A finite-element study of the effects of electrode position on the measured impedance change in impedance cardiography
Traditional impedance cardiography (ICG) technique uses band electrodes both for delivering current to and measuring impedance change in the thorax. The use of spot electrodes increases the ease of electrode placement and comfort level for patients. Research has shown that changes in thoracic impeda...
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| Published in | IEEE transactions on biomedical engineering Vol. 48; no. 12; pp. 1390 - 1401 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
New York, NY
IEEE
01.12.2001
Institute of Electrical and Electronics Engineers The Institute of Electrical and Electronics Engineers, Inc. (IEEE) |
| Subjects | |
| Online Access | Get full text |
| ISSN | 0018-9294 1558-2531 |
| DOI | 10.1109/10.966598 |
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| Abstract | Traditional impedance cardiography (ICG) technique uses band electrodes both for delivering current to and measuring impedance change in the thorax. The use of spot electrodes increases the ease of electrode placement and comfort level for patients. Research has shown that changes in thoracic impedance can have multiple causes. In this study, we used finite element modeling to investigate the sources of impedance change for both band-electrode and spot-electrode ICG, and focused on how differences in electrode location affect the contribution of different sources to changes in impedance. The ultimate purpose is to identify the optimal electrode type and placement for the sensing of stroke volume (SV). Our models were built on sets of end-diastolic and end-systolic magnetic resonance images of a healthy human subject. The results showed that the effect of ventricular contraction is opposite to that of the other changes in systole: the expansion of major vessels, decrease in blood resistivity due to increased blood flow velocity, and decrease in lung resistivity due to increased blood perfusion. Ventricular contraction, the only factor that tends to increase systolic impedance, has a larger effect than any of the other factors. When spot electrodes are placed on the anterior chest wall near the heart, ventricular contraction is so dominant that the measured impedance increases from end-diastole to end-systole, and the change represents 82% of the contribution from ventricular contraction. When using the common band-electrode configuration, the change in measured impedance is a more balanced combination of the four effects, and ventricular contraction is overcome by the other three factors so that the impedance decreases. These results suggest that the belief that ICG can be used to directly measure SV based on the change in the whole thoracic impedance may be invalid, and that spot electrodes may be more useful for understanding local physiological events such as ventricular volume change. These findings are supported by previously reported experimental observations. |
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| AbstractList | Traditional impedance cardiography (ICG) technique uses band electrodes both for delivering current to and measuring impedance change in the thorax. The use of spot electrodes increases the ease of electrode placement and comfort level for patients. Research has shown that changes in thoracic impedance can have multiple causes. In this study, we used finite element modeling to investigate the sources of impedance change for both band-electrode and spot-electrode ICG, and focused on how differences in electrode location affect the contribution of different sources to changes in impedance. The ultimate purpose is to identify the optimal electrode type and placement for the sensing of stroke volume (SV). Our models were built on sets of end-diastolic and end-systolic magnetic resonance images of a healthy human subject. The results showed that the effect of ventricular contraction is opposite to that of the other changes in systole: the expansion of major vessels, decrease in blood resistivity due to increased blood flow velocity, and decrease in lung resistivity due to increased blood perfusion. Ventricular contraction, the only factor that tends to increase systolic impedance, has a larger effect than any of the other factors. When spot electrodes are placed on the anterior chest wall near the heart, ventricular contraction is so dominant that the measured impedance increases from end-diastole to end-systole, and the change represents 82% of the contribution from ventricular contraction. When using the common band-electrode configuration, the change in measured impedance is a more balanced combination of the four effects, and ventricular contraction is overcome by the other three factors so that the impedance decreases. These results suggest that the belief that ICG can be used to directly measure SV based on the change in the whole thoracic impedance may be invalid, and that spot electrodes may be more useful for understanding local physiological events such as ventricular volume change. These findings are supported by previously reported experimental observations.Traditional impedance cardiography (ICG) technique uses band electrodes both for delivering current to and measuring impedance change in the thorax. The use of spot electrodes increases the ease of electrode placement and comfort level for patients. Research has shown that changes in thoracic impedance can have multiple causes. In this study, we used finite element modeling to investigate the sources of impedance change for both band-electrode and spot-electrode ICG, and focused on how differences in electrode location affect the contribution of different sources to changes in impedance. The ultimate purpose is to identify the optimal electrode type and placement for the sensing of stroke volume (SV). Our models were built on sets of end-diastolic and end-systolic magnetic resonance images of a healthy human subject. The results showed that the effect of ventricular contraction is opposite to that of the other changes in systole: the expansion of major vessels, decrease in blood resistivity due to increased blood flow velocity, and decrease in lung resistivity due to increased blood perfusion. Ventricular contraction, the only factor that tends to increase systolic impedance, has a larger effect than any of the other factors. When spot electrodes are placed on the anterior chest wall near the heart, ventricular contraction is so dominant that the measured impedance increases from end-diastole to end-systole, and the change represents 82% of the contribution from ventricular contraction. When using the common band-electrode configuration, the change in measured impedance is a more balanced combination of the four effects, and ventricular contraction is overcome by the other three factors so that the impedance decreases. These results suggest that the belief that ICG can be used to directly measure SV based on the change in the whole thoracic impedance may be invalid, and that spot electrodes may be more useful for understanding local physiological events such as ventricular volume change. These findings are supported by previously reported experimental observations. Traditional impedance cardiography (ICG) technique uses band electrodes both for delivering current to and measuring impedance change in the thorax. The use of spot electrodes increases the ease of electrode placement and comfort level for patients. Research has shown that changes in thoracic impedance can have multiple causes. In this study, we used finite element modeling to investigate the sources of impedance change for both band-electrode and spot-electrode ICG, and focused on how differences in electrode location affect the contribution of different sources to changes in impedance. The ultimate purpose is to identify the optimal electrode type and placement for the sensing of stroke volume (SV). Our models were built on sets of end-diastolic and end-systolic magnetic resonance images of a healthy human subject. The results showed that the effect of ventricular contraction is opposite to that of the other changes in systole: the expansion of major vessels, decrease in blood resistivity due to increased blood flow velocity, and decrease in lung resistivity due to increased blood perfusion. Ventricular contraction, the only factor that tends to increase systolic impedance, has a larger effect than any of the other factors. When spot electrodes are placed on the anterior chest wall near the heart, ventricular contraction is so dominant that the measured impedance increases from end-diastole to end-systole, and the change represents 82% of the contribution from ventricular contraction. When using the common band-electrode configuration, the change in measured impedance is a more balanced combination of the four effects, and ventricular contraction is overcome by the other three factors so that the impedance decreases. These results suggest that the belief that ICG can be used to directly measure SV based on the change in the whole thoracic impedance may be invalid, and that spot electrodes may be more useful for understanding local physiological events such as ventricular volume change. These findings are supported by previously reported experimental observations. The results showed that the effect of ventricular contraction is opposite to that of the other changes in systole: the expansion of major vessels, decrease in blood resistivity due to increased blood flow velocity, and decrease in lung resistivity due to increased blood perfusion. Traditional impedance cardiography (ICG) technique uses band electrodes both for delivering current to and measuring impedance change in the thorax. The use of spot electrodes increases the ease of electrode placement and comfort level for patients. Research has shown that changes in thoracic impedance can have multiple causes. In this study, we used finite element modeling to investigate the sources of impedance change for both band-electrode and spot-electrode ICG, and focused on how differences in electrode location affect the contribution of different sources to changes in impedance. The ultimate purpose is to identify the optimal electrode type and placement for the sensing of stroke volume (SV). Our models were built on sets of end-diastolic and end-systolic magnetic resonance images of a healthy human subject. The results showed that the effect of ventricular contraction is opposite to that of the other changes in systole: the expansion of major vessels, decrease in blood resistivity due to increased blood flow velocity, and decrease in lung resistivity due to increased blood perfusion. Ventricular contraction, the only factor that tends to increase systolic impedance, has a larger effect than any of the other factors. When spot electrodes are placed on the anterior chest wall near the heart, ventricular contraction is so dominant that the measured impedance increases from end-diastole to end-systole, and the change represents 82% of the contribution from ventricular contraction. When using the common band-electrode configuration, the change in measured impedance is a more balanced combination of the four effects, and ventricular contraction is overcome by the other three factors so that the impedance decreases. These results suggest that the belief that ICG can be used to directly measure SV based on the change in the whole thoracic impedance may be invalid, and that spot electrodes may be more useful for understanding local physiological events such as ventricular volume change. These findings are supported by previously reported experimental observations |
| Author | Kim, Y. Haynor, D.R. Wang, Y. |
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| Cites_doi | 10.1063/1.1744988 10.1161/01.cir.2.6.811 10.1016/S0147-9563(05)80036-6 10.1016/0020-7101(95)01146-3 10.1109/10.81557 10.1109/TBME.1986.325869 10.1007/BF02444019 10.1109/10.341826 10.1097/00003246-198610000-00017 10.1109/10.486292 10.1007/BF02368066 10.1111/j.1749-6632.1970.tb17735.x 10.1161/01.RES.4.6.664 10.3349/ymj.1989.30.1.1 10.1109/TBME.1986.325870 10.1109/10.310088 10.1007/BF02510508 10.1097/00004669-197807000-00017 10.1007/BF02474537 10.1097/00003246-199201000-00018 10.1109/10.8683 10.1097/00004669-197701000-00020 10.1007/BF02524429 10.1093/cvr/24.1.24 |
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| Keywords | Electrodes Human Finite element method Evaluation Correlation Position Measurement technique Circulatory system Impedance Modeling Cardiograph Electrical impedance |
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| References | ref13 ref12 ref15 ref14 ref31 ref30 ref10 ref2 Sramek (ref9) ref17 ref16 ref19 Adamicza (ref18) 1994; 82 Mohapatra (ref11) 1981 ref24 ref26 Miller (ref23) 1990; 18 ref25 ref20 ref22 Kubicek (ref32) 1974; 9 ref21 Berne (ref29) 1979; 1 Woodcock (ref3) 1974; 9 ref28 ref27 Kubicek (ref1) 1966; 37 ref8 ref7 ref4 ref6 ref5 |
| References_xml | – ident: ref27 doi: 10.1063/1.1744988 – ident: ref6 doi: 10.1161/01.cir.2.6.811 – volume-title: Non-Invasive Cardiovascular Monitoring by Electrical Impedance Technique year: 1981 ident: ref11 – ident: ref2 doi: 10.1016/S0147-9563(05)80036-6 – start-page: 38 volume-title: Proc. 6th Int. Conf. Electrical Bioimpedance ident: ref9 article-title: Stroke volume equation with a linear base impedance model and its accuracy, as compared to thermodilution and magnetic flowmeter techniques in humans and animals – ident: ref24 doi: 10.1016/0020-7101(95)01146-3 – volume: 37 start-page: 1208 year: 1966 ident: ref1 article-title: Development and evaluation of an impedance cardiac output system publication-title: Aerosp. Med. – ident: ref14 doi: 10.1109/10.81557 – ident: ref17 doi: 10.1109/TBME.1986.325869 – ident: ref15 doi: 10.1007/BF02444019 – ident: ref13 doi: 10.1109/10.341826 – ident: ref10 doi: 10.1097/00003246-198610000-00017 – ident: ref21 doi: 10.1109/10.486292 – ident: ref28 doi: 10.1007/BF02368066 – ident: ref7 doi: 10.1111/j.1749-6632.1970.tb17735.x – volume: 1 volume-title: Handbook of Physiology: The Cardiovascular System year: 1979 ident: ref29 – ident: ref26 doi: 10.1161/01.RES.4.6.664 – ident: ref8 doi: 10.3349/ymj.1989.30.1.1 – volume: 18 start-page: 207 year: 1990 ident: ref23 article-title: Finite element analysis of bioelectric phenomena publication-title: Crit. Rev. Biomed. Eng. – ident: ref16 doi: 10.1109/TBME.1986.325870 – volume: 82 start-page: 37 year: 1994 ident: ref18 article-title: The measurement of cardiac output in dogs by impedance cardiography with different electrode arrangements publication-title: Acta Physiologica Hungarica – ident: ref22 doi: 10.1109/10.310088 – volume: 9 start-page: 406 year: 1974 ident: ref3 article-title: Plethysmography publication-title: Biomed. Eng. – ident: ref19 doi: 10.1007/BF02510508 – ident: ref5 doi: 10.1097/00004669-197807000-00017 – ident: ref25 doi: 10.1007/BF02474537 – ident: ref30 doi: 10.1097/00003246-199201000-00018 – ident: ref12 doi: 10.1109/10.8683 – ident: ref4 doi: 10.1097/00004669-197701000-00020 – ident: ref20 doi: 10.1007/BF02524429 – volume: 9 start-page: 410 year: 1974 ident: ref32 article-title: The minnesota impedance cardiograph—theory and applications publication-title: Biomed. Eng. – ident: ref31 doi: 10.1093/cvr/24.1.24 |
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| Snippet | Traditional impedance cardiography (ICG) technique uses band electrodes both for delivering current to and measuring impedance change in the thorax. The use of... The results showed that the effect of ventricular contraction is opposite to that of the other changes in systole: the expansion of major vessels, decrease in... |
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| SubjectTerms | Adult Biological and medical sciences Blood Cardiography Cardiography, Impedance - instrumentation Conductivity Current measurement Electric Impedance Electrocardiography. Vectocardiography Electrodes Electrodiagnosis. Electric activity recording Finite element method Finite element methods Flow velocity Heart - physiology Humans Impedance Impedance measurement Investigative techniques, diagnostic techniques (general aspects) Magnetic resonance Magnetic resonance imaging Magnetic Resonance Imaging, Cine Male Mathematical models Medical sciences Models, Cardiovascular Myocardial Contraction - physiology Thorax |
| Title | A finite-element study of the effects of electrode position on the measured impedance change in impedance cardiography |
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