TY - GEN
T1 - A Microfluidic Chip for Testing the Migration Ability of SH-SY5Y Cells in Constricted Channels
AU - Liu, Menghua
AU - Wu, Anping
AU - Bai, Kailun
AU - Yan, Haotian
AU - Yang, Xi
AU - Shi, Qing
AU - Wang, Huaping
AU - Hou, Yaozhen
N1 - Publisher Copyright:
© 2024 Copyright held by the owner/author(s).
PY - 2025/1/18
Y1 - 2025/1/18
N2 - The 3D structure and microenvironmental morphology of the physical environment influence the migration pathways and modes of cancer cells, which is crucial for understanding cancer dissemination and metastasis mechanisms. However, existing microfluidic chip structures still face challenges in inducing directional migration of neuroblastoma cells along narrow tubular structures. This study introduces a microfluidic chip design featuring guidance channels and narrow drainage tubes to assess the migration capabilities of SH-SY5Y cells in narrow tubular environments. Specifically, SHSY5Y Cells Guidance Channels (SGCs) were designed and fabricated as functional zones to induce directional migration of cells, while two narrow drainage tubes were placed on either side to facilitate media drainage and alleviate channel blockages. By establishing directed flow from an initial chamber to a final chamber, cell migration along SGCs was induced. Experimental results demonstrate that the microfluidic chip with SGCs effectively evaluates cell migration in elongated tubular environments. Furthermore, increasing the initial cell density seeded into the chip significantly enhanced the number of cells undergoing directional migration.
AB - The 3D structure and microenvironmental morphology of the physical environment influence the migration pathways and modes of cancer cells, which is crucial for understanding cancer dissemination and metastasis mechanisms. However, existing microfluidic chip structures still face challenges in inducing directional migration of neuroblastoma cells along narrow tubular structures. This study introduces a microfluidic chip design featuring guidance channels and narrow drainage tubes to assess the migration capabilities of SH-SY5Y cells in narrow tubular environments. Specifically, SHSY5Y Cells Guidance Channels (SGCs) were designed and fabricated as functional zones to induce directional migration of cells, while two narrow drainage tubes were placed on either side to facilitate media drainage and alleviate channel blockages. By establishing directed flow from an initial chamber to a final chamber, cell migration along SGCs was induced. Experimental results demonstrate that the microfluidic chip with SGCs effectively evaluates cell migration in elongated tubular environments. Furthermore, increasing the initial cell density seeded into the chip significantly enhanced the number of cells undergoing directional migration.
KW - SH-SY5Y cell
KW - advanced manufacturing
KW - cell migration
KW - microchannel
KW - microfluidic chip
UR - http://www.scopus.com/pages/publications/85217852195
U2 - 10.1145/3704558.3707069
DO - 10.1145/3704558.3707069
M3 - Conference contribution
AN - SCOPUS:85217852195
T3 - CFIMA 2024 - Proceedings of 2024 2nd International Conference on Frontiers of Intelligent Manufacturing and Automation
SP - 379
EP - 384
BT - CFIMA 2024 - Proceedings of 2024 2nd International Conference on Frontiers of Intelligent Manufacturing and Automation
PB - Association for Computing Machinery, Inc
T2 - 2nd International Conference on Frontiers of Intelligent Manufacturing and Automation, CFIMA 2024
Y2 - 9 August 2024 through 11 August 2024
ER -
