Direct transesterification of microalgae after pulsed electric field treatment

Papachristou, Ioannis; Zhang, S; Gorte, Olga; Ochsenreither, Katrin; Wüstner, Rüdiger; Nazarova, N. I.; Frey, Wolfgang; Silve, Aude

doi:10.1002/jctb.7293

Cited by 4 publications

(1 citation statement)

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“…The present study investigated several organic solvents in order to perform lipid extraction on wet biomass from A. protothecoides, a microalgae well-known for its high productivity and its high neutral lipid content ideal for biofuel production. − A recent GC analysis of the FAME profile, carried out in our laboratory, confirmed the low content of linolenic acid methyl ester (<7%), 13% is accounted for by saturated fatty acids, and C18:1 and C18:2 have a share of 80%, which exceeds the FAME composition requirements for biodiesel according to EN14214.…”

Section: Discussionmentioning

confidence: 76%

Excess of Water Enables Efficient Lipid Extraction from Wet Pulsed-Electric Field-Treated A. protothecoides Microalgae Using Immiscible Solvents

Silve,

Nazarova,

Wüstner

et al. 2024

ACS Sustainable Chem. Eng.

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This article presents a new processing approach to perform lipid extraction on the wet microalgae A. protothecoides using nonpolar solvents or solvents of low polarity. It was demonstrated that solvents such as hexane, heptane, or 2-butanol exhibit a negligible extraction efficiency (<4% of total lipid content) when added to the pulsed-electric field (PEF)-treated and dewatered biomass slurry. In contrast, extraction efficiency after PEF treatment could substantially be increased by adding water and solvent to the biomass slurry. For this case, additional water admixture during extraction enabled to recover 67.3, 62, or 82.3% of the total lipid content, respectively. When utilizing methyl terbutyl ether (MTBE), ethylacetate, and 2-methyltetrahydrofuran (2-MeTHF) as extracting solvents, the yield increase by additional water admixture is far less pronounced. In all cases, the extraction process was performed after a PEF treatment using 1.50 MJ/kgDW plus 24-h incubation and 20 h of mixing time with the solvents and the solvent/water mixtures. Estimations on the energy required for the whole downstream process showed that this process variant allows an energy consumption of 31.48 MJ/kgbiodiesel at maximum and 7.98 MJ/kgbiodiesel at minimum. The low energy requirements (only <22% of the energy content of the lipids) open pathways to energetical applications of microalgae lipids.

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