Microfluidic devices developed over the past decade feature greater intricacy, increased
performance requirements, new materials, and innovative fabrication methods …

The complexity of droplet microfluidics grows with the implementation of parallel processes
and multiple functionalities on a single device. This poses a severe challenge to the …

Organs-on-Chips (OoCs) are testing platforms for the phar-maceutical, cosmetic, and
chemical industries. They are composed of miniaturized organ tissues (so-called organ …

Microfluidic capture chips are useful for preparing or analyzing a wide range of different
chemical, biological, and medical samples. A typical microfluidic capture chip contains …

Droplet-based microfluidic networks allow to process biological or medical samples by
standard unit operations, such as mixing, incubating, sorting, or sensing. However, many of …

Microfluidics is a prospective field which provides technological advances to the life
sciences. However, the design process for microfluidic devices is still in its infancy and …

Microfluidics deals with the manipulation of small amounts of fluids (in the order of few micro-
to pico-liters) and finds a broad application in (bio-) chemistry, biology, pharmacology, and …

Microfluidic networks can be applied to droplet-based Lab-on-a-Chip devices, where
droplets are used to confine samples which flow through closed microchannels along …

Microfluidics is a technology that enables moving analytic processes from expensive and
bulky laboratory equipment to small-scale devices. Microfluidic devices, usually in the form …

The emergence of FluidFM technology has presented a novel opportunity for selective
aspiration and distribution of liquids at the sub-micron scale. However, precise control over …