Abstract
AbstractWhile many tools exist to study immune‐cell chemotaxis in vitro, current methods often lack desirable features. Using fluid‐walled microfluidics, circuits are built around primary murine macrophages deposited in pre‐defined patterns on Petri dishes or microplates. Concentration gradients of complement component 5a (C5a) are established in flow‐free or flowing environments, cell migration imaged, and cell directionality and velocity correlated to calculated local C5a concentrations. In flow‐free circuits built around patterned macrophages, only cells nearest the C5a source migrate regardless of local attractant concentration. Conversely, in flowing circuits free from intercellular signaling and attractant degradation, only cells distant from the source migrate. In both systems, cells respond to lower C5a concentrations than previously reported (≈0.1 pM). Finally, macrophages follow instantly‐shifted gradients better than slowly‐shifting ones, suggesting that migration depends on both spatial and temporal responses to concentration.
Sign-in/Register to access full text options 
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
