A Miniaturized 3D-Printed Pressure Regulator (μPR) for Microfluidic Cell Culture Applications

Abstract

AbstractControlled fluid flows are the hallmark feature of microfluidic culture systems and provide precise definition over the biophysical and biochemical microenvironment. Flow control is commonly achieved using displacement-based (e.g., syringe or peristaltic pumps) or pressure-based techniques. These methods offer complex flow capabilities but can be challenging to integrate into incubators or other confined environments due to their large form factors and accompanying peripheral equipment. Since many microfluidic cell culture studies use a single controlled flow rate to maintain or stimulate cells, a portable flow control platform that fits easily into an incubator will benefit the microfluidic community. Here, we demonstrate that a tunable, 3D printed micro pressure regulator (μPR), combined with a battery-powered miniature air pump, can operate as a stand-alone pneumatic flow control platform for microfluidic applications. We detail the design and fabrication of the μPR and demonstrate: i) a tunable outlet pressure range relevant for microfluidic applications (1-10 kPa), ii) highlight dynamic control in a microfluidic network, and iii) maintain human umbilical vein endothelial cells (HUVECs) in a multi-compartment membrane-based culture device under continuous flow conditions. We anticipate that our 3D-printed fabrication approach and open access designs will allow other laboratories to rapidly customize μPRs to support a broad range of applications.