradiation treatments. The results show that microalgal lutein produced by fertilizers with urea supplements has the potential to develop anti-blue-light oxidation products and reduce the economic challenges of microalgal biomass applied to carbon biofixation and biofuel production.

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Feasibility of Utilizing Wastewaters for Large-Scale Microalgal Cultivation and Biofuel Productions Using Hydrothermal Liquefaction Technique: A Comprehensive Review

Cited by 9 publications

References 117 publications

Integrated Waste Biorefineries: Achieving Sustainable Development Goals, 2nd edition

Integrated Waste Biorefineries: Achieving Sustainable Development Goals, 2nd edition

Optimization of the glycerol production fromDunaliella tertiolectaandDunaliellaisolates

A Low-Cost Fertilizer Medium Supplemented with Urea for the Lutein Production of Chlorella sp. and the Ability of the Lutein to Protect Cells against Blue Light Irradiation

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