High-precision modular microfluidics by micromilling of interlocking injection-molded blocks

Owens, Crystal E.; Hart, A. John

doi:10.1039/c7lc00951h

Cited by 95 publications

(64 citation statements)

References 44 publications

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“…An increasing number of recent microfluidic studies involve chips made of hard plastics because of their suitability for use in modular microfluidics [34]. A similar trend can be seen in biomicrofluidic studies with a move away from PDMS in favor of hard plastics like PS that have traditionally played a large and well understood role in cell experiments in vitro [35].…”

Section: Introductionmentioning

confidence: 81%

Characterization and Neutral Atom Beam Surface Modification of a Clear Castable Polyurethane for Biomicrofluidic Applications

et al. 2019

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Polyurethanes (PU) are a broad class of polymers that offer good solvent compatibility and a wide range of properties that can be used to generate microfluidic layers. Here, we report the first characterization of a commercially available Shore 80D polyurethane (Ultraclear™ 480N) for biomicrofluidic applications. Studies included comparing optical clarity with Polydimethylsiloxane (PDMS) and using high-fidelity replica molding to produce solid PU structures from the millimeter to nanometer scales. Additionally, we report the first use of NanoAccel™ treatment in Accelerated Neutral Atom Beam (ANAB) mode to permanently roughen the surface of PU and improve the adhesion of breast cancer cells (MDA-MB-231) on PU. Surface energy measurements using Owens-Wendt equations indicate an increase in polar and total surface energy due to ANAB treatment. Fourier-transform infrared (FTIR) spectroscopy in attenuated total reflectance (ATR) mode was used to demonstrate that the treatment does not introduce any new types of functional groups on the surface of Ultraclear™ PU. Finally, applicability in rapid prototyping for biomicrofluidics was demonstrated by utilizing a 3D-printing-based replica molding strategy to create PU microfluidic layers. These layers were sealed to polystyrene (PS) bases to produce PU-PS microfluidic chips. Ultraclear™ PU can serve as a clear and castable alternative to PDMS in biomicrofluidic studies.

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Section: Introductionmentioning

confidence: 81%

Characterization and Neutral Atom Beam Surface Modification of a Clear Castable Polyurethane for Biomicrofluidic Applications

et al. 2019

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“…Moreover, by reducing both the lattice constant and cavity depth, miniaturized PCs could be developed for controlling ultrasonic waves. Such devices could be fabricated by advanced manufacturing techniques, such as replication-based forming [54][55][56] , high-resolution additive manufacturing [57][58][59] , and/or micromilling 60,61 . It should also be possible to reduce the response time of the system through automatic operation.…”

Section: Discussionmentioning

confidence: 99%

Dispersion tuning and route reconfiguration of acoustic waves in valley topological phononic crystals

et al. 2020

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The valley degree of freedom in crystals offers great potential for manipulating classical waves, however, few studies have investigated valley states with complex wavenumbers, valley states in graded systems, or dispersion tuning for valley states. Here, we present tunable valley phononic crystals (PCs) composed of hybrid channel-cavity cells with three tunable parameters. Our PCs support valley states and Dirac cones with complex wavenumbers. They can be configured to form chirped valley PCs in which edge modes are slowed to zero group velocity states, where the energy at different frequencies accumulates at different designated locations. They enable multiple functionalities, including tuning of dispersion relations for valley states, robust routing of surface acoustic waves, and spatial modulation of group velocities. This work may spark future investigations of topological states with complex wavenumbers in other classical systems, further study of topological states in graded materials, and the development of acoustic devices.

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“…As new applications emerge, developing a more thorough understanding of pulsatile systems will greatly benefit microfluidics as a whole. Microfluidics has recently experienced a push toward modularity to improve adoption rate by decreasing the need for custom lithographic devices. This presents an excellent opportunity for designing modular fluid oscillators, which eliminate the dependence on outside equipment to generate the oscillatory signal.…”

Section: Conclusion and Perspectivementioning

confidence: 99%

Pulsatile Flow in Microfluidic Systems

Dincau

Dressaire

Sauret

2019

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This review describes the current knowledge and applications of pulsatile flow in microfluidic systems. Elements of fluid dynamics at low Reynolds number are first described in the context of pulsatile flow. Then the practical applications in microfluidic processes are presented: the methods to generate a pulsatile flow, the generation of emulsion droplets through harmonic flow rate perturbation, the applications in mixing and particle separation, and the benefits of pulsatile flow for clog mitigation. The second part of the review is devoted to pulsatile flow in biological applications. Pulsatile flows can be used for mimicking physiological systems, to alter or enhance cell cultures, and for bioassay automation. Pulsatile flows offer unique advantages over a steady flow, especially in microfluidic systems, but also require some new physical insights and more rigorous investigation to fully benefit future applications.

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High-precision modular microfluidics by micromilling of interlocking injection-molded blocks

Cited by 95 publications

References 44 publications

Characterization and Neutral Atom Beam Surface Modification of a Clear Castable Polyurethane for Biomicrofluidic Applications

Characterization and Neutral Atom Beam Surface Modification of a Clear Castable Polyurethane for Biomicrofluidic Applications

Dispersion tuning and route reconfiguration of acoustic waves in valley topological phononic crystals

Pulsatile Flow in Microfluidic Systems

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