Enhanced cell viability and cell adhesion using low conductivity medium for negative dielectrophoretic cell patterning

Negative dielectrophoretic (n‐DEP) cell manipulation is an efficient way to pattern human liver cells on micro‐electrode arrays. Maintaining cell viability is an important objective for this approach. This study investigates the effect of low conductivity medium and the optimally designed microchip...

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Bibliographic Details
Published in:Biotechnology journal 2010-10, Vol.5 (10), p.1005-1015
Main Authors: Puttaswamy, Srinivasu Valagerahally, Sivashankar, Shilpa, Chen, Rong-Jhe, Chin, Chung-Kuang, Chang, Hwan-You, Liu, Cheng Hsien
Format: Article
Language:English
Subjects:
Cell adhesion
Cell Adhesion - physiology
Cell patterning
Cell Survival - physiology
Electrodes
Electrophoresis, Microchip - methods
Hep G2 Cells
Humans
Hydrogen-Ion Concentration
Isotonic Solutions
Medium conductivity
Negative dielectrophoresis
Osmolar Concentration
Osmolarity
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Summary:Negative dielectrophoretic (n‐DEP) cell manipulation is an efficient way to pattern human liver cells on micro‐electrode arrays. Maintaining cell viability is an important objective for this approach. This study investigates the effect of low conductivity medium and the optimally designed microchip on cell viability and cell adhesion. To explore the influence of conductivity on cell viability and cell adhesion, we have used earlier reported dielectrophoresis (DEP) buffer with a conductivity of 10.2 mS/m and three formulated media with conductivity of 9.02 (M1), 8.14 (M2), 9.55 (M3) mS/m. The earlier reported isotonic sucrose/dextrose buffer (DEP buffer) used for DEP manipulation has the drawback of poor cell adhesion and cell viability. A microchip prototype with well‐defined positioning of titanium electrode arrays was designed and fabricated on a glass substrate. The gap between the radial electrodes was accurately determined to achieve good cell patterning performance. Parameters such as dimension of positioning electrode, amplitude, and frequency of voltage signal were investigated to optimize the performance of the microchip.
ISSN:1860-6768
1860-7314
1860-7314
DOI:10.1002/biot.201000194