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Issue
Korean Journal of Chemical Engineering,
Vol.33, No.6, 1757-1766, 2016
Recent developments in scale-up of microfluidic emulsion generation via parallelization
Jeong HH, Issadore D, Lee D
Microfluidics affords precise control over the flow of multiphasic fluids in micron-scale channels. By manipulating the viscous and surface tension forces present in multiphasic flows in microfluidic channels, it is possible to produce highly uniform emulsion droplets one at a time. Monodisperse droplets generated based on microfluidics are useful templates for producing uniform microcapsules and microparticles for encapsulation and delivery of active ingredients as well as living cells. Also, droplet microfluidics have been extensively exploited as a means to enable highthroughput biological screening and assays. Despite the promise droplet-based microfluidics hold for a wide range of applications, low production rate (<<10mL/hour) of emulsion droplets has been a major hindrance to widespread utilization at the industrial and commercial scale. Several reports have recently shown that one way to overcome this challenge and enable mass production of microfluidic droplets is to parallelize droplet generation, by incorporating a large number of droplet generation units (N>>100) and networks of fluid channels that distribute fluid to each of these generators onto a single chip. To parallelize droplet generation and, at the same time, maintain high uniformity of emulsion droplets, several considerations have to be made including the design of channel geometries to ensure even distribution of fluids to each droplet generator, methods for large-scale and uniform fabrication of microchannels, device materials for mechanically robust operation to withstand high-pressure injection, and development of commercially feasible fabrication techniques for three-dimensional microfluidic devices. We highlight some of the recent advances in the mass production of highly uniform microfluidics droplets via parallelization and discuss outstanding issues.
Keywords: Microfluidics; Emulsions; Droplets; Scale-up; Large-scale Integration; Device Fabrication
[References]
  1. Kikuchi Y, Sato K, Ohki H, Kaneko T, Microvasc. Res., 44, 226, 1992
  2. Manz A, Harrison DJ, Verpoorte EMJ, Fettinger JC, Paulus A, Ludi H, Widmer HM, J. Chromatogr., 593, 253, 1992
  3. Garstecki P, Fuerstman MJ, Stone HA, Whitesides GM, Lab Chip, 6, 437, 2006
  4. Mazutis L, Griffiths AD, Lab Chip, 12, 1800, 2012
  5. Solvas XCI, deMello A, Chem. Commun., 47, 1936, 2011
  6. Jin SH, Jeong HH, Lee B, Lee SS, Lee CS, Lab Chip, 15, 3677, 2015
  7. Pang Y, Kim H, Liu ZM, Stone HA, Lab Chip, 14, 4029, 2014
  8. Sugiura S, Nakajima M, Iwamoto S, Seki M, Langmuir, 17(18), 5562, 2001
  9. Utada AS, Fernandez-Nieves A, Stone HA, Weitz DA, Phys. Rev. Lett., 99, 094502, 2007
  10. Lee MH, Hribar KC, Brugarolas T, Kamat NP, Burdick JA, Lee D, Adv. Funct. Mater., 22(1), 131, 2012
  11. Joensson HN, Svahn HA, Angew. Chem.-Int. Edit., 51, 12176, 2012
  12. Jeong HH, Jin SH, Lee BJ, Kim T, Lee CS, Lab Chip, 15, 889, 2015
  13. Duraiswamy S, Khan SA, Nano Lett., 10, 3757, 2010
  14. Jung JH, Park TJ, Lee SY, Seo TS, Angew. Chem.-Int. Edit., 51, 5634, 2012
  15. Hindson BJ, Ness KD, Masquelier DA, Belgrader P, Heredia NJ, Makarewicz AJ, Bright IJ, Lucero MY, Hiddessen AL, Anal. Chem., 83, 8604, 2011
  16. Juul S, Ho YP, Koch J, Andersen FF, Stougaard M, Leong KW, Knudsen BR, ACS Nano, 5, 8305, 2011
  17. Koziej D, Floryan C, Sperling RA, Ehrlicher AJ, Issadore D, Westervelt R, Weitz DA, Nanoscale, 5, 5468, 2013
  18. Agresti JJ, Antipov E, Abate AR, Ahn K, Rowat AC, Baret JC, Marquez M, Klibanov AM, Griffiths AD, Weitz DA, Proc. Natl. Acad. Sci. U.S.A., 107, 6550, 2010
  19. Brouzes E, Medkova M, Savenelli N, Marran D, Twardowski M, Hutchison JB, Rothberg JM, Link DR, Perrimon N, Samuels ML, Proc. Natl. Acad. Sci. U.S.A., 106, 14195, 2009
  20. Sjostrom SL, Bai YP, Huang MT, Liu ZH, Nielsen J, Joensson HN, Svahn HA, Lab Chip, 14, 806, 2014
  21. Muluneh M, Kim B, Buchsbaum G, Issadore D, Lab Chip, 14, 4638, 2014
  22. Barbier V, Willaime H, Tabeling P, Jousse F, Phys. Rev. E, 74, 2006
  23. Holtze C, J. Phys. D-Appl. Phys., 46, 2013
  24. Joscelyne SM, Tragardh G, J. Membr. Sci., 169(1), 107, 2000
  25. Vladisavljevic GT, Khalid N, Neves MA, Kuroiwa T, Nakajima M, Uemura K, Ichikawa S, Kobayashi I, Adv. Drug Deliv. Rev., 65, 1626, 2013
  26. Lim J, Caen O, Vrignon J, Konrad M, Taly V, Baret JC, Biomicrofluidics, 9, 034101, 2015
  27. Sahin S, Schroen K, Lab Chip, 15, 2486, 2015
  28. Nisisako T, Ando T, Hatsuzawa T, Lab Chip, 12, 3426, 2012
  29. Romanowsky MB, Abate AR, Rotem A, Holtze C, Weitz DA, Lab Chip, 12, 802, 2012
  30. Muluneh M, Issadore D, Lab Chip, 13, 4750, 2013
  31. Jeong HH, Yelleswarapu VR, Yadavali S, Issadore D, Lee D, Lab Chip, 15, 4387, 2015
  32. Bardin D, Kendall MR, Dayton PA, Lee AP, Biomicrofluidics, 7, 034112, 2013
  33. Li W, Greener J, Voicu D, Kumacheva E, Lab Chip, 9, 2715, 2009
  34. Conchouso D, Castro D, Khan SA, Foulds IG, Lab Chip, 14, 3011, 2014
  35. Tetradis-Meris G, Rossetti D, de Torres CP, Cao R, Lian GP, Janes R, Ind. Eng. Chem. Res., 48(19), 8881, 2009
  36. McDonald JC, Whitesides GM, Acc. Chem. Res., 35, 491, 2002
  37. Nge PN, Rogers CI, Woolley AT, Chem. Rev., 113(4), 2550, 2013
  38. Fiorini GS, Chiu DT, Biotechniques, 38, 429, 2005
  39. Nisisako T, Torii T, Lab Chip, 8, 287, 2008
  40. Xu Y, Wang CX, Li LX, Matsumoto N, Jang K, Dong YY, Mawatari K, Suga T, Kitamori T, Lab Chip, 13, 1048, 2013
  41. Kotowski J, Navratil V, Slouka Z, Snita D, Microelectron. Eng., 110, 441, 2013
  42. Saarela V, Haapala M, Kostiainen R, Kotiaho T, Franssila S, Lab Chip, 7, 644, 2007
  43. Zhai HY, Yuan KS, Yu X, Chen ZG, Liu ZP, Su ZH, Electrophoresis, 36(20), 2509, 2015
  44. Saarela V, Haapala M, Kostiainen R, Kotiaho T, Franssila S, J. Micromech. Microeng., 19, 055001, 2009
  45. Kolari K, Saarela V, Franssila S, J. Micromech. Microeng., 18, 2008
  46. Baram A, Naftali M, J. Micromech. Microeng., 16, 2287, 2006
  47. Giboz J, Copponnex T, Mele P, J. Micromech. Microeng., 17, R96, 2007
  48. Tanzi S, Matteucci M, Christiansen TL, Friis S, Christensen MT, Garnaes J, Wilson S, Kutchinsky J, Taboryski R, Lab Chip, 13, 4784, 2013
  49. Abgrall P, Low LN, Nguyen NT, Lab Chip, 7, 520, 2007
  50. Guckenberger DJ, de Groot TE, Wan AMD, Beebe DJ, Young EWK, Lab Chip, 15, 2364, 2015
  51. Jun MBG, Liu XY, DeVor RE, Kapoor SG, J. Manuf. Sci. E-T Asme., 128, 893, 2006
  52. Becker H, Gartner C, Electrophoresis, 21(1), 12, 2000
  53. Heckele M, Guber AE, Truckenmuller R, Microsyst. Technol., 12, 1031, 2006
  54. Tsao CW, DeVoe DL, Microfluid. Nanofluid., 6, 1, 2009
  55. Roy E, Galas JC, Veres T, Lab Chip, 11, 3193, 2011
  56. Yoon SC, Horita Z, Kim HS, J. Mater. Process. Technol., 201, 32, 2008
  57. Yoon SC, Jeong HG, Lee S, Kim HS, Comp. Mater. Sci., 77, 202, 2013
  58. Tsao CW, Hromada L, Liu J, Kumar P, DeVoe DL, Lab Chip, 7, 499, 2007
  59. Saharil F, Carlborg CF, Haraldsson T, van der Wijngaart W, Lab Chip, 12, 3032, 2012
  60. Sia SK, Whitesides GM, Electrophoresis, 24(21), 3563, 2003
  61. Grover WH, Skelley AM, Liu CN, Lagally ET, Mathies RA, Sens. Actuators B-Chem., 89, 315, 2003
  62. Zhou JW, Ellis AV, Voelcker NH, Electrophoresis, 31(1), 2, 2010
  63. Thompson BL, Ouyang YW, Duarte GRM, Carrilho E, Krauss ST, Landers JP, Nat. Protoc., 10, 875, 2015
  64. Melchels FPW, Feijen J, Grijpma DW, Biomaterials, 31, 6121, 2010
  65. Waldbaur A, Rapp H, Lange K, Rapp BE, Anal. Methods, 3, 2681, 2011
  66. Shallan AI, Smejkal P, Corban M, Guijt RM, Breadmore MC, Anal. Chem., 86, 3124, 2014
  67. O’Neill PF, Azouz AB, Vazquez M, Liu J, Marczak S, Slouka Z, Chang HC, Diamond D, Brabazon D, Biomicrofluidics, 8, 052112, 2014
  68. Au AK, Lee W, Folch A, Lab Chip, 14, 1294, 2014
  69. Comina G, Suska A, Filippini D, Lab Chip, 14, 424, 2014
  70. Ho CMB, Ng SH, Li KHH, Yoon YJ, Lab Chip, 15, 3627, 2015
  71. Bhargava KC, Thompson B, Malmstadt N, Proc. Natl. Acad. Sci. U. S. A., 111, 15013, 2014
  72. Femmer T, Jans A, Eswein R, Anwar N, Moeller M, Wessling M, Kuehne AJ, ACS Appl. Mater. Interfaces, 7, 12635, 2015
  73. Tran TM, Cater S, Abate AR, Biomicrofluidics, 8, 016502, 2014
  74. Arriaga LR, Amstad E, Weitz DA, Lab Chip, 15, 3335, 2015
  75. Kim SC, Sukovich DJ, Abate AR, Lab Chip, 15, 3163, 2015
  76. Brugarolas T, Tu FQ, Lee D, Soft Matter, 9, 9046, 2013
  77. Datta SS, Abbaspourrad A, Amstad E, Fan J, Kim SH, Romanowsky M, Shum HC, Sun BJ, Utada AS, Windbergs M, Zhou SB, Weitz DA, Adv. Mater., 26(14), 2205, 2014
  78. Zhao CX, Adv. Drug Deliv. Rev., 65, 1420, 2013
[Cited By]
  1. Jeong SG, Jeong JH, Kang KK, Jin SH, Lee BJ, Choi CH, Lee CS, Korean Journal of Chemical Engineering, 35(10), 2036, 2018
  2. Jeong HH, Korean Chemical Engineering Research, 56(5), 761, 2018
  3. Behdani B, Monjezi S, Zhang J, Wang C, Park JT, Korean Journal of Chemical Engineering, 37(12), 2117, 2020
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