Modular design of centrifugal microfluidic system and its application in nucleic acid screening

Modular integration of functional components on the chip and increasement in control accuracy through real-time alteration in the force direction of droplets is an effective way to optimize centrifugal microfluidic sys-tems and realize passive components, compact modules, and high-throughput control. Conventional centrifugal microfluidic chips are mainly driven and controlled by centrifugal force and Euler force. The control valves are easily affected by machining precision, making the control unstable. In this study, a novel centrifugal micro-fluidic system is introduced to improve the freedom and accuracy of chip control while facilitating the design and addition of passive functional components. Furthermore, we modularize the centrifugal microfluidic chip to greatly shorten the period of design and optimization cycle and achieve chip reusability and multi-threaded control. Finally, to verify the feasibility of the modular centrifugal microfluidic chip applied to high-throughput nucleic acid screening, we test the nucleic acid purification and detection colorimetric reactions based on the modular centrifugal microfluidic chip. Among them, Chelex-100 is used to realize the purification of nucleic acid in cell lysate, and the purified solution can realize amplification in the PCR instrument, and the nucleic acid detection results are consistent with the off-chip kit by experimental testing. The system has great flexibility and stability under the acceptable purity of nucleic acid, which indicates that the platform has great potential for large-scale rapid screening applications.

Automated summary

Modular integration of functional components on the chip and real-time alteration in the force direction of droplets optimizes centrifugal microfluidic systems and allows for passive components, compact modules, and high-throughput control. A novel centrifugal microfluidic system is introduced to improve chip control freedom and accuracy while facilitating the design and addition of passive functional components. The system is modularized to shorten design and optimization cycles and achieve chip reusability and multi-threaded control. Testing the nucleic acid purification and detection reactions on the modular chip verifies its feasibility for high-throughput nucleic acid screening.