Sequential Downstream Process for Concurrent Extraction of Lutein, Phytol, and Biochemicals from Marine Microalgal Biomass as a Sustainable Biorefinery

Sadukha, Shreya; Mehta, Bhavika; Chatterjee, Shruti; Ghosh, Arup; Dineshkumar, Ramalingam

doi:10.1021/acssuschemeng.2c04804

Cited by 5 publications

(1 citation statement)

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“…Even though the recovery of total lipids was reduced, 60 ± 1.5 wt% of the initial biomass weight was recovered as carbohydrates and lipids, which is higher than current single product recovery strategies. Sadukha et al studied the sequential recovery of major biochemical compounds from Chlorella variabilis biomass and showed 76.4% recovery of lipids but only 54.6% of carbohydrates which results in a lower overall recovery from the initial biomass [31] than reported here. The remaining 40 wt% of biomass is likely rich in proteins and other bioproducts that also have the potential to be recovered even further as proven by Izanlou et al [17] and Hildebrand et al [32] which may further decrease the economic risk of microalgal-based fuels and chemicals.…”

Section: Resultscontrasting

confidence: 52%

Sequential Extraction of Carbohydrates and Lipids from Chlorella vulgaris Using Combined Physical and Chemical Pre-Treatments

Hammann,

Ross,

Seames

2024

ChemEngineering

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A key focus of microalgae-based fuels/chemicals research and development has been on the lipids that many strains generate, but recent studies show that solely recovering these lipids may not be cost competitive with fossil-derived processes. However, if the carbohydrates can also be recovered and ultimately converted into useful chemical intermediates, this may improve the economics for microalgae-based sustainable product technologies. In the present work, physical and chemical pre-treatments were performed on the Chlorella vulgaris microalgae strain to recover the carbohydrates from the biomass primarily in the form of glucose and galactose. The effects of temperature, acid concentration, microalgae solid-to-liquid loading, and hydrolysis time on carbohydrate hydrolysis and recovery was explored to identify optimum conditions. The highest recovery of total carbohydrates, 90 ± 1.1 wt% at 95% confidence which represents 40 wt% of the initial biomass, was obtained using temperature-assisted weak-acid extraction. Sequential extraction of carbohydrates and lipids was then explored. The highest recovery of total lipids was 71 ± 1.8 wt%, which represents 22 ± 0.9 wt% of the initial biomass. The sequential extraction of carbohydrates followed by lipids resulted in an overall recovery of 60 ± 1.6 wt% of the initial biomass, which is higher than current single product recovery strategies. These results suggest that adding carbohydrate recovery may be a viable strategy for overcoming a major economic hurdle to microalgae-derived chemical and fuel production by significantly increasing the yield of usable materials from microalgae biomass.

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Section: Resultscontrasting

confidence: 52%