Journal
IEEE TRANSACTIONS ON BIOMEDICAL ENGINEERING
Volume 69, Issue 5, Pages 1674-1684Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TBME.2021.3126849
Keywords
Impedance; Electrodes; Biomedical optical imaging; Standards; Optical recording; Impedance measurement; Biomedical measurement; Biopotentials; impedance properties; interfaces; liquid crystals; micro electrode arrays; optrode; recording sites; signal quality
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Funding
- Australian Research Council [DP160104625, DP200102825]
- US Office of Naval Research Global [N62909-18-1-2147]
- Australian National Health and Medical Research Council [2002282]
- Australian Research Council [DP200102825] Funding Source: Australian Research Council
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This study investigates the impedance properties of optrode technology for biopotential recording. The results show that the liquid crystals in the optrode platform have higher input impedance values suitable for voltage sensing. The optrode system automatically scales the input impedance to maintain a relatively constant ratio, allowing for high spatial-resolution recordings regardless of the size of the recording site.
Recording and monitoring electrically-excitable cells is critical to understanding the complex cellular networking within organs as well as the processes underlying many electro-physiological pathologies. Biopotential recording using an optical-electrode (optrode) is a novel approach which has potential to significantly improve interface-instrumentation impedance mismatching as recording contact-sizes become smaller and smaller. Optrodes incorporate a conductive interface that can sense extracellular potential and an underlying layer of liquid crystals that passively transduces electrical signals into measurable optical signals. This study investigates the impedance properties of this optical technology by varying the diameter of recording sites and observing the corresponding changes in the impedance values. The results show that the liquid crystals in this optrode platform exhibit input impedance values (1 M omega - 100 G omega) that are three orders of magnitude higher than the corresponding interface impedance, which is appropriate for voltage sensing. The automatic scaling of the input impedance enabled within the optrode system maintains a relatively constant ratio between input and total system impedance of about one for sensing areas with diameters ranging from 40 mu m to 1 mm, at which the calculated signal loss is predicted to be <1%. This feature preserves the interface-transducer impedance ratio, regardless of the size of the recording site, allowing development of passive optrode arrays capable of very high spatial-resolution recordings.
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