Stop flow lithography in perfluoropolyether (PFPE) microfluidic channels

Bong, Ki Wan; Lee, Jiseok; Doyle, Patrick S.

doi:10.1039/c4lc00877d

Cited by 27 publications

(25 citation statements)

References 55 publications

(119 reference statements)

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“…Furthermore, flow lithography can be divided into continuous flow lithography (CFL) and stop flow lithography (SFL) . CFL fabricated microstructures are under a continuous flow of the monomer, which limits its resolution.…”

Section: Resultsmentioning

confidence: 99%

“…CFL fabricated microstructures are under a continuous flow of the monomer, which limits its resolution. In contrast, the SFL microstructure fabrication process was performed in a stationary solution, which greatly improved the resolution . In addition, once structure fabrication process was complete, a much greater flow rate could be applied to flush away the structures.…”

Section: Resultsmentioning

confidence: 99%

“…Furthermore, flow lithography can be divided into continuous flow lithography (CFL) and stop flow lithography (SFL). [45][46][47][48][49] CFL fabricated microstructures are under a continuous flow of the monomer, which limits its resolution. In contrast, the SFL microstructure fabrication process was performed in a stationary solution, which greatly improved the resolution.…”

Section: Fabrication Of Hydrogel Shapesmentioning

confidence: 99%

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High‐Throughput Fabrication and Modular Assembly of 3D Heterogeneous Microscale Tissues

Yang

et al. 2016

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3D hydrogel microstructures that encapsulate cells have been used in broad applications in microscale tissue engineering, personalized drug screening, and regenerative medicine. Recent technological advances in microstructure assembly, such as bioprinting, magnetic assembly, microfluidics, and acoustics, have enabled the construction of designed 3D tissue structures with spatially organized cells in vitro. However, a bottleneck exists that still hampers the application of microtissue structures, due to a lack of techniques that combined high-throughput fabrication and flexible assembly. Here, a versatile method for fabricating customized microstructures and reorganizing building blocks composed of functional components into a combined single geometric shape is demonstrated. The arbitrary microstructures are dynamically synthesized in a microfluidic device and then transferred to an optically induced electrokinetics chip for manipulation and assembly. Moreover, building blocks containing different cells can be arranged into a desired geometry with specific shape and size, which can be used for microscale tissue engineering.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Fabrication Of Hydrogel Shapesmentioning

confidence: 99%

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High‐Throughput Fabrication and Modular Assembly of 3D Heterogeneous Microscale Tissues

Yang

et al. 2016

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“…UV-curable PDMS as a material of microfluidic chips for flow lithography Before fabricating microfluidic chips for SFL, we first verified whether oxygen was permeable to UV-cured PDMS as reported previously. 20 When we photopolymerized the PEGDA prepolymer solution through two glass slides either with or without UV-cured PDMS ( Fig. 1(a)), the synthesized cylinders in contact with UV-cured PDMS became mobile immediately after UV exposure for 100 ms (top panels in Fig.…”

Section: Resultsmentioning

confidence: 99%

“…19 Materials that enable microfluidic devices to perform FL must satisfy two major requirements. 20 First, the materials that are in contact with the photopatternable polymers and photoinitiators ought to be permeable to oxygen, which is the most critical criterion. The oxygen molecules that permeate through the materials serve as great radical scavengers, which consequently generates thin boundary layers of photocrosslinking inhibition (a few micrometers in depth) at the contact surfaces between the materials and the photopatternable polymers.…”

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confidence: 99%

Flow lithography in ultraviolet-curable polydimethylsiloxane microfluidic chips

Kim

Seo

et al. 2017

Biomicrofluidics

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Flow Lithography (FL) is the technique used for the synthesis of hydrogel microparticles with various complex shapes and distinct chemical compositions by combining microfluidics with photolithography. Although polydimethylsiloxane (PDMS) has been used most widely as almost the sole material for FL, PDMS microfluidic chips have limitations: (1) undesired shrinkage due to the thermal expansion of masters used for replica molding and (2) interfacial delamination between two thermally cured PDMS layers. Here, we propose the utilization of ultraviolet (UV)-curable PDMS (X-34-4184) for FL as an excellent alternative material of the conventional PDMS. Our proposed utilization of the UV-curable PDMS offers three key advantages, observed in our study: (1) UV-curable PDMS exhibited almost the same oxygen permeability as the conventional PDMS. (2) The almost complete absence of shrinkage facilitated the fabrication of more precise reverse duplication of microstructures. (3) UV-cured PDMS microfluidic chips were capable of much stronger interfacial bonding so that the burst pressure increased to $0.9 MPa. Owing to these benefits, we demonstrated a substantial improvement of productivity in synthesizing polyethylene glycol diacrylate microparticles via stop flow lithography, by applying a flow time (40 ms) an order of magnitude shorter. Our results suggest that UV-cured PDMS chips can be used as a general platform for various types of flow lithography and also be employed readily in other applications where very precise replication of structures on micro-or submicrometer scales and/or strong interfacial bonding are desirable. Published by AIP Publishing. [http://dx

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Translating Therapeutic Microgels into Clinical Applications

Kittel

Kuehne

Laporte

2021

Adv Healthcare Materials

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Microgels are crosslinked, water‐swollen networks with a 10 nm to 100 µm diameter and can be modified chemically or biologically to render them biocompatible for advanced clinical applications. Depending on their intended use, microgels require different mechanical and structural properties, which can be engineered on demand by altering the biochemical composition, crosslink density of the polymer network, and the fabrication method. Here, the fundamental aspects of microgel research and development, as well as their specific applications for theranostics and therapy in the clinic, are discussed. A detailed overview of microgel fabrication techniques with regards to their intended clinical application is presented, while focusing on how microgels can be employed as local drug delivery materials, scavengers, and contrast agents. Moreover, microgels can act as scaffolds for tissue engineering and regeneration application. Finally, an overview of microgels is given, which already made it into pre‐clinical and clinical trials, while future challenges and chances are discussed. This review presents an instructive guideline for chemists, material scientists, and researchers in the biomedical field to introduce them to the fundamental physicochemical properties of microgels and guide them from fabrication methods via characterization techniques and functionalization of microgels toward specific applications in the clinic.

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Stop flow lithography in perfluoropolyether (PFPE) microfluidic channels

Cited by 27 publications

References 55 publications

High‐Throughput Fabrication and Modular Assembly of 3D Heterogeneous Microscale Tissues

High‐Throughput Fabrication and Modular Assembly of 3D Heterogeneous Microscale Tissues

Flow lithography in ultraviolet-curable polydimethylsiloxane microfluidic chips

Translating Therapeutic Microgels into Clinical Applications

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