MEMS Dielectrophoresis Device for Osteoblast Cell Stimulation

H. Zou; R.R.A. Syms; S. Mellon; K.E. Tanner

doi:10.4028/www.scientific.net/AMR.60-61.63

Paper Titles

Design of a Hybrid-Type Electrostatically Driven Microgripper Integrated Vacuum Tool
p.40

A DC Voltage Driven Flow-Through Electroporation Microchip
p.44

Detection for Spring Constant of Microcantilevers in Atomic Force Microscopy Based on Frequency Measurements
p.49

Photochemical Synthesis of Gold Nanostructures in Different Solvents
p.57

MEMS Dielectrophoresis Device for Osteoblast Cell Stimulation
p.63

An Excellent Platinum Piezoresistive Pressure Sensor Using Adhesive Bonding with SU-8
p.68

A High-Efficiency Energy Storage Scheme of Solar Micro-Power Systems
p.74

Study on Excitation Voltage Effects of the Thermal Excitation Resonant Pressure Sensor
p.79

Gauge Factor and Nonlinearity of P-Type Polysilicon Nanofilms
p.84

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 60-61MEMS Dielectrophoresis Device for Osteoblast Cell...

MEMS Dielectrophoresis Device for Osteoblast Cell Stimulation

Abstract:

A fixed microelectrode device for cell stimulation has been designed and fabricated using micro-electromechanical systems (MEMS) technology. Dielectrophoretic forces obtained from non-uniform electric fields were used for manipulating and positioning osteoblasts. The experiments show that the osteoblasts experience positive dielectrophoresis (p-DEP) when suspended in iso-osmotic culture medium and exposed to AC fields at 5 MHz frequency. This work will help to investigate the mechanisms underlying Wolff’s law of bone growth dynamics at the cellular level. The methods used can also be developed to control osteoblast metabolism and ultimately enhance bone repair processes.