Calcium Selective Polymeric Membranes for Microfabricated Sensor Arrays

Abstract

The potentiometric and impedance characteristics of various selective Ca²⁺ polymeric membranes are described and interpreted by theory and experiments for Ca²⁺ microfabricated sensor arrays. These are designed for further biomedical applications with an emphasis on potential in situ applications. The polymeric materials used in the present studies consist of either carboxylated PVC or aliphatic polyurethane. Both materials showed good adherence properties to the polyimide-coated Kapton substrate used in planar sensor fabrication. The impedance analysis, performed in the frequency range from 65,000 Hz to 0.1 Hz, revealed the bulk geometrical response at high frequencies. Measured R_bulk corresponds to the unperturbed bulk resistance. That, in turn, depends on mobilities and concentrations of Ca²⁺ complex and mobile sites. Decreases in R_bulk correlated well with sensor behavior during the preconditioning (hydration) period. Studies of blood interactions with these sensors proved that the main sensor characteristics (E₀, slope of the calibration curve, and reproducibility of response) are not significantly affected after 14 days of whole blood contact.

∗On leave from Gallaudet University, Washington, DC

Key Words:

• calcium planar microchemical sensor arrays
• polymeric membranes
• impedance analysis
• blood interactions with sensor materials

Notes

∗On leave from Gallaudet University, Washington, DC