ABSTRACT
Microfluidics optimize experimental procedures but often require external pumps for precise, steady, and low flow rates. These procedures typically require extended, continuous operation for long-duration experiments. We introduce the Dual-Syringe Continuous Pumping Mechanism (DSCPM), a low-cost, precise, and continuous pump for microfluidic applications with input multiplexing capability. With a 3D-printed housing and standard components, the DSCPM is easy to fabricate and accessible. Operating at a microliter per minute flow rates, the DSCPM uses fluidic bridge rectification to combine syringe pump precision with continuous infusion. We validated laminar flow in microfluidic ’cell traps’ without disrupting microbial growth. COMSOL simulations confirmed safe shear stress levels. We also developed and tested fluidic multiplexers for greater modularity and automation. Addressing current pump limitations, such as discontinuity and high costs, the DSCPM can enhance experimental capabilities and promote efficiency and precision while increasing accessibility of hardware automation in many fields.
Competing Interest Statement
S.M.D.O. co-founded Doroth, an AgTech start-up focused on developing DNA-based sensors and automation technologies to monitor biological targets in crop fields remotely. Y.H.P. is an employee of BioSens8, a start-up focused on wearable microfluidic sensing technologies. The remaining authors declare no competing interests.