Title :
Cell Culture Imaging Using Microimpedance Tomography
Author :
Linderholm, Pontus ; Marescot, Laurent ; Loke, Meng Heng ; Renaud, Philippe
Author_Institution :
Lab. of Microsyst., Lausanne
Abstract :
We present a novel, inexpensive, and fast microimpedance tomography system for two-dimensional imaging of cell and tissue cultures. The system is based on four-electrode measurements using 16 planar microelectrodes (5 mum x 4 mm) integrated into a culture chamber. An Agilent 4294A impedance analyzer combined with a front-end amplifier is used for the impedance measurements. Two-dimensional images are obtained using a reconstruction algorithm. This system is capable of accurately resolving the shape and position of a human hair, yielding vertical cross sections of the object. Human epithelial stem cells (YF 29) are also grown directly on the device surface. Tissue growth can be followed over several days. A rapid resistivity decrease caused by permeabilized cell membranes is also monitored, suggesting that this technique can be used in electroporation studies.
Keywords :
biological tissues; biomedical measurement; biomembrane transport; cellular biophysics; electric impedance imaging; electric impedance measurement; image reconstruction; medical image processing; microelectrodes; tomography; Agilent 4294A impedance analyzer; cell culture imaging; electroporation studies; four-electrode measurements; front-end amplifier; human epithelial stem cells; human hair position; image reconstruction algorithm; impedance measurements; microimpedance tomography; permeabilized cell membranes; planar microelectrodes; tissue culture imaging; two-dimensional imaging; Conductivity; Hair; Humans; Impedance measurement; Microelectrodes; Reconstruction algorithms; Shape; Stem cells; Surface reconstruction; Tomography; Four-electrode measurements; high-throughput screening; impedance tomography; inversion; microelectrode array; resistivity tomography; Cell Culture Techniques; Cells, Cultured; Electric Impedance; Humans; Image Enhancement; Image Interpretation, Computer-Assisted; Tomography;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
DOI :
10.1109/TBME.2007.910649
