Daniel L. Geiger scite author profile

Droplet-based microfluidic technology offers several benefits: the integration of multiple laboratory functions into a single microfabricated chip, manual intervention possibilities, minimal sample consumption, and increased analysis speed and data precision. These advantages have boosted the widespread application of this technology in biological and biomedical research. Despite recent progress, considerable challenges remain to be addressed for end-user applications. This especially concerns the difficulty of creating powerful and easy to implement methods for real-time analysis and active manipulation of passing droplets. Toward this end, we developed a very sensitive optical device equipped with smart algorithms for real-time label-free monitoring and active manipulation of passing droplets. We demonstrate the advanced properties of the developed optical device by measuring different droplet production parameters as well as the label-free detection of cells in droplets. Moreover, the newly developed technology was connected with a function generator system to allow for subsequent manipulation of the monitored droplets based on the measured parameters. As an example, we performed electric field-mediated, label-free sorting of cell-containing droplets from empty ones. Furthermore, we achieved an efficient size-based separation of droplets. We envision that the developed optical device will be a useful tool for the online monitoring of passing droplets and will be implemented for the integration and automation of various droplet-based microfluidic functional units. K E Y W O R D S active droplet manipulation, droplet-based microfluidics, high-throughput, label-free, realtime observation This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Equivalent power system impedance estimation using voltage and current measurements

Eidson

Geiger

Halpin

2014

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Assessing Voltage Fluctuations and Lamp Flicker Using RMS Voltages

Geiger

Halpin

2017

IEEE Trans. Power Delivery

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Measurement of nano particle adhesion by atomic force microscopy using probability theory based analysis

Geiger¹,

Schrezenmeier²,

Roos³

et al. 2017

J. Phys. D: Appl. Phys.

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Daniel L. Geiger

Vetigastropoda

Label‐free monitoring and manipulation of microfluidic water‐in‐oil droplets

Equivalent power system impedance estimation using voltage and current measurements

Assessing Voltage Fluctuations and Lamp Flicker Using RMS Voltages

Measurement of nano particle adhesion by atomic force microscopy using probability theory based analysis

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