BACKGROUND: The purpose of this study is to report the effect of different media osmolarity on a cell line monolayer of normal human conjunctival epithelia (IOBA-NHC) using Electric Cell-substrate Impedance Sensing (ECIS). METHODS: We built our own ECIS system. We fabricated biocompatible microelectrodes. We used a monolayer of IOBA-NHC cells with media at different osmolarities (315, 360, 446, and 617 mOsm/l). RESULTS: When there is an increase in hyperosmolarity, there is a slight decrease in the measured resistance of the naked microelectrode (without cells), whereas its capacitance remained practically unchanged. The evaluation of resistance and capacitance of a microelectrode covered by a monolayer of IOBA-NHC in relation to a naked microelectrode showed no difference in the standard media (315 mOsm/l), a small difference with 360 mOsm/l, and significant differences with hyperosmolarities of 446 mOsm/l and 610 mOsm/l. The resistance with a confluent cell monolayer is up to three times greater compared to the value of the resistance of the naked electrode with standard media. CONCLUSIONS: Both resistance and capacitance measurements for the cell monolayer were sensitive to changes in osmolarity.
BACKGROUND: The purpose of this study is to report the effect of different media osmolarity on a cell line monolayer of normal humanconjunctival epithelia (IOBA-NHC) using Electric Cell-substrate Impedance Sensing (ECIS). METHODS: We built our own ECIS system. We fabricated biocompatible microelectrodes. We used a monolayer of IOBA-NHC cells with media at different osmolarities (315, 360, 446, and 617 mOsm/l). RESULTS: When there is an increase in hyperosmolarity, there is a slight decrease in the measured resistance of the naked microelectrode (without cells), whereas its capacitance remained practically unchanged. The evaluation of resistance and capacitance of a microelectrode covered by a monolayer of IOBA-NHC in relation to a naked microelectrode showed no difference in the standard media (315 mOsm/l), a small difference with 360 mOsm/l, and significant differences with hyperosmolarities of 446 mOsm/l and 610 mOsm/l. The resistance with a confluent cell monolayer is up to three times greater compared to the value of the resistance of the naked electrode with standard media. CONCLUSIONS: Both resistance and capacitance measurements for the cell monolayer were sensitive to changes in osmolarity.
Authors: Ee-Munn Chia; Paul Mitchell; Elena Rochtchina; Anne J Lee; Rita Maroun; Jie Jin Wang Journal: Clin Exp Ophthalmol Date: 2003-06 Impact factor: 4.207
Authors: Yeoun Hee Kim; In Jun Yang; Ly Thi Huong Nguyen; Sang Il Gum; Sung Yu; Gwang Ja Lee; Bo Ae Kim; Jae Chang Jung; Young Jeung Park Journal: Korean J Ophthalmol Date: 2020-02