Real-time monitoring of skin wound healing on nano-grooves topography using electric cell-substrate impedance sensing (ECIS)

•The nano-grooves topography was fabricated with the dimensions of 75nm in depth and 200nm in width of grooves and ridges.•ECIS was first employed to monitoring skin wound healing process on nano-grooves.•The effect of nano-grooves was investigated for accelerating wound healing with reduced scar fo...

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Bibliographic Details
Published inSensors and actuators. B, Chemical Vol. 250; pp. 461 - 468
Main Authors Cui, Yao, An, Yu, Jin, Tongyu, Zhang, Fan, He, Pingang
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 01.10.2017
Elsevier Science Ltd
Subjects
Cell growth
Cell migration
Cell proliferation
Critical care
ECIS
Electric cells
Electrodes
Elongation
Grooves
Impedance
Monitoring
Morphology
Nano-grooves topography
Real time
Recovery
Scars
Skin
Skin wound healing
Statistical analysis
Substrates
Tissue engineering
Topography
Wound healing
Cell proliferation
ECIS
Nano-grooves topography
Skin wound healing
Cell migration
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Summary:•The nano-grooves topography was fabricated with the dimensions of 75nm in depth and 200nm in width of grooves and ridges.•ECIS was first employed to monitoring skin wound healing process on nano-grooves.•The effect of nano-grooves was investigated for accelerating wound healing with reduced scar formation.•Good linear correlations were established between impedance response and cell recovery degree/cell number.•Our work provides a useful approach for the clinical monitoring of skin wound healing in a real-time and label-free manner. Skin wound healing represents a critical medical topic. For its ideal case, the injured tissue can repair quickly without scars. In this paper, an ECIS device was developed using nano-grooves to simulate internal extracellular matrix (ECM) with 75nm in depth and 200nm in width of grooves and ridges. HFF and HaCaT cells were cultured but only HFF cells could orient along the nano-grooves. In the cell migration and proliferation occurred during the wound healing, HFF and HaCaT cells both presented increased normalized impedance (NI) values at the characteristic frequencies of 977Hz and 1465Hz, respectively. Compared to flat electrodes, nano-grooves electrodes generated less intense impedance signals in HFF cell migration and proliferation, and HaCaT cell migration, but more intense ones in HaCaT cell proliferation. Cell images were captured simultaneously and the statistical analysis demonstrated that the nano-grooves electrode could accelerate the migration while slow down the proliferation. After establishing the correlations between impedance response and cell behaviors, it could be found that the NI values increased all linearly the rising of recovery degree and cell number. Under the equal changes of recovery degree and cell number on nano-grooves, HFF cells produced the both declined impedance signals, because of the elongation, while, HaCaT cells created the same and deduced NI variation rates, due to the unchanged morphology and aggregation growth, respectively. Our work provides a useful approach for the clinical monitoring of skin wound healing in a real-time and label-free manner, potentially promoting the development of regenerative medicine.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2017.04.183