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Flow Homogenization Enables a Massively Parallel Fluidic Design for High‐Throughput and Multiplexed Cell Isolation
Author(s) -
Ooi Chinchun,
Earhart Christopher M.,
Hughes Casey E.,
Lee JungRok,
Wong Dawson J.,
Wilson Robert J.,
Rohatgi Rajat,
Wang Shan X.
Publication year - 2020
Publication title -
advanced materials technologies
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.184
H-Index - 42
ISSN - 2365-709X
DOI - 10.1002/admt.201900960
Subject(s) - microfluidics , massively parallel , microscale chemistry , fluidics , throughput , computer science , multiplexing , homogenization (climate) , nanotechnology , materials science , computer hardware , parallel computing , engineering , electrical engineering , telecommunications , mathematics education , mathematics , wireless , biodiversity , ecology , biology
Microfluidic devices are widely used for applications such as cell isolation. Currently, the most common method to improve throughput for microfluidic devices involves fabrication of multiple, identical channels in parallel. However, this “numbering up” only occurs in one dimension, thereby limiting gains in volumetric throughput. In contrast, macrofluidic devices permit high volumetric flow rates but lack the finer control of microfluidics. Here, it is demonstrated how a micropore array design enables flow homogenization across a magnetic cell capture device, thus creating a massively parallel series of microscale flow channels with consistent fluidic and magnetic properties, regardless of spatial location. This design enables scaling in two dimensions, allowing flow rates exceeding 100 mL h −1 while maintaining >90% capture efficiencies of spiked lung cancer cells from blood in a simulated circulating tumor cell system. Additionally, this design facilitates modularity in operation, which is demonstrated by combining two different devices in tandem for multiplexed cell separation in a single pass with no additional cell losses from processing.