Sequential extraction of value-added bioproducts from three Chlorella strains using a drying-based combined disruption technique

Zahra Izanlou , Mahmood Akhavan Mahdavi , Reza Gheshlaghi , Arash Karimian

Bioresources and Bioprocessing ›› 2023, Vol. 10 ›› Issue (1) : 44

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Bioresources and Bioprocessing ›› 2023, Vol. 10 ›› Issue (1) : 44 DOI: 10.1186/s40643-023-00664-1
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Sequential extraction of value-added bioproducts from three Chlorella strains using a drying-based combined disruption technique

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Abstract

In this study, the sequential extraction of the three types of biochemicals from microalgae is employed, which is a more realistic and practical solution for large-scale extraction of bioproducts. The drying, grinding, organic solvent treatment, and ultra-sonication were combined to disrupt cells and sequentially extract bioproducts from three microalgae strains, Chlorella sorokiniana IG-W-96, Chlorella sp. PG-96, and Chlorella vulgaris IG-R-96. As the drying is the most energy-intensive step in cell disruption and sequential extraction, the effect of this step on sequential extraction deeply explored. The results show that total ash-plus contents of biochemicals in freeze-dried samples (95.4 ± 2.8%, 89.3 ± 3.9%, and 77.5 ± 4.2 respectively) are higher than those in oven-dried samples (91.0 ± 2.8%, 89.5 ± 3.0%, 71.4 ± 4.8%, respectively) showing the superiority of freeze drying over oven drying merely for Chlorella vulgaris IG-R-96 (p-value = 0.003) and non-significant variation for Chlorella sorokiniana IG-W-96 (p-value = 0.085) and Chlorella sp. PG-96 (p-value = 0.466). Variation among biochemical contents of strains is due to the difference in cell wall strength confirmed by TEM imaging. The freeze-dried samples achieved higher lipid yields than oven-dried samples. The total carbohydrate yields followed the same pattern. The extraction yields of total protein were higher in freeze-dried samples than in oven-dried. Total mass balance revealed that drying-based sequential extraction of value-added bioproducts could better demonstrate the economic potential of sustainable and renewable algal feedstock than independent assays for each biochemical.

Keywords

Chlorella / Bioproducts / Disruption / Drying / Sequential extraction / Biorefinery

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Zahra Izanlou, Mahmood Akhavan Mahdavi, Reza Gheshlaghi, Arash Karimian. Sequential extraction of value-added bioproducts from three Chlorella strains using a drying-based combined disruption technique. Bioresources and Bioprocessing, 2023, 10(1): 44 DOI:10.1186/s40643-023-00664-1

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Alhattab M, Kermanshahipour A, Su-Ling Brooks M. Microalgae disruption techniques for product recovery: influence of cell wall composition. J Appl Phycol, 2019, 31: 61-88.

[2]

Ansari FA, Shriwastav A, Gupta SK, Rawat I, Guldhe A, Bux F. Lipid extracted algae as a source for protein and reduced sugar: a step closer to the biorefinery. Bioresour Technol, 2015, 179: 559-564.

[3]

Ansari FA, Gupta SK, Shriwastav A, Guldhe A, Rawat I, Bux F. Evaluation of various solvent systems for lipid extraction from wet microalgal biomass and its effects on primary metabolites of lipid-extracted biomass. Environ Sci Pollut Res, 2017, 24: 15299-15307.

[4]

Ansari FA, Gupta SK, Nasr M, Rawat I, Bux F. Evaluation of various cell drying and disruption techniques for sustainable metabolite extractions from microalgae grown in wastewater: a multivariate approach. J Clean Prod, 2018, 182: 634-643.

[5]

Chen Y, Vaidyanathan S. Simultaneous assay of pigments, carbohydrates, proteins and lipids in microalgae. Anal Chim Acta, 2013, 776: 31-40.

[6]

Chen CY, Zhao XQ, Yen HW, Ho SH, Cheng CL, Lee DJ, Bai FW, Cang JS. Microalgae-based carbohydrates for biofuel production. Biochem Eng J, 2013, 78: 1-10.

[7]

Dos Santos RR, Moreira DM, Kunigami CN, Aranda DAG, Teixeira CMLL. Comparison between several methods of total lipid extraction from Chlorella vulgaris biomass. Ultrason Sonochem, 2015, 22: 95-99.

[8]

DuBois M, Gilles KA, Hamilton JK, Rebers PA, Smith F. Colorimetric method for determination of sugars and related substances. Anal Chem, 1956, 28: 350-356.

[9]

El-Sheekh MM, Hamouda RA. Lipids extraction from the green alga Ankistrodesmus falcatus using different methods. Rend Fis Acc Lincei, 2016, 27: 589-595.

[10]

Gerde JA, Wang T, Yao L, Jung S, Johnson LA, Lamsal B. Optimizing protein isolation from defatted and non-defatted Nannochloropsis microalgae biomass. Algal Res, 2013, 2: 145-153.

[11]

Grossmann L, Ebert S, Hinrichs J, Weiss J. Production of protein-rich extracts from disrupted microalgae cells: impact of solvent treatment and lyophilization. Algal Res, 2018, 36: 67-76.

[12]

Günerken E, D’Hondt E, Eppink MHM, Garcia-Gonzalez L, Elst K, Wijffels RH. Cell disruption for microalgae biorefineries. Biotechnol Adv, 2015, 33: 243-260.

[13]

Gupta SK, Ansari FA, Nasr M, Rawat I, Nayunigari MK, Bux F. Cultivation of Chlorella sorokiniana and Scenedesmus obliquus in wastewater: fuzzy intelligence for evaluation of growth parameters and metabolites extraction. J Clean Prod, 2017, 147: 419-430.

[14]

Hernández D, Riaño B, Coca M, García-González MC. Saccharification of carbohydrates in microalgal biomass by physical, chemical and enzymatic pre-treatments as a previous step for bioethanol production. Chem Eng J, 2015, 262: 939-945.

[15]

Kim SS, Ly HV, Kim J, Lee EY, Woo HC. Pyrolysis of microalgae residual biomass derived from Dunaliella tertiolecta after lipid extraction and carbohydrate saccharification. Chem Eng J, 2015, 263: 194-199.

[16]

Lam MK, Tan IS, Lee KT. Utilizing lipid-extracted microalgae biomass residues for maltodextrin production. Chem Eng J, 2014, 235: 224-230.

[17]

Lee OK, Oh YK, Lee EY. Bioethanol production from carbohydrate-enriched residual biomass obtained after lipid extraction of Chlorella sp. KR-1. Bioresour Technol, 2015, 196: 22-27.

[18]

Naveena B, Armshaw P, Pembroke JT. Ultrasonic intensification as a tool for enhanced microbial biofuel yields. Biotechnol Biofuels, 2015, 8: 140.

[19]

Phong WN, Show PL, Teh WH, Teh TX, Lim HMY, Nazri NSB, Tan CH, Chang JS, Ling TC. Proteins recovery from wet microalgae using liquid biphasic flotation (LBF). Bioresour Technol, 2017, 244: 1329-1336.

[20]

Phong WN, Show PL, Le CF, Tao Y, Chang JS, Ling TC. Improving cell disruption efficiency to facilitate protein release from microalgae using chemical and mechanical integrated method. Biochem Eng J, 2018, 135: 83-90.

[21]

Pohndorf RS, Camara AS, Larrosa APQ, Pinheiro CP, Strieder MM, Pinto LAA. Production of lipids from microalgae Spirulina sp.: influence of drying, cell disruption and extraction methods. Biomass Bioenerg, 2016, 93: 25-32.

[22]

Roy I, Gupta MN. Freeze-drying of proteins: some emerging concerns. Biotechnol Appl Biochem, 2004, 39: 165-177.

[23]

Safi C, Charton M, Pignolet O, Silvestre F, Vaca-Garcia C, Pontalier PY. Influence of microalgae cell wall characteristics on protein extractability and determination of nitrogen-to-protein conversion factors. J Appl Phycol, 2013, 25: 523-529.

[24]

Sayedin F, Kermanshahi-pour A, He QS, Tibbetts SM, Lalonde CGE, Brar SK. Microalgae cultivation in thin stillage anaerobic digestate for nutrient recovery and bioproduct production. Algal Res, 2020, 47: 101867.

[25]

Schulze C, Reinhardt J, Wurster M, Ortiz-Tena JG, Sieber V, Mundt S. A one-stage cultivation process for lipid- and carbohydrate-rich biomass of Scenedesmus obtusiusculus based on artificial and natural water sources. Bioresour Technol, 2016, 218: 498-504.

[26]

Shekarabi SPH, Mehrgan MS, Razi N, Sabzi S. Biochemical composition and fatty acid profile of the marine microalga Isochrysis galbana dried with different methods. J Microbiol Biotechnol Food Sci, 2019, 9: 521-524.

[27]

Sierra LS, Dixon CK, Wilken LR. Enzymatic cell disruption of the microalgae Chlamydomonas reinhardtii for lipid and protein extraction. Algal Res, 2017, 25: 149-159.

[28]

Sluiter A, Hames B, Ruiz R, Scarlata C, Sluiter J, Templeton D, Crocker DL. Determination of structural carbohydrates and lignin in Biomass. Lab Anal Proc, 2008, 1617(1): 1-16.
[29]

Van Wychen S, Rowland SM, Lesco KC, Shanta PV, Dong T, Laurens LM. Advanced mass balance characterization and fractionation of algal biomass composition. J Appl Phycol, 2021, 33: 2965-2708.

[30]

Yan JK, Wang YY, Ma HL, Wang ZB. Ultrasonic effects on the degradation kinetics, preliminary characterization and antioxidant activities of polysaccharides from Phellinus linteus mycelia. Ultrason Sonochem, 2016, 29: 251-257.

[31]

Zhang R, Chen J, Zhang X. Extraction of intracellular protein from Chlorella pyrenoidosa using a combination of ethanol soaking, enzyme digest, ultrasonication and homogenization techniques. Bioresour Technol, 2018, 247: 267-272.

Funding

Ferdowsi University of Mashhad(3/46418)

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