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Effect of monophasic pulsed stimulation on live single cell de-adhesion on conducting polymers with adsorbed fibronectin as revealed by single cell force spectroscopy

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posted on 2024-11-16, 04:00 authored by Hongrui Zhang, Gordon WallaceGordon Wallace, Michael HigginsMichael Higgins
The force required to detach a single fibroblast cell in contact with the conducting polymer, polypyrrole doped with dodecylbenzene, was quantified using the Atomic Force Microscope-based technique, Single Cell Force Spectroscopy. The de-adhesion force for a single cell was 0.64 ± 0.03 nN and predominately due to unbinding of α5β1 integrin complexes with surface adsorbed fibronectin, as confirmed by blocking experiments using antibodies. Monophasic pulsed stimulation (50 μs pulse duration) superimposed on either an applied oxidation (+500) or reduction (−500 mV) constant voltage caused a significant decrease in the de-adhesion force by 30%-45% to values ranging from 0.34 to 0.43 nN (±0.02 nN). The electrical stimulation caused a reduction in the molecular-level jump and plateau interactions, while an opposing increase in nonspecific interactions was observed during the cell de-adhesion process. Due to the monophasic pulsed stimulation, there is an apparent change or weakening of the cell membrane properties, which is suggested to play a role in reducing the cell de-adhesion. Based on this study, pulsed stimulation with optimized threshold parameters represents a possible approach to tune cell interactions and adhesion on conducting polymers.

Funding

Synergistic nanostimulation of nerve cells using atomic force microscopy technology

Australian Research Council

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ARC Centre of Excellence for Electromaterials Science

Australian Research Council

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History

Citation

Zhang, H., Wallace, G. G. & Higgins, M. J. (2019). Effect of monophasic pulsed stimulation on live single cell de-adhesion on conducting polymers with adsorbed fibronectin as revealed by single cell force spectroscopy. Biointerphases: an open access journal for the biomaterials interface community, 14 (2), 021003-1-021003-11.

Journal title

Biointerphases

Volume

14

Issue

2

Language

English

RIS ID

134677

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