Abstract
Microfluidics offers promising methods for aligning cells in physiologically relevant configurations to recapitulate human organ functionality. Specifically, microstructures within microfluidic devices facilitate 3D cell culture by guiding hydrogel precursors containing cells. Conventional approaches utilize capillary forces of hydrogel precursors to guide fluid flow into desired areas of high wettability. These methods, however, require complicated fabrication processes and subtle loading protocols, thus limiting device throughput and experimental yield. Here, we present a swift and robust hydrogel patterning technique for 3D cell culture, where preloaded hydrogel solution in a microfluidic device is aspirated while only leaving a portion of the solution in desired channels. The device is designed such that differing critical capillary pressure conditions are established over the interfaces of the loaded hydrogel solution, which leads to controlled removal of the solution during aspiration. A proposed theoretical model of capillary pressure conditions provides physical insights to inform generalized design rules for device structures. We demonstrate formation of multiple, discontinuous hollow channels with a single aspiration. Then we test vasculogenic capacity of various cell types using a microfluidic device obtained by our technique to illustrate its capabilities as a viable micro-manufacturing scheme for high-throughput cellular co-culture.
Highlights
Microfluidics offers promising methods for aligning cells in physiologically relevant configurations to recapitulate human organ functionality
Our rail-based open microfluidic platform consists of a 3D printed structure of photo curable resin and an underlying pressure sensitive adhesive (PSA) film. 3D-printed rail structures consisted of high rails (HRs) surrounded by low rail (LRs) and reservoir walls which supports rail structures and are bonded to the PSA film
Upon aspirating through the same port, the liquid is sucked into the pipette only from the region below high rail (HR), while the low rail (LR) strongly retains the liquid
Summary
Microfluidics offers promising methods for aligning cells in physiologically relevant configurations to recapitulate human organ functionality. Conventional approaches utilize capillary forces of hydrogel precursors to guide fluid flow into desired areas of high wettability These methods, require complicated fabrication processes and subtle loading protocols, limiting device throughput and experimental yield. Different types of cell suspensions or hydrogels containing cells can later fill the remaining adjacent channels after cross-linking of the pre-loaded hydrogel precursor These microstructure-mediated hydrogel patterning methods can mediate meniscus-pinning for precisely segregating co-cultures in hydrogels to model v asculature[8,9,10], tumor extravasation dynamics[11], glomerular filtration barrier[12], and intestinal epithelium tubes[13]. Plates between which liquids are confined owing to capillary forces, while the side areas are exposed to the air[23] In those studies, spontaneous capillary flow along corner or rail structures enhanced yield by reducing the effect of user’s dispensing pressure. Our rail-based open microfluidic devices are amenable to fabrication by injection molding[21,26], thereby suggesting their great potential as an easy-to-use co-culture platform with low cost and high manufacturing scalablity
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
