Separation of microalgae from bacterial contaminants using spiral microchannel in the presence of a chemoattractant

Leticia F. Ngum; Y. Matsushita; Samir F. El-Mashtoly; Ahmed M. R. Fath El-Bab; Ahmed L Abdel-Mawgood

doi:10.1186/s40643-024-00746-8

Bioresources and Bioprocessing ›› 2024, Vol. 11 ›› Issue (1) : 36 DOI: 10.1186/s40643-024-00746-8

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Separation of microalgae from bacterial contaminants using spiral microchannel in the presence of a chemoattractant

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Abstract

Cell separation using microfluidics has become an effective method to isolate biological contaminants from bodily fluids and cell cultures, such as isolating bacteria contaminants from microalgae cultures and isolating bacteria contaminants from white blood cells. In this study, bacterial cells were used as a model contaminant in microalgae culture in a passive microfluidics device, which relies on hydrodynamic forces to demonstrate the separation of microalgae from bacteria contaminants in U and W-shaped cross-section spiral microchannel fabricated by defocusing CO₂ laser ablation. At a flow rate of 0.7 ml/min in the presence of glycine as bacteria chemoattractant, the spiral microfluidics devices with U and W-shaped cross-sections were able to isolate microalgae (Desmodesmus sp.) from bacteria (E. coli) with a high separation efficiency of 92% and 96% respectively. At the same flow rate, in the absence of glycine, the separation efficiency of microalgae for U- and W-shaped cross-sections was 91% and 96%, respectively. It was found that the spiral microchannel device with a W-shaped cross-section with a barrier in the center of the channel showed significantly higher separation efficiency. Spiral microchannel chips with U- or W-shaped cross-sections were easy to fabricate and exhibited high throughput. With these advantages, these devices could be widely applicable to other cell separation applications, such as separating circulating tumor cells from blood.

Keywords

W-shaped cross-section / CO₂ laser ablation / Glycine / Separation efficiency / Removal ratio

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Leticia F. Ngum, Y. Matsushita, Samir F. El-Mashtoly, Ahmed M. R. Fath El-Bab, Ahmed L Abdel-Mawgood. Separation of microalgae from bacterial contaminants using spiral microchannel in the presence of a chemoattractant. Bioresources and Bioprocessing, 2024, 11(1): 36 DOI:10.1186/s40643-024-00746-8

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Adel M, Allam A, Sayour AE, Ragai HF, Umezu S, El-bab AMRF. Fabrication of spiral low-cost microchannel with trapezoidal cross section for cell separation using a grayscale approach. Micromachines, 2023, 14(7): 1340.

[2]	Ahn SW, Lee SS, Lee SJ, Kim JM. Microfluidic particle separator utilizing sheathless elasto-inertial focusing. Chem Eng Sci, 2015, 126: 237-243.

[3]	Al-Halhouli A, Al-Faqheri W, Alhamarneh B, Hecht L, Dietzel A. Spiral microchannels with trapezoidal cross section fabricated by femtosecond laser ablation in glass for the inertial separation of microparticles. Micromachines, 2018, 9(4): 171.

[4]	Bakhshi MS, Rizwan M, Khan GJ, Duan H, Zhai K. Design of a novel integrated microfluidic chip for continuous separation of circulating tumor cells from peripheral blood cells. Sci Rep, 2022, 12: 17016.

[5]	Bhagat AAS, Kuntaegowdanahalli SS, Papautsky I. Continuous particle separation in spiral microchannels using dean flows and differential migration. Lab Chip, 2008, 8(11): 1906-1914.

[6]	Bodénès P, Wang HY, Lee TH, Chen HY, Wang CY. Microfluidic techniques for enhancing biofuel and biorefinery industry based on microalgae. Biotechnol Biofuels, 2019, 12: 33.

[7]	Borowitzka MA. High-value products from microalgae-their development and commercialisation. J Appl Phycol, 2013, 25: 743-756.

[8]	Chung AJ. A minireview on inertial microfluidics fundamentals: inertial particle focusing and secondary flow. BioChip J, 2019, 13: 53-63.

[9]	Di Carlo D, Irimia D, Tompkins RG, Toner M. Continuous inertial focusing, ordering, and separation of particles in microchannels. Proc Natl Acad Sci USA, 2007, 104(48): 18892-18897.

[10]	Hejazian M, Li W, Nguyen NT. Lab on a chip for continuous-flow magnetic cell separation. Lab Chip, 2015, 15(4): 959-970.

[11]	Helmy MO, El-Bab ARF, El-Hofy HA. Fabrication and characterization of polymethyl methacrylate microchannel using dry and underwater CO₂ laser. Proc Inst Mech Eng, 2018, 232: 23-30.

[12]	Kang DH, Kim K, Kim YJ. An anti-clogging method for improving the performance and lifespan of blood plasma separation devices in real-time and continuous microfluidic systems. Sci Rep, 2018, 8: 17015.

[13]	Kemna EWM, Schoeman RM, Wolbers F, Vermes I, Weitz DA, Van Den Berg A. High-yield cell ordering and deterministic cell-in-droplet encapsulation using Dean flow in a curved microchannel. Lab Chip, 2012, 12(16): 2881-2887.

[14]	Kim GY, Son J, Han JI, Park JK. Inertial microfluidics-based separation of microalgae using a contraction–expansion array microchannel. Micromachines, 2021, 12(1): 97.

[15]	Korensky G, Chen X, Bao M, Miller A, Lapizco-Encinas B, Park M, Du K. Single Chlamydomonas reinhardtii cell separation from bacterial cells and auto-fluorescence tracking with a nanosieve device. Electrophoresis, 2021, 42(1–2): 95-102.

[16]	Lee ML, Yao DJ. The separation of microalgae using Dean flow in a spiral microfluidic device. Inventions, 2018, 3: 40.

[17]	Liu P, Liu H, Semenec L, Yuan D, Yan S, Cain AK, Li M. Length-based separation of Bacillus subtilis bacterial populations by viscoelastic microfluidics. Microsyst Nanoeng, 2022, 8: 7.

[18]	Mansour H, Soliman EA, El-Bab AMF, Abdel-Mawgood AL. Development of epoxy resin-based microfluidic devices using CO₂ laser ablation for DNA amplification point-of-care (POC) applications. Int J Adv Manuf Technol, 2022, 120: 4355-4372.

[19]	McGrath J, Jimenez M, Bridle H. Deterministic lateral displacement for particle separation: A review. Lab Chip, 2014, 14(21): 4139-4158.

[20]	Mehran A, Rostami P, Saidi MS, Firoozabadi B, Kashaninejad N. High-throughput, label-free isolation of white blood cells from whole blood using parallel spiral microchannels with u-shaped cross-section. Biosensors, 2021, 11(11): 406.

[21]	Morales-Jiménez M, Gouveia L, Yañez-Fernandez J, Castro-Muñoz J, Barragan-Huerta BE. Microalgae-based biopolymer as a potential bioactive film. Coatings, 2020, 10: 120.

[22]	Morales-Jiménez M, Yáñez-Fernández J, Castro-Muñoz R, Barragán-Huerta BE. Jafari SM, Castro-Muñoz R. Recovery of High Added Value Compounds from Microalgae Cultivation Using Membrane Technology. Membrane Separation of Food Bioactive Ingredients, 2021, Springer, Cham: Food Bioactive Ingredients.

[23]	Mourelle ML, Gómez CP, Legido JL. The potential use of marine microalgae and cyanobacteria in cosmetics and thalassotherapy. Cosmetics, 2017, 4: 46.

[24]	Nam J, Jee H, Jang WS, Yoon J, Park BG, Lee SJ, Lim CS. Sheathless shape-based separation of candida albicans using a viscoelastic non-newtonian fluid. Micromachines, 2019, 10: 817.

[25]	Narayana Iyengar S, Kumar T, Mårtensson G, Russom A. High resolution and rapid separation of bacteria from blood using elasto-inertial microfluidics. Electrophoresis, 2021, 42: 2538-2551.

[26]	Nasser GA, El-Bab AMRF, Abdel-Mawgood AL, Mohamed H, Saleh AM. CO₂ laser fabrication of PMMA microfluidic double T-junction device with modified inlet-angle for cost-effective PCR application. Micromachines, 2019, 10: 10.

[27]	Nasser GA, Fath El-Bab AMR, Mohamed H, Abouelsoud A. Low cost micro-droplet formation chip with a hand-operated suction syringe. Proceedings - 2018 IEEE 18th International Conference on Bioinformatics and Bioengineering, BIBE 2018, pp 73–78. 2019. https://doi.org/10.1109/BIBE.2018.00021

[28]	Okello JL, El-Bab AM, Yoshino M, El-Hofy HA, Hassan MA. Modelling of surface roughness in CO₂ laser ablation of aluminium-coated polymethyl methacrylate (PMMA) using adaptive neuro-fuzzy inference system (ANFIS) in Volume 2B: Advanced Manufacturing. Am Soc Mech Eng, 2022

[29]	Olm F, Urbansky A, Dykes JH, Laurell T, Scheding S. Label-free neuroblastoma cell separation from hematopoietic progenitor cell products using acoustophoresis - towards cell processing of complex biological samples. Sci Rep, 2019, 9: 8777.

[30]	Patil V, Tran K, Giselrød HR. Towards sustainable production of biofuels from microalgae. Int J Mol Sci, 2008, 9(7): 1188-1195.

[31]	Pødenphant M, Ashley N, Koprowska K, Mir KU, Zalkovskij M, Bilenberg B, Bodmer W, Kristensen A, Marie R. Separation of cancer cells from white blood cells by pinched flow fractionation. Lab Chip, 2015, 15(24): 4598-4606.

[32]	Robla J, Alguacil FJ, Dittami SM, Marie D, Deragon E, Guillebault D, Mengs G, Medlin LK, Robla J, Alguacil FJ, Dittami SM, Marie D. Determination of the efficiency of filtration of cultures from microalgae and bacteria using hollow fiber filters. Environ Sci, 2021, 7(7): 1230-1239.

[33]	Ruiz J, Olivieri G, De Vree J, Bosma R, Willems P, Reith JH, Eppink MHM, Kleinegris DMM, Wijffels RH, Barbosa MJ. Towards industrial products from microalgae. Energy Environ Sci, 2016, 9: 3036-3043.

[34]	Schaap A, Dumon J, Toonder JD. Sorting algal cells by morphology in spiral microchannels using inertial microfluidics. Microfluid Nanofluid, 2016, 20: 125.

[35]	Spilling K. Spilling K. Basic Methods for Isolating and Culturing Microalgae. ) Biofuels from Algae Methods in Molecular Biology, 2017, New York: Humana.

[36]	Syed MS, Rafeie M, Vandamme D, Asadnia M, Henderson R, Taylor RA, Warkiani ME. Selective separation of microalgae cells using inertial microfluidics. Biores Technol, 2018, 252: 91-99.

[37]	Wan C, Alam MA, Zhao XQ, Zhang XY, Guo SL, Ho SH, Chang JS, Bai FW. Current progress and future prospect of microalgal biomass harvest using various flocculation technologies. Biores Technol, 2015, 184: 251-257.

[38]	Wang Y. The automatic and high-throughput purification and enrichment of microalgae cells using deterministic lateral displacement arrays with different post shapes. J Chem Technol Biotechnol, 2021, 96: 2228-2237.

[39]	Wang Y, Wang J, Xudong Jiang WW. Dielectrophoretic separation of microalgae cells in ballast water in a microfluidic chip. Electrophoresis, 2019, 40: 969-978.

[40]	Wang Y, Wang J, Cheng J, Zhang Y, Ding G, Wang X, Kang Y, Pan X. Serial separation of microalgae in a microfluidic chip under inertial and dielectrophoretic forces. IEEE Sens J, 2020, 20: 14607-14616.

[41]	Wang S, Liu Z, Wu S, Sun H, Wei J, Fan Z, Sui Z, Liu L, Pan X. Microalgae separation by inertia-enhanced pinched flow fractionation. Electrophoresis, 2021, 42: 2223-2229.

[42]	Yang Y, Pollard AM, Höfler C, Poschet G, Wirtz M, Hell R, Sourjik V. Relation between chemotaxis and consumption of amino acids in bacteria. Mol Microbiol, 2015, 96(6): 1272-1282.

[43]	Yu ZTF, Yong KMA, Fu J. Microfluidic blood cell preparation: now and beyond. Small, 2014, 10: 1687-1703.

[44]	Yuan D, Tan SH, Zhao Q, Yan S, Sluyter R, Nguyen NT, Zhang J, Li W. Sheathless Dean-flow-coupled elasto-inertial particle focusing and separation in viscoelastic fluid. RSC Adv, 2017, 7: 3461-3469.

[45]	Yuan D, Zhao Q, Yan S, Tang SY, Zhang Y, Yun G, Nguyen NT, Zhang J, Li M, Li W. Sheathless separation of microalgae from bacteria using a simple straight channel based on viscoelastic microfluidics. Lab Chip, 2019, 19(17): 2811-2821.

[46]	Zhang X, Zhu Z, Xiang N, Long F, Ni Z. Automated microfluidic instrument for label-free and high-throughput cell separation. Anal Chem, 2018, 90(6): 4212-4220.