메뉴 건너뛰기
Microfluidics and Nanofluidics
Volumn 14, Issue 3-4, 2013, Pages 469-477
Selective particle and cell clustering at air-liquid interfaces within ultrasonic microfluidic systems
Author keywords

Acoustic radiation force; Acoustic streaming; Air liquid interface; Particle manipulation; Ultrasonic standing waves
Indexed keywords

ACOUSTIC EMISSIONS; ACOUSTIC RADIATORS; ACOUSTIC STREAMING; ACOUSTIC WAVE PROPAGATION; ACOUSTIC WAVE TRANSMISSION; BIOCHIPS; BLOOD; ESCHERICHIA COLI; LIQUIDS; MICROFLUIDICS; SILICA; ULTRASONIC WAVES; VELOCITY CONTROL;
EID: 84878533659     PISSN: 16134982     EISSN: 16134990     Source Type: Journal    
DOI: 10.1007/s10404-012-1065-9     Document Type: Article
Times cited : (36)
References (28)
  • 1
    • 61849089803 scopus 로고    scopus 로고
    • Decomplexing biofluids using microchip based acoustophoresis
    • 10.1039/b811027a
    • Augustsson P, Persson J, Ekström S, Ohlin M, Laurell T (2009) Decomplexing biofluids using microchip based acoustophoresis. Lab Chip 9:810-818
    • (2009) Lab Chip , vol.9 , pp. 810-818
    • Augustsson, P.1    Persson, J.2    Ekström, S.3    Ohlin, M.4    Laurell, T.5
  • 2
    • 76949091885 scopus 로고    scopus 로고
    • Measuring the local pressure amplitude in microchannel acoustophoresis
    • 10.1039/b920376a
    • Barnkob R, Augustsson P, Laurell T, Bruus H (2010) Measuring the local pressure amplitude in microchannel acoustophoresis. Lab Chip 10:563-570
    • (2010) Lab Chip , vol.10 , pp. 563-570
    • Barnkob, R.1    Augustsson, P.2    Laurell, T.3    Bruus, H.4
  • 3
    • 21344470452 scopus 로고    scopus 로고
    • Surface tension: Floater clustering in a standing wave
    • 10.1038/4351045a
    • Falkovich G, Weinberg A, Denissenko P, Lukaschuk S (2005) Surface tension: floater clustering in a standing wave. Nature 435:1045-1046
    • (2005) Nature , vol.435 , pp. 1045-1046
    • Falkovich, G.1    Weinberg, A.2    Denissenko, P.3    Lukaschuk, S.4
  • 4
    • 0001348889 scopus 로고
    • On the forces acting on a small particle in an acoustical field in an ideal fluid
    • Gor'Kov L (1962) On the forces acting on a small particle in an acoustical field in an ideal fluid. Sov Phys Dokl 6:773-775
    • (1962) Sov Phys Dokl , vol.6 , pp. 773-775
    • Gor'Kov, L.1
  • 5
    • 27844561228 scopus 로고    scopus 로고
    • Positioning, displacement, and localization of cells using ultrasonic forces
    • 10.1002/bit.20540
    • Haake A, Neild A, Radziwill G, Dual J (2005) Positioning, displacement, and localization of cells using ultrasonic forces. Biotechnol Bioeng 92:8-14
    • (2005) Biotechnol Bioeng , vol.92 , pp. 8-14
    • Haake, A.1    Neild, A.2    Radziwill, G.3    Dual, J.4
  • 6
    • 34548077793 scopus 로고    scopus 로고
    • Microfluidic platforms for lab-on-a-chip applications
    • 10.1039/b706364b
    • Haeberle S, Zengerle R (2007) Microfluidic platforms for lab-on-a-chip applications. Lab Chip 7:1094-1110
    • (2007) Lab Chip , vol.7 , pp. 1094-1110
    • Haeberle, S.1    Zengerle, R.2
  • 7
    • 7944228666 scopus 로고    scopus 로고
    • Continuous cell washing and mixing driven by an ultrasound standing wave within a microfluidic channel
    • 10.1039/b408045a
    • Hawkes J, Barber R, Emerson D, Coakley T (2004) Continuous cell washing and mixing driven by an ultrasound standing wave within a microfluidic channel. Lab Chip 4:446-452
    • (2004) Lab Chip , vol.4 , pp. 446-452
    • Hawkes, J.1    Barber, R.2    Emerson, D.3    Coakley, T.4
  • 8
    • 57349191073 scopus 로고    scopus 로고
    • Rapid bioparticle concentration and detection by combining a discharge driven vortex with surface enhanced Raman scattering
    • 10.1063/1.2710191
    • Hou D, Maheshwari S, Chang H (2007) Rapid bioparticle concentration and detection by combining a discharge driven vortex with surface enhanced Raman scattering. Biomicrofluidics 1:104-106
    • (2007) Biomicrofluidics , vol.1 , pp. 14106
    • Hou, D.1    Maheshwari, S.2    Chang, H.3
  • 9
    • 33847326950 scopus 로고    scopus 로고
    • Chip integrated strategies for acoustic separation and manipulation of cells and particles
    • 10.1039/b601326k
    • Laurell T, Petersson F, Nilsson A (2007) Chip integrated strategies for acoustic separation and manipulation of cells and particles. Chem Soc Rev 36:492-506
    • (2007) Chem Soc Rev , vol.36 , pp. 492-506
    • Laurell, T.1    Petersson, F.2    Nilsson, A.3
  • 10
    • 50249142943 scopus 로고    scopus 로고
    • Microfluidic colloidal island formation and erasure induced by surface acoustic wave radiation
    • Li H, Friend J, Yeo L (2008) Microfluidic colloidal island formation and erasure induced by surface acoustic wave radiation. Phys Rev Lett 101:084502
    • (2008) Phys Rev Lett , vol.101 , pp. 084
    • Li, H.1    Friend, J.2    Yeo, L.3
  • 11
    • 80052536944 scopus 로고    scopus 로고
    • Separation of platelets from whole blood using standing surface acoustic waves in a microchannel
    • 10.1039/c1lc20346k
    • Nam J, Lim H, Kim D, Shin S (2011) Separation of platelets from whole blood using standing surface acoustic waves in a microchannel. Lab Chip 11:3361-3364
    • (2011) Lab Chip , vol.11 , pp. 3361-3364
    • Nam, J.1    Lim, H.2    Kim, D.3    Shin, S.4
  • 12
    • 33846606028 scopus 로고    scopus 로고
    • Design, modeling and characterization of microfluidic devices for ultrasonic manipulation
    • 10.1016/j.snb.2006.04.065
    • Neild A, Oberti S, Dual J (2007) Design, modeling and characterization of microfluidic devices for ultrasonic manipulation. Sens Actuators B Chem 121:452-461
    • (2007) Sens Actuators B Chem , vol.121 , pp. 452-461
    • Neild, A.1    Oberti, S.2    Dual, J.3
  • 13
    • 34547574977 scopus 로고    scopus 로고
    • Simultaneous positioning of cells into two-dimensional arrays using ultrasound
    • 10.1002/bit.21315
    • Neild A, Oberti S, Radziwill G, Dual J (2007) Simultaneous positioning of cells into two-dimensional arrays using ultrasound. Biotechnol Bioeng 97:1335-1339
    • (2007) Biotechnol Bioeng , vol.97 , pp. 1335-1339
    • Neild, A.1    Oberti, S.2    Radziwill, G.3    Dual, J.4
  • 14
    • 1942469916 scopus 로고    scopus 로고
    • Acoustic control of suspended particles in micro fluidic chips
    • 10.1039/b313493h
    • Nilsson A, Petersson F, Jönsson H, Laurell T (2004) Acoustic control of suspended particles in micro fluidic chips. Lab Chip 4:131-135
    • (2004) Lab Chip , vol.4 , pp. 131-135
    • Nilsson, A.1    Petersson, F.2    Jönsson, H.3    Laurell, T.4
  • 15
    • 33846661327 scopus 로고    scopus 로고
    • Manipulation of micrometer sized particles within a micromachined fluidic device to form two-dimensional patterns using ultrasound
    • 10.1121/1.2404920
    • Oberti S, Neild A, Dual J (2007) Manipulation of micrometer sized particles within a micromachined fluidic device to form two-dimensional patterns using ultrasound. J Acoust Soc Am 121:778-785
    • (2007) J Acoust Soc Am , vol.121 , pp. 778-785
    • Oberti, S.1    Neild, A.2    Dual, J.3
  • 16
    • 56949102085 scopus 로고    scopus 로고
    • The use of acoustic radiation forces to position particles within fluid droplets
    • 10.1016/j.ultras.2008.05.002
    • Oberti S, Neild A, Quach R, Dual J (2009) The use of acoustic radiation forces to position particles within fluid droplets. Ultrasonics 49:47-52
    • (2009) Ultrasonics , vol.49 , pp. 47-52
    • Oberti, S.1    Neild, A.2    Quach, R.3    Dual, J.4
  • 17
    • 12344284715 scopus 로고    scopus 로고
    • Continuous separation of lipid particles from erythrocytes by means of laminar flow and acoustic standing wave forces
    • 10.1039/b405748c
    • Petersson F, Nilsson A, Holm C, Jönsson H, Laurell T (2005) Continuous separation of lipid particles from erythrocytes by means of laminar flow and acoustic standing wave forces. Lab Chip 5:20-22
    • (2005) Lab Chip , vol.5 , pp. 20-22
    • Petersson, F.1    Nilsson, A.2    Holm, C.3    Jönsson, H.4    Laurell, T.5
  • 18
    • 14744269752 scopus 로고    scopus 로고
    • Carrier medium exchange through ultrasonic particle switching in microfluidic channels
    • 10.1021/ac048394q
    • Petersson F, Nilsson A, Jönsson H, Laurell T (2005) Carrier medium exchange through ultrasonic particle switching in microfluidic channels. Anal Chem 77:1216-1221
    • (2005) Anal Chem , vol.77 , pp. 1216-1221
    • Petersson, F.1    Nilsson, A.2    Jönsson, H.3    Laurell, T.4
  • 19
    • 34547118407 scopus 로고    scopus 로고
    • Free flow acoustophoresis: Microfluidic-based mode of particle and cell separation
    • 10.1021/ac070444e
    • Petersson F, Aberg L, Sward-Nilsson A, Laurell T (2007) Free flow acoustophoresis: microfluidic-based mode of particle and cell separation. Anal Chem 79:5117-5123
    • (2007) Anal Chem , vol.79 , pp. 5117-5123
    • Petersson, F.1    Aberg, L.2    Sward-Nilsson, A.3    Laurell, T.4
  • 20
    • 0017328008 scopus 로고
    • Fluctuations in buoyant density during the cell cycle of Escherichia coli K12: Significance for the preparation of synchronous cultures by age selection
    • Poole R (1977) Fluctuations in buoyant density during the cell cycle of Escherichia coli K12: significance for the preparation of synchronous cultures by age selection. J Gen Microbiol 98:177-186
    • (1977) J Gen Microbiol , vol.98 , pp. 177-186
    • Poole, R.1
  • 21
    • 0003021253 scopus 로고
    • On the circulation of air observed in Kundt's tubes, and on some allied acoustical problems
    • JFM 16.0891.03 10.1098/rstl.1884.0002
    • Rayleigh L (1884) On the circulation of air observed in Kundt's tubes, and on some allied acoustical problems. Philos Trans R Soc Lond 175:1-21
    • (1884) Philos Trans R Soc Lond , vol.175 , pp. 1-21
    • Rayleigh, L.1
  • 22
    • 0032349934 scopus 로고    scopus 로고
    • Acoustic streaming
    • 0907.76081 10.1007/s001620050068
    • Riley N (1998) Acoustic streaming. Theor Comput Fluid Dyn 10:349-356
    • (1998) Theor Comput Fluid Dyn , vol.10 , pp. 349-356
    • Riley, N.1
  • 23
    • 0344393764 scopus 로고    scopus 로고
    • Microstreaming effects on particle concentration in an ultrasonic standing wave
    • 10.1002/aic.690491110
    • Spengler J, Coakley W, Christensen K (2003) Microstreaming effects on particle concentration in an ultrasonic standing wave. AIChE J 49:2773-2782
    • (2003) AIChE J , vol.49 , pp. 2773-2782
    • Spengler, J.1    Coakley, W.2    Christensen, K.3
  • 24
    • 34247849373 scopus 로고    scopus 로고
    • Microparticle collection and concentration via a miniature surface acoustic wave device
    • 10.1039/b618044b
    • Tan M, Friend J, Yeo L (2007) Microparticle collection and concentration via a miniature surface acoustic wave device. Lab Chip 7:618-625
    • (2007) Lab Chip , vol.7 , pp. 618-625
    • Tan, M.1    Friend, J.2    Yeo, L.3
  • 25
    • 60049096829 scopus 로고    scopus 로고
    • Cell separation by non-inertial force fields in microfluidic systems
    • 1258.92005 10.1016/j.mechrescom.2008.08.006
    • Tsutsui H, Ho C (2009) Cell separation by non-inertial force fields in microfluidic systems. Mech Res Commun 36:92-103
    • (2009) Mech Res Commun , vol.36 , pp. 92-103
    • Tsutsui, H.1    Ho, C.2
  • 26
    • 33751049120 scopus 로고    scopus 로고
    • Ultrasonic enhancement of bead-based bioaffinity assays
    • 10.1039/b609184a
    • Wiklund M, Hertz H (2006) Ultrasonic enhancement of bead-based bioaffinity assays. Lab Chip 6:1279-1292
    • (2006) Lab Chip , vol.6 , pp. 1279-1292
    • Wiklund, M.1    Hertz, H.2
  • 27
    • 0030841146 scopus 로고    scopus 로고
    • Using acoustic radiation force as a concentration method for erythrocytes
    • 10.1121/1.421009
    • Yasuda K, Haupt S, Umemura S, Yagi T, Nishida M, Shibata Y (1997) Using acoustic radiation force as a concentration method for erythrocytes. J Acoust Soc Am 102:642-645
    • (1997) J Acoust Soc Am , vol.102 , pp. 642-645
    • Yasuda, K.1    Haupt, S.2    Umemura, S.3    Yagi, T.4    Nishida, M.5    Shibata, Y.6
  • 28
    • 0000289237 scopus 로고
    • Acoustic radiation pressure on a compressible sphere
    • Yosioka K, Kawasima Y (1955) Acoustic radiation pressure on a compressible sphere. Acustica 5:167-173
    • (1955) Acustica , vol.5 , pp. 167-173
    • Yosioka, K.1    Kawasima, Y.2

* 이 정보는 Elsevier사의 SCOPUS DB에서 KISTI가 분석하여 추출한 것입니다.