Enhancing cell separation in a hybrid spiral dielectrophoretic microchannel: Numerical insights and optimal operating conditions

Reliable separation of circulating tumor cells from blood cells is crucial for early cancer diagnosis and prognosis. Many conventional microfluidic platforms take advantage of the size difference between particles for their separation, which renders them impractical for sorting overlapping‐sized cel...

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Bibliographic Details
Published in:Biotechnology progress 2024-05, Vol.40 (3), p.e3437-n/a
Main Authors: Uddin, Mohammed Raihan, Chen, Xiaolin
Format: Article
Language:English
Subjects:
A549 Cells
Blood circulation
Cancer
Cell migration
Cell Separation - instrumentation
Cell Separation - methods
Cell size
circulating tumor cells
Dielectrophoresis
Electric field strength
Electric fields
Electric potential
Electrophoresis - instrumentation
Electrophoresis - methods
high separation distance
high‐throughput
Humans
inertial microfluidics
Lab-On-A-Chip Devices
label‐free separation
Leukocytes - cytology
Lung cancer
Microchannels
Microfluidic Analytical Techniques - instrumentation
Microfluidics
Neoplastic Cells, Circulating - pathology
Stage separation
Tumor cells
Voltage
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Summary:Reliable separation of circulating tumor cells from blood cells is crucial for early cancer diagnosis and prognosis. Many conventional microfluidic platforms take advantage of the size difference between particles for their separation, which renders them impractical for sorting overlapping‐sized cells. To address this concern, a hybrid inertial‐dielectrophoretic microfluidic chip is proposed in this work for continuous and single‐stage separation of lung cancer cell line A549 cells from white blood cells of overlapping size. The working mechanism of the proposed spiral microchannel embedded with planar interdigitated electrodes is validated against the experimental results. A numerical investigation is carried out over a range of flow conditions and electric field intensity to determine the separation efficiency and migration characteristics of the cell mixture. The results demonstrate the unique capability of the proposed microchannel to achieve high‐throughput separation of cells at low applied voltages in both vertical and lateral directions. A significant lateral separation distance between the CTCs and the WBCs has been achieved, which allows for high‐resolution and effective separation of cells. The separation resolution can be controlled by adjusting the strength of the applied electric field. Furthermore, the results demonstrate that the lateral separation distance is maximum at a voltage termed the critical voltage, which increases with the increase in the flow rate. The proposed microchannel and the developed technique can provide valuable insight into the development of a tunable and robust medical device for effective and high‐throughput separation of cancer cells from the WBCs.
ISSN:8756-7938
1520-6033
1520-6033
DOI:10.1002/btpr.3437