Hydrodynamic metamaterials: Microfabricated arrays to steer, refract, and focus streams of biomaterials

We show that it is possible to direct particles entrained in a fluid along trajectories much like rays of light in classical optics. A microstructured, asymmetric post array forms the core hydrodynamic element and is used as a building block to construct microfluidic metamaterials and to demonstrate...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2008-05, Vol.105 (21), p.7434-7438
Main Authors: Morton, Keith J, Loutherback, Kevin, Inglis, David W, Tsui, Ophelia K, Sturm, James C, Chou, Stephen Y, Austin, Robert H
Format: Article
Language:English
Subjects:
Biocompatible Materials - chemical synthesis
Biocompatible Materials - chemistry
Biological Sciences
Biomaterials
Biomedical materials
Biophysics
Biotechnology
Cells
Dyes
Fluid flow
Humans
Hydrodynamics
Lymphocytes
Microfluidic Analytical Techniques
Microfluidics - methods
Optical focus
Optics
Particle Size
Particle trajectories
Physical Sciences
Platelets
Refraction
Streams
Trajectories
Water - chemistry
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Summary:We show that it is possible to direct particles entrained in a fluid along trajectories much like rays of light in classical optics. A microstructured, asymmetric post array forms the core hydrodynamic element and is used as a building block to construct microfluidic metamaterials and to demonstrate refractive, focusing, and dispersive pathways for flowing beads and cells. The core element is based on the concept of deterministic lateral displacement where particles choose different paths through the asymmetric array based on their size: Particles larger than a critical size are displaced laterally at each row by a post and move along the asymmetric axis at an angle to the flow, while smaller particles move along streamline paths. We create compound elements with complex particle handling modes by tiling this core element using multiple transformation operations; we show that particle trajectories can be bent at an interface between two elements and that particles can be focused into hydrodynamic jets by using a single inlet port. Although particles propagate through these elements in a way that strongly resembles light rays propagating through optical elements, there are unique differences in the paths of our particles as compared with photons. The unusual aspects of these modular, microfluidic metamaterials form a rich design toolkit for mixing, separating, and analyzing cells and functional beads on-chip.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0712398105