Kirby Research Group at Cornell: Microfluidics and Nanofluidics :

Cornell University, College of Engineering

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Cornell Micro/Nanofluidics Laboratory

The Micro/Nanofluidics Laboratory, directed by Professor Brian Kirby, is a research group in the Sibley School of Mechanical and Aerospace Engineering at Cornell University devoted to research on understanding and application of micro- and nanofluidic systems. Micro-and Nanofluidics describe fluidic regimes defined by the length scale of the flow channels, the techniques for making the devices, and the dominant physics.

Features

Kirby Lab microfluidics nanofluidics protein refolding in microchips

Miniaturizing pharmaceutical discovery
How microscale protein refolding devices accelerate pharmaceutical development

Circulating tumor cell capture
Enabling personalized chemotherapeutics for cancer patients

Patterned surface microstructures
Studying neurobiology with microfluidic tools

News

Polacheck reports on cancer cell migration in PNAS

Barbati to chair international Gordon Research Seminar on Microfluidics

Announcing the 2011 Microfluidics GRC

Kirbylab receives grant for genetic analysis of circulating tumor cells

Multi-institutional team chosen to probe cytoskeletal architecture in CTCs

Hawkins reports on automated characterization of Mycobacterium

Pratt and Huang report on rare cell capture in microfluidic devices

Link between substrate stiffness and adipose differentiation reported

Rouillard reports on high-viability photocrosslinked alginate

Kirby to present at CTC Meeting in San Francisco

Kirby to present at Lorentz CTC workshop


	Ben in the lab, working on dielectrophoresis in microchips, spring 2007.

	Signal amplification from electrokinetic concentration of liposomes targeting biological pathogens. (see reference at the journal website here).


	Atomic-force microscopy image of polyester/polyethylene fiber containing 1120 nanodomains and showing domain coalescence and domain dimensional instabilities, particularly in the outward radial direction (courtesy J. Hinestroza). We are using microfluidic techniques to pattern micron-scale portions of these nanofibers for material characterization.