Abstract
Double emulsions are useful geometries as templates for core-shell particles, hollow sphere capsules, and for the production of biomedical delivery vehicles. In microfluidics, two approaches are currently being pursued for the preparation of microfluidic double emulsion devices. The first approach utilizes soft lithography, where many identical double-flow-focusing channel geometries are produced in a hydrophobic silicone matrix. This technique requires selective surface modification of the respective channel sections to facilitate alternating wetting conditions of the channel walls to obtain monodisperse double emulsion droplets. The second technique relies on tapered glass capillaries, which are coaxially aligned, so that double emulsions are produced after flow focusing of two co-flowing streams. This technique does not require surface modification of the capillaries, as only the continuous phase is in contact with the emulsifying orifice; however, these devices cannot be fabricated in a reproducible manner, which results in polydisperse double emulsion droplets, if these capillary devices were to be parallelized. Here, we present 3D printing as a means to generate four identical and parallelized capillary device architectures, which produce monodisperse double emulsions with droplet diameters in the range of 500 µm. We demonstrate high throughput synthesis of W/O/W and O/W/O double emulsions, without the need for time-consuming surface treatment of the 3D printed microfluidic device architecture. Finally, we show that we can apply this device platform to generate hollow sphere microgels.
Highlights
Droplet-based microfluidics are a versatile tool to generate double emulsions, which is a droplet inside a droplet in a continuous phase [1]
On the one hand and channel geometries produced by soft-lithography in silicones (PDMS) [12,13]
In contrast to classical capillary devices, where the geometry is set by the shape of the two wider interval of fluid flow rates
Summary
Droplet-based microfluidics are a versatile tool to generate double emulsions, which is a droplet inside a droplet in a continuous phase [1]. The tapering and alignment processes usually go in hand with mismatches, which in a parallelized device causes polydispersity due to different pressure drops and disturbed flow patterns at edges and corners [14]. The inlets and outlets for fluid delivery to and from the microfluidic chip can be connected using wide distribution and collection channels. This idea has brought forth various designs for upscaling the production of double emulsions, namely tree- or ladder-type channel geometries [15] as well as devices for tandem emulsification [16]
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