Bioparticle separation in non-Newtonian fluid using pulsed flow in micro-channels

Devarakonda, Surendra B.; Han, Jungyoup; Ahn, Chong H.; Banerjee, Rupak K.

doi:10.1007/s10404-006-0131-6

Cited by 18 publications

(14 citation statements)

References 45 publications

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“…As we are interested here primarily in how the pressure profile changes with different k and n values, we have selected a typical flow profile at k = 3, n = 0.5, which serves to illustrate the features of the flow including the velocity, viscosity, and electric field profiles. These values are within the typical range of those for non-Newtonian flows, e.g., for blood, k = 3.313, n = 0.3568 (Devarakonda et al 2007). The applied electric potential distribution in the T-junction is shown in Fig.…”

Section: Resultsmentioning

confidence: 76%

“…For example, human blood (Devarakonda et al 2007), mayonnaise, and dilute polyethelene glycol solutions (Guillot et al 2006) and dilute linear polystyrene solutions (Tanner 2002) all satisfy the Carreau model and have viscosity ratios in the region 10 -5 B l Ã 1 B 10 -2 . The ranges of the Carreau parameters were chosen to include a broad range of fluids.…”

Section: Operating Parameter Rangesmentioning

confidence: 97%

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Pressure sensor positioning in an electrokinetic microrheometer device: simulations of shear-thinning liquid flows

Craven

Rees

Zimmerman

2010

Microfluid Nanofluid

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A novel design for a microrheometer is simulated and tested using finite element modeling techniques. Non-Newtonian fluid obeying the Carreau viscosity model is driven through a microchannel T-junction using electroosmosis. A range of shear rates, and hence viscosities, is produced as the fluid is forced to turn the corner of the T-junction. Thus, the design has the potential to enable the constitutive viscous parameters to be determined from a single microfluidic experiment. Three-dimensional simulations are performed for a broad range of Carreau constitutive parameters. The pressure fields on the microchannel walls, floor, and ceiling are shown to be sensitive to the Carreau parameters that determine the fluid's shear-thinning behavior. The fluid dynamics theory and numerical results described in this article pave the way for a detailed analysis of the corresponding inverse problem, that is, to determine the values of the Carreau constitutive parameters from the pressure field measured by optimal positioning of cheap piezo electric pressure transducers embedded into the inner surface of the microchannel network.

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Section: Resultsmentioning

confidence: 76%

Section: Operating Parameter Rangesmentioning

confidence: 97%

Pressure sensor positioning in an electrokinetic microrheometer device: simulations of shear-thinning liquid flows

Craven

Rees

Zimmerman

2010

Microfluid Nanofluid

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“…3(a) demonstrates the utility of simple bifurcations to extract pure plasma (Yang et al, 2006). Processing time could be reduced by adding pulsatile flow (Devarakonda et al, 2007), but the increased complexity and fouling potential may be of concern for space diagnostics. Another design option is to send the entire fluid stream through a constriction followed by an expansion.…”

Section: Microfluidic Channel Designmentioning

confidence: 99%

Design Principles for Microfluidic Biomedical Diagnostics in Space

Nelson¹

2011

Biomedical Engineering - From Theory to Applications

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“…Viscoelastic is an interesting phenomena existing in fluid due to the elastic component of the liquid and it has also attracts the attention from the microfluidic community (Squires and Quake 2005), e.g. for mixing (Gan et al 2006), focusing (Leshansky et al 2007) and particle fractionation (Devarakonda et al 2007). However, to our understanding this is the first study of viscoelasticity tuning of the hydrodynamic spreading in a microfluidic channel.…”

Section: Introductionmentioning

confidence: 99%

Microfluidic high viability neural cell separation using viscoelastically tuned hydrodynamic spreading

Hjort

Wicher

et al. 2008

Biomed Microdevices

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A high viability microfluidic cell separation technique of high throughput was demonstrated based on size difference continuous mode hydrodynamic spreading with viscoelastic tuning. Using water with fluorescent dye as sample fluid and in parallel introducing as elution a viscoelastic biocompatible polymer solution of alginic sodium, the spreading behavior was investigated at different polymer concentrations and flow rates. Particle separation was studied in the same detail for 9.9 microm and 1.9 microm latex beads. Using buffered aqueous solutions and further surface treatments to protect from cell adhesion, separation between neuron cells and glial cells from rat's spine cord was demonstrated and compared to the separation of latex particles of 20 and 4.6 microm sizes. High relative viability (above 90%) of neural cells was demonstrated compared the reference cells of the same batch.

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Bioparticle separation in non-Newtonian fluid using pulsed flow in micro-channels

Cited by 18 publications

References 45 publications

Pressure sensor positioning in an electrokinetic microrheometer device: simulations of shear-thinning liquid flows

Pressure sensor positioning in an electrokinetic microrheometer device: simulations of shear-thinning liquid flows

Design Principles for Microfluidic Biomedical Diagnostics in Space

Microfluidic high viability neural cell separation using viscoelastically tuned hydrodynamic spreading

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