Fundamentals of inertial focusing in microchannels.

@article{Zhou2013FundamentalsOI,
  title={Fundamentals of inertial focusing in microchannels.},
  author={Jian Zhou and Ian Papautsky},
  journal={Lab on a chip},
  year={2013},
  volume={13 6},
  pages={
          1121-32
        }
}
Inertial microfluidics has been attracting considerable interest in recent years due to immensely promising applications in cell biology. Despite the intense attention, the primary focus has been on development of inertial microfluidic devices with less emphasis paid to elucidation of the inertial focusing mechanics. The incomplete understanding, and sometimes confusing experimental results that indicate a different number of focusing positions in square or rectangular microchannels under… 
View on PubMed
biomicro.uc.edu
293 Citations
Highly Influential Citations
18
Background Citations
66
Methods Citations
17
Results Citations
6

Figures from this paper

293 Citations

Citation Type

Citation Type

Single stream inertial focusing in a straight microchannel.
TLDR
This work presents an inertial microfluidic focuser that uses inertial lift force as the only driving force to focus microparticles into a single position, and demonstrates single-position focusing of different sized microbeads and cells with 95-100% efficiency.
Inertial microfluidics in contraction-expansion microchannels: A review.
TLDR
This article comprehensively reviews various contraction-expansion microchannels with Newtonian and viscoelastic fluids for particle focusing, separation, and microfluid mixing and provides particle manipulation performance data analysis for the contraction- expansion microchannel design.
Inertial Focusing of Microparticles in Curvilinear Microchannels
TLDR
The objective is to analyse the decoupling effects of inertial forces and Dean drag forces on microparticles of different sizes in curvilinear microchannels with inner radius of 800 μm and curvature angle of 280°, which have not been considered in the literature related to inertial microfluidics.
New insights into the physics of inertial microfluidics in curved microchannels. I. Relaxing the fixed inflection point assumption.
TLDR
It is proposed that the dynamic distance (δ) between the real equilibrium positions and their nearest inflection points can clearly explain several (previously) unexplained phenomena in inertial microfluidic systems.
Inertial Focusing in Spiral Microchannels
The ability to control and manipulate the motion of particles or bio-cells from a complex mixture has been the center of attention since the beginning of microfluidics. The microfluidics community
Channel innovations for inertial microfluidics.
TLDR
The purpose of this review is to provide guidance for the continued study of innovative channel designs to improve further the accuracy and throughput of inertial microfluidics.
The upper limit and lift force within inertial focusing in high aspect ratio curved microfluidics
TLDR
The two necessary equations to design the systems and successfully focus the targets in a single, stable, and high-quality position are provided and an interesting scaling law of the lift force is revealed, which is believed to provide a valuable insight into the phenomenon of inertial focusing.
A Review of Secondary Flow in Inertial Microfluidics
TLDR
This review comprehensively summarize the usage of the secondary flow in inertial microfluidics, which is a relatively minor flow perpendicular to the primary flow that may reduce the number of equilibrium positions as well as modify the location of particles focusing within channel cross sections by applying an additional hydrodynamic drag.
Inertial microfluidics: Recent advances
TLDR
A comprehensive review of the recent advances and applications of inertial microfluidic devices according to different channel geometries ranging from straight channels, curved channels to contraction‐expansion‐array channels is presented.
Fundamentals and applications of inertial microfluidics: a review.
TLDR
This review discusses the fundamental kinematics of particles in microchannels to familiarise readers with the mechanisms and underlying physics in inertial microfluidic systems and presents a comprehensive review of recent developments and key applications of inertialMicrofluidics systems according to their microchannel structures.
...
1
2
3
4
5
...

References

SHOWING 1-10 OF 82 REFERENCES
Particle focusing in staged inertial microfluidic devices for flow cytometry.
TLDR
A staged channel design consisting of both curved and straight sections that combine to order particles into a single streamline with longitudinal spacing is presented, suggesting a potentially significant role for inertial focusing in the development of inexpensive flow cytometry-based diagnostics and in applications requiring the analysis of high particle concentrations.
Inertial microfluidics for continuous particle filtration and extraction
In this paper, we describe a simple passive microfluidic device with rectangular microchannel geometry for continuous particle filtration. The design takes advantage of preferential migration of
Lateral and cross-lateral focusing of spherical particles in a square microchannel.
TLDR
The three-dimensional positions of neutrally buoyant spherical particles inside a square microchannel are measured using the digital holographic microscopy technique, and a transition from the lateral tubular pinch to the cross-lateral focusing with increasing R(C) is reported.
Continuous inertial focusing, ordering, and separation of particles in microchannels
TLDR
The ability to differentially order particles of different sizes, continuously, at high rates, and without external forces in microchannels is expected to have a broad range of applications in continuous bioparticle separation, high-throughput cytometry, and large-scale filtration systems.
Visualization of microscale particle focusing in diluted and whole blood using particle trajectory analysis.
Inertial microfluidics has demonstrated the potential to provide a rich range of capabilities to manipulate biological fluids and particles to address various challenges in biomedical science and
Inertial microfluidics for sheath-less high-throughput flow cytometry
TLDR
This paper describes a sheath-less, on-chip flow cytometry system based on the principle of Dean coupled inertial microfluidics, which relies entirely on the microchannel geometry for particle focusing, eliminating the need for complex microchannel designs and additionalmicrofluidic plumbing associated with she Heath-based techniques.
Dynamic self-assembly and control of microfluidic particle crystals
TLDR
Focusing on the dynamics of the particle–particle interactions reveals a mechanism for the dynamic self-assembly process; inertial lift forces and a parabolic flow field act together to stabilize interparticle spacings that otherwise would diverge to infinity due to viscous disturbance flows.
Enhanced particle filtration in straight microchannels using shear-modulated inertial migration
TLDR
This work introduces a novel method for enhanced particle filtration using shear-modulated inertial migration in straight microchannels using a straight microfluidic channel with a rectangular cross section to passively and continuously filter 1.9 μm polystyrene particles.
Continuous scalable blood filtration device using inertial microfluidics
TLDR
A massively parallel microfluidic device that passively separates pathogenic bacteria cells from diluted blood with macroscale performance is presented for the first time and it is expected that this parallelizable, robust, and label‐free approach would be useful for filtration of blood as well as for other cell separation and concentration applications from large volume samples.
The lateral migration of neutrally-buoyant spheres transported through square microchannels
The lateral migration of neutrally-buoyant particles transported through square microchannels has been experimentally investigated over a Reynolds number range of 0.06 ≤ Re ≤ 58.65 at the ratio of
...
1
2
3
4
5
...