Maike Windbergs scite author profile

How droplet microfluidics can be used to fabricate solid-shelled microcapsules having precisely controlled release behavior is described. Glass capillary devices enable the production of monodisperse double emulsion drops, which can then be used as templates for microcapsule formation. The exquisite control afforded by microfluidics can be used to tune the compositions and geometrical characteristics of the microcapsules with exceptional precision. The use of this approach to fabricate microcapsules that only release their contents when exposed to a specific stimulus--such as a change in temperature, exposure to light, a change in the chemical environment, or an external stress--only after a prescribed time delay, and at a prescribed rate is reviewed.

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Biodegradable Core–Shell Carriers for Simultaneous Encapsulation of Synergistic Actives

Windbergs

Zhao

Heyman³

et al. 2013

J. Am. Chem. Soc.

176

142

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Simultaneous encapsulation of multiple active substances in a single carrier is essential for therapeutic applications of synergistic combinations of drugs. However, traditional carrier systems often lack efficient encapsulation and release of incorporated substances, particularly when combinations of drugs must be released in concentrations of a prescribed ratio. We present a novel biodegradable core−shell carrier system fabricated in a one-step, solvent-free process on a microfluidic chip; a hydrophilic active (doxorubicin hydrochloride) is encapsulated in the aqueous core, while a hydrophobic active (paclitaxel) is encapsulated in the solid shell. Particle size and composition can be precisely controlled, and core and shell can be individually loaded with very high efficiency. Drugloaded particles can be dried and stored as a powder. We demonstrate the efficacy of this system through the simultaneous encapsulation and controlled release of two synergistic anticancer drugs using two cancerderived cell lines. This solvent-free platform technology is also of high potential value for encapsulation of other active ingredients and chemical reagents.

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Raman microscopy for cellular investigations — From single cell imaging to drug carrier uptake visualization

Kann

Offerhaus

Windbergs

et al. 2015

Advanced Drug Delivery Reviews

138

105

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Maike Windbergs

25th Anniversary Article: Double Emulsion Templated Solid Microcapsules: Mechanics And Controlled Release

Biodegradable Core–Shell Carriers for Simultaneous Encapsulation of Synergistic Actives

Raman microscopy for cellular investigations — From single cell imaging to drug carrier uptake visualization

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