Enhanced Unidirectional Cell Migration Persistence Induced by Asymmetrical Micropatterns with Nanostructures

Kaixin Chen; Yuanhao Xu; Stella Pang

Enhanced Unidirectional Cell Migration Persistence Induced by Asymmetrical Micropatterns with Nanostructures

Kaixin Chen
, Yuanhao Xu
, Stella Pang^*

^*Corresponding author for this work

Research output: Conference Papers › RGC 33 - Other conference paper › peer-review

Abstract

This study demonstrates that asymmetrical micropatterns with nanopillars enhance persistent unidirectional cell migration. Analysis of cell migration dynamics and F-actin imaging revealed improved unidirectional control and cytoskeletal reorganization on arrowheads with nanopillars. This platform demonstrates the potential for applications in accelerating wound healing and mimicking tissue interfaces for biomedical devices.

Original language	English
Publication status	Presented - 30 May 2025
Event	68th International Conference on Electron, Ion, and Photon Beam Technology and Nanofabrication - Hyatt Regency Savannah, Savannah, Georgia Duration: 27 May 2025 → 30 May 2025 https://eipbn.org/

Conference

Conference	68th International Conference on Electron, Ion, and Photon Beam Technology and Nanofabrication
Abbreviated title	EIPBN 2025
Place	Georgia
City	Savannah
Period	27/05/25 → 30/05/25
Internet address	https://eipbn.org/

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Research Unit(s) information for this publication is provided by the author(s) concerned.

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title = "Enhanced Unidirectional Cell Migration Persistence Induced by Asymmetrical Micropatterns with Nanostructures",

abstract = "This study demonstrates that asymmetrical micropatterns with nanopillars enhance persistent unidirectional cell migration. Analysis of cell migration dynamics and F-actin imaging revealed improved unidirectional control and cytoskeletal reorganization on arrowheads with nanopillars. This platform demonstrates the potential for applications in accelerating wound healing and mimicking tissue interfaces for biomedical devices.",

author = "Kaixin Chen and Yuanhao Xu and Stella Pang",

note = "Research Unit(s) information for this publication is provided by the author(s) concerned. ; 68th International Conference on Electron, Ion, and Photon Beam Technology and Nanofabrication , EIPBN 2025 ; Conference date: 27-05-2025 Through 30-05-2025",

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TY - CONF

T1 - Enhanced Unidirectional Cell Migration Persistence Induced by Asymmetrical Micropatterns with Nanostructures

AU - Chen, Kaixin

AU - Xu, Yuanhao

AU - Pang, Stella

N1 - Research Unit(s) information for this publication is provided by the author(s) concerned.

PY - 2025/5/30

Y1 - 2025/5/30

N2 - This study demonstrates that asymmetrical micropatterns with nanopillars enhance persistent unidirectional cell migration. Analysis of cell migration dynamics and F-actin imaging revealed improved unidirectional control and cytoskeletal reorganization on arrowheads with nanopillars. This platform demonstrates the potential for applications in accelerating wound healing and mimicking tissue interfaces for biomedical devices.

AB - This study demonstrates that asymmetrical micropatterns with nanopillars enhance persistent unidirectional cell migration. Analysis of cell migration dynamics and F-actin imaging revealed improved unidirectional control and cytoskeletal reorganization on arrowheads with nanopillars. This platform demonstrates the potential for applications in accelerating wound healing and mimicking tissue interfaces for biomedical devices.

M3 - RGC 33 - Other conference paper

T2 - 68th International Conference on Electron, Ion, and Photon Beam Technology and Nanofabrication

Y2 - 27 May 2025 through 30 May 2025

ER -

Enhanced Unidirectional Cell Migration Persistence Induced by Asymmetrical Micropatterns with Nanostructures

Abstract

Conference

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