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  • Microfluidic-assisted fabrication of carriers for controlled drug delivery.

Microfluidic-assisted fabrication of carriers for controlled drug delivery.

Lab on a chip (2017-05-10)
Dongfei Liu, Hongbo Zhang, Flavia Fontana, Jouni T Hirvonen, Hélder A Santos
ABSTRACT

The microfluidic technique has brought unique opportunities toward the full control over the production processes for drug delivery carriers, owing to the miniaturisation of the fluidic environment. In comparison to the conventional batch methods, the microfluidic setup provides a range of advantages, including the improved controllability of material characteristics, as well as the precisely controlled release profiles of payloads. This review gives an overview of different fluidic principles used in the literature to produce either polymeric microparticles or nanoparticles, focusing on the materials that could have an impact on drug delivery. We also discuss the relations between the particle size and size distribution of the obtained carriers, and the design and configuration of the microfluidic setups. Overall, the use of microfluidic technologies brings exciting opportunities to expand the body of knowledge in the field of controlled drug delivery and great potential to clinical translation of drug delivery systems.

MATERIALS
Product Number
Brand
Product Description

Sigma-Aldrich
Droplet generation and storage chip, Fluidic 719, COC
Sigma-Aldrich
Droplet generator chip - One channel design, Fluidic 162, PC
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Micro Vortex Mixer Chip, Fluidic 642, PC
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Micro Vortex Mixer Chip, Fluidic 642, PMMA
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Droplet generator chip - Multi channel design, Fluidic 1032, PC
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Stir Bar Actuated Mixer Chip, Fluidic 286, PMMA
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Male Mini Luer fluid connector, single, Fluidic 331, PP
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Droplet generator chip - Multi channel design, Fluidic 912, COC
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Cross-shaped channel chip - 100 μm channel, Fluidic 166, PMMA with Luer Interface
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Cross-shaped channel chip - 400 μm channel, Fluidic 395, Cyclic Olefin Polymer (COP) with Luer Interface
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Droplet generator chip - Multi channel design, Fluidic 285, PC
Sigma-Aldrich
Droplet generator chip - Multi channel design, Fluidic 285, COC
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Cross-shaped channel chip - 100 μm channel, Fluidic 166, Cyclic Olefin Polymer (COP) with Luer Interface
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Cross-shaped channel chip - 50 μm channel (double T-junction), Fluidic 201, Cyclic Olefin Polymer (COP) with Luer Interface
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Straight channel chip (4 parallel channels), Fluidic 156, PMMA
Sigma-Aldrich
Cross-shaped channel chip - 400 μm channel, Fluidic 395, PMMA with Luer Interface
Sigma-Aldrich
Cross-shaped channel chip - 400 μm channel, Fluidic 395, Cyclic Olefin Copolymer (COC) with Luer Interface
Sigma-Aldrich
Cross-shaped channel chip (slide format), Fluidic 160, PMMA with Mini-Luer Interface
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Cross-shaped channel chip (slide format), Fluidic 160, Cyclic Olefin Copolymer (COC) with Mini-Luer Interface
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Reaction chamber chip - 6 μl, Fluidic 132, COP
Sigma-Aldrich
Droplet generator chip - One channel design, Fluidic 162, COC
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Rhombic chamber chip - 100 μl, Fluidic 221, PMMA
Sigma-Aldrich
Straight channel chip (4 parallel channels), Fluidic 138, PMMA
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Cross-shaped channel chip (slide format), Fluidic 161, PMMA with Mini-Leur Interface
Sigma-Aldrich
Cross-shaped channel chip - 50 μm channel (double T-junction), Fluidic 201, Cyclic Olefin Copolymer (COP) with Luer Interface
Sigma-Aldrich
Cross-shaped channel chip (slide format), Fluidic 161, Cyclic Olefin Copolymer (COC) with Mini-Luer Interface
Sigma-Aldrich
Cross-shaped channel chip - 50 μm channel (double T-junction), Fluidic 201, PMMA with Luer Interface
Sigma-Aldrich
Cross-shaped channel chip - 100 μm channel, Fluidic 166, Cyclic Olefin Copolymer (COC) with Luer Interface
Sigma-Aldrich
Micro Vortex Mixer Chip, Fluidic 641, COC
Sigma-Aldrich
Micro Vortex Mixer Chip, Fluidic 641, PMMA