Biomedical sensor using thick film technology for transcutaneous oxygen measurement
Biomedical sensor using thick film technology for transcutaneous oxygen measurement
Transcutaneous blood gas monitoring is a non-invasive measurement technique for obtaining fast and relatively accurate responses to determine the respiratory conditions of patients. In this investigation, a screen-printed, disposable, transcutaneous oxygen sensor based on the working principle of amperometry, incorporates an integral heating element to enhance transcutaneous diffusion of blood gases typically at 44 °C. A Clark cell configuration is employed with gold working and counter electrodes and a silver/silver chloride reference electrode. Two different types of electrolytes namely potassium nitrate gel and polyelectrolyte (Nafion®) have been studied under laboratory test conditions. A fully computer-controlled gas testing rig has been constructed to automate the varying of oxygen levels. Linear relationships have been established with an averaged sensitivity level of 0.029 ?A/mmHg. In addition, a brief pilot clinical trial involving a fully grown human subject has been carried out alongside a commercial transcutaneous blood gas analyser. The investigations have shown that although the measured signals are weaker than those obtained from the laboratory test, the thick film sensor displays a repeatable and linear relationship when correlating with the commercial system. This study has greatly contributed towards the understanding for the suitability of the materials in achieving a viable, low-cost biomedical sensor.
291-297
Lam, Liza
3ed9cea5-c4eb-4961-8d63-4118cde3a33a
Atkinson, John
5e9729b2-0e1f-400d-a889-c74f6390ea58
2007
Lam, Liza
3ed9cea5-c4eb-4961-8d63-4118cde3a33a
Atkinson, John
5e9729b2-0e1f-400d-a889-c74f6390ea58
Lam, Liza and Atkinson, John
(2007)
Biomedical sensor using thick film technology for transcutaneous oxygen measurement.
Medical Engineering & Physics, 29 (3), .
(doi:10.1016/j.medengphy.2006.03.010).
Abstract
Transcutaneous blood gas monitoring is a non-invasive measurement technique for obtaining fast and relatively accurate responses to determine the respiratory conditions of patients. In this investigation, a screen-printed, disposable, transcutaneous oxygen sensor based on the working principle of amperometry, incorporates an integral heating element to enhance transcutaneous diffusion of blood gases typically at 44 °C. A Clark cell configuration is employed with gold working and counter electrodes and a silver/silver chloride reference electrode. Two different types of electrolytes namely potassium nitrate gel and polyelectrolyte (Nafion®) have been studied under laboratory test conditions. A fully computer-controlled gas testing rig has been constructed to automate the varying of oxygen levels. Linear relationships have been established with an averaged sensitivity level of 0.029 ?A/mmHg. In addition, a brief pilot clinical trial involving a fully grown human subject has been carried out alongside a commercial transcutaneous blood gas analyser. The investigations have shown that although the measured signals are weaker than those obtained from the laboratory test, the thick film sensor displays a repeatable and linear relationship when correlating with the commercial system. This study has greatly contributed towards the understanding for the suitability of the materials in achieving a viable, low-cost biomedical sensor.
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Submitted date: 18 November 2005
Published date: 2007
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Local EPrints ID: 43836
URI: http://eprints.soton.ac.uk/id/eprint/43836
ISSN: 1350-4533
PURE UUID: 32ab2f47-dd4c-44b9-b75f-653da0cd575c
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Date deposited: 02 Feb 2007
Last modified: 16 Mar 2024 02:32
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Author:
Liza Lam
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