Enhanced-throughput production of polymersomes using a parallelized capillary microfluidic device

Kim, Shin‐Hyun; Kim, Jinwoong; Kim, Do-Hoon; Han, Song; Weitz, David A.

doi:10.1007/s10404-012-1069-5

Cited by 67 publications

(41 citation statements)

References 34 publications

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“…Lipidic vesicles have also been produced via T‐junction droplets breaking (Figure b) . Importantly, the viscosity of the outer water phase helps improving the flow focusing geometry, while the volatility of the organic solvent favors the self‐assembly of the amphiphiles, facilitating the formation process . Two different mechanisms have been proposed for the formation of the vesicles from the double emulsion: the evaporation of the organic solvent induces the formation of a depletion force, which in turn initiate the dewetting process (Figure c) .…”

Section: Microfluidic Production Of Microparticles/dropletsmentioning

confidence: 99%

Microfluidics for Production of Particles: Mechanism, Methodology, and Applications

Liu

Fontana

Python

et al. 2019

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In the past two decades, microfluidics‐based particle production is widely applied for multiple biological usages. Compared to conventional bulk methods, microfluidic‐assisted particle production shows significant advantages, such as narrower particle size distribution, higher reproducibility, improved encapsulation efficiency, and enhanced scaling‐up potency. Herein, an overview of the recent progress of the microfluidics technology for nano‐, microparticles or droplet fabrication, and their biological applications is provided. For both nano‐, microparticles/droplets, the previously established mechanisms behind particle production via microfluidics and some typical examples during the past five years are discussed. The emerging interdisciplinary technologies based on microfluidics that have produced microparticles or droplets for cellular analysis and artificial cells fabrication are summarized. The potential drawbacks and future perspectives are also briefly discussed.

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Section: Microfluidic Production Of Microparticles/dropletsmentioning

confidence: 99%

Microfluidics for Production of Particles: Mechanism, Methodology, and Applications

Liu

Fontana

Python

et al. 2019

Small

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“…For example, changing the platform’s architecture to tolerate higher internal pressure affects the mixing time and the physicochemical properties of the NPs. Therefore, parallelization of the microchannels is a promising way to meet the NP production yields required for in vivo studies; such parallel process approaches have been studied for emulsion droplet generation 22–27 and in the chemical engineering industry. 28 …”

Section: Introductionmentioning

confidence: 99%

Parallel microfluidic synthesis of size-tunable polymeric nanoparticles using 3D flow focusing towards in vivo study

Lim

Bertrand

Valencia

et al. 2014

Nanomedicine: Nanotechnology, Biology and Medicine

144

108

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Microfluidic synthesis of nanoparticles (NPs) can enhance the controllability and reproducibility in physicochemical properties of NPs compared to bulk synthesis methods. However, applications of microfluidic synthesis are typically limited to in vitro studies due to low production rates. Herein, we report the parallelization of NP synthesis by 3D hydrodynamic flow focusing (HFF) using a multilayer microfluidic system to enhance the production rate without losing the advantages of reproducibility, controllability, and robustness. Using parallel 3D HFF, polymeric poly(lactide-co-glycolide)-b-polyethyleneglycol (PLGA-PEG) NPs with sizes tunable in the range of 13–150 nm could be synthesized reproducibly with high production rate. As a proof of concept, we used this system to perform in vivo pharmacokinetic and biodistribution study of small (20 nm diameter) PLGA-PEG NPs that are otherwise difficult to synthesize. Microfluidic parallelization thus enables synthesis of NPs with tunable properties with production rates suitable for both in vitro and in vivo studies.

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“…We note, however, that the final diameter of the vesicles differed from the initial droplet's core diameter (see in Figure S2 the thin shell droplets), which was, in addition, different from previously reported values. [33] We also note that during the assembly and solvent evaporation process (illustrated by the red arrows in Figure 1c) excess polymer attached to one pole of the vesicles, a phenomenon that has also been previously observed on both polymersomes and liposomes. [34] To monitor diameter change and visualize the droplet-to-vesicle evolution process, we transferred the droplets to a cavity glass slide that was subsequently covered with a cover slide.…”

Section: Resultsmentioning

confidence: 75%

Microfluidic fabrication of polymersomes enclosing an active Belousov-Zhabotinsky (BZ) reaction: Effect on their stability of solute concentrations in the external media

Pérez–Mercader

2016

Colloids and Surfaces B: Biointerfaces

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Enhanced-throughput production of polymersomes using a parallelized capillary microfluidic device

Cited by 67 publications

References 34 publications

Microfluidics for Production of Particles: Mechanism, Methodology, and Applications

Microfluidics for Production of Particles: Mechanism, Methodology, and Applications

Parallel microfluidic synthesis of size-tunable polymeric nanoparticles using 3D flow focusing towards in vivo study

Microfluidic fabrication of polymersomes enclosing an active Belousov-Zhabotinsky (BZ) reaction: Effect on their stability of solute concentrations in the external media

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