A new floating sensor array to detect electric near fields of beating heart preparations
A new flexible sensor for in vitro experiments was developed to measure the surface potential, Φ, and its gradient, E (electric near field), at given sites of the heart. During depolarisation, E describes a vector loop from which direction and magnitude of local conduction velocity θ can be computed...
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| Veröffentlicht in: | Biosensors & bioelectronics Jg. 21; H. 12; S. 2232 - 2239 |
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| Sprache: | Englisch |
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Lausanne
Elsevier B.V
15.06.2006
Elsevier Science |
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| ISSN: | 0956-5663, 1873-4235 |
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| Abstract | A new flexible sensor for in vitro experiments was developed to measure the surface potential,
Φ, and its gradient,
E (electric near field), at given sites of the heart. During depolarisation,
E describes a vector loop from which direction and magnitude of local conduction velocity
θ can be computed. Four recording silver electrodes (14
μm
×
14
μm) separated by 50
μm, conducting leads, and solderable pads were patterned on a 50
μm thick polyimide film. The conductive structures, except the electrodes, were isolated with polyimide, and electrodes were chlorided. Spacer pillars mounted on the tip fulfil two functions: they keep the electrodes 70
μm from the tissue allowing non-contact recording of
Φ and prevent lateral slipping. The low mass (9.1
mg) and flexibility (6.33
N/m) of the sensor let it easily follow the movement of the beating heart without notable displacement. We examined the electrodes on criteria like rms-noise of
Φ, signal-to-noise ratio of
Φ and
E, maximum peak-slope recording d
Φ/d
t, and deviation of local activation time (LAT) from a common signal and obtained values of 24–28
μV, 46 and 41
dB, 497–561
V/s and no differences, respectively. With appropriate data acquisition (sampling rate 100
kHz, 24-bit), we were able to record
Φ and to monitor
E and
θ on-line from beat-to-beat even at heart rates of 600
beats/min. Moreover, this technique can discriminate between uncoupled cardiac activations (as occur in fibrotic tissue) separated by less than 1
mm and 1
ms. |
|---|---|
| AbstractList | A new flexible sensor for in vitro experiments was developed to measure the surface potential, Phi, and its gradient, E (electric near field), at given sites of the heart. During depolarisation, E describes a vector loop from which direction and magnitude of local conduction velocity theta can be computed. Four recording silver electrodes (14 microm x 14 microm) separated by 50 microm, conducting leads, and solderable pads were patterned on a 50 microm thick polyimide film. The conductive structures, except the electrodes, were isolated with polyimide, and electrodes were chlorided. Spacer pillars mounted on the tip fulfil two functions: they keep the electrodes 70 microm from the tissue allowing non-contact recording of Phi and prevent lateral slipping. The low mass (9.1 mg) and flexibility (6.33 N/m) of the sensor let it easily follow the movement of the beating heart without notable displacement. We examined the electrodes on criteria like rms-noise of Phi, signal-to-noise ratio of Phi and E, maximum peak-slope recording dPhi/dt, and deviation of local activation time (LAT) from a common signal and obtained values of 24-28 microV, 46 and 41 dB, 497-561 V/s and no differences, respectively. With appropriate data acquisition (sampling rate 100 kHz, 24-bit), we were able to record Phi and to monitor E and theta on-line from beat-to-beat even at heart rates of 600 beats/min. Moreover, this technique can discriminate between uncoupled cardiac activations (as occur in fibrotic tissue) separated by less than 1 mm and 1 ms.A new flexible sensor for in vitro experiments was developed to measure the surface potential, Phi, and its gradient, E (electric near field), at given sites of the heart. During depolarisation, E describes a vector loop from which direction and magnitude of local conduction velocity theta can be computed. Four recording silver electrodes (14 microm x 14 microm) separated by 50 microm, conducting leads, and solderable pads were patterned on a 50 microm thick polyimide film. The conductive structures, except the electrodes, were isolated with polyimide, and electrodes were chlorided. Spacer pillars mounted on the tip fulfil two functions: they keep the electrodes 70 microm from the tissue allowing non-contact recording of Phi and prevent lateral slipping. The low mass (9.1 mg) and flexibility (6.33 N/m) of the sensor let it easily follow the movement of the beating heart without notable displacement. We examined the electrodes on criteria like rms-noise of Phi, signal-to-noise ratio of Phi and E, maximum peak-slope recording dPhi/dt, and deviation of local activation time (LAT) from a common signal and obtained values of 24-28 microV, 46 and 41 dB, 497-561 V/s and no differences, respectively. With appropriate data acquisition (sampling rate 100 kHz, 24-bit), we were able to record Phi and to monitor E and theta on-line from beat-to-beat even at heart rates of 600 beats/min. Moreover, this technique can discriminate between uncoupled cardiac activations (as occur in fibrotic tissue) separated by less than 1 mm and 1 ms. A new flexible sensor for in vitro experiments was developed to measure the surface potential, Phi, and its gradient, E (electric near field), at given sites of the heart. During depolarisation, E describes a vector loop from which direction and magnitude of local conduction velocity theta can be computed. Four recording silver electrodes (14 microm x 14 microm) separated by 50 microm, conducting leads, and solderable pads were patterned on a 50 microm thick polyimide film. The conductive structures, except the electrodes, were isolated with polyimide, and electrodes were chlorided. Spacer pillars mounted on the tip fulfil two functions: they keep the electrodes 70 microm from the tissue allowing non-contact recording of Phi and prevent lateral slipping. The low mass (9.1 mg) and flexibility (6.33 N/m) of the sensor let it easily follow the movement of the beating heart without notable displacement. We examined the electrodes on criteria like rms-noise of Phi, signal-to-noise ratio of Phi and E, maximum peak-slope recording dPhi/dt, and deviation of local activation time (LAT) from a common signal and obtained values of 24-28 microV, 46 and 41 dB, 497-561 V/s and no differences, respectively. With appropriate data acquisition (sampling rate 100 kHz, 24-bit), we were able to record Phi and to monitor E and theta on-line from beat-to-beat even at heart rates of 600 beats/min. Moreover, this technique can discriminate between uncoupled cardiac activations (as occur in fibrotic tissue) separated by less than 1 mm and 1 ms. A new flexible sensor for in vitro experiments was developed to measure the surface potential, [Phi], and its gradient, E (electric near field), at given sites of the heart. During depolarisation, E describes a vector loop from which direction and magnitude of local conduction velocity [theta] can be computed. Four recording silver electrodes (14 mu m x 14 mu m) separated by 50 mu m, conducting leads, and solderable pads were patterned on a 50 mu m thick polyimide film. The conductive structures, except the electrodes, were isolated with polyimide, and electrodes were chlorided. Spacer pillars mounted on the tip fulfil two functions: they keep the electrodes 70 mu m from the tissue allowing non-contact recording of [Phi] and prevent lateral slipping. The low mass (9.1 mg) and flexibility (6.33 N/m) of the sensor let it easily follow the movement of the beating heart without notable displacement. We examined the electrodes on criteria like rms-noise of [Phi], signal-to-noise ratio of [Phi] and E, maximum peak-slope recording d[Phi]/dt, and deviation of local activation time (LAT) from a common signal and obtained values of 24-28 mu V, 46 and 41 dB, 497-561 V/s and no differences, respectively. With appropriate data acquisition (sampling rate 100 kHz, 24-bit), we were able to record [Phi] and to monitor E and [theta] on-line from beat-to-beat even at heart rates of 600 beats/min. Moreover, this technique can discriminate between uncoupled cardiac activations (as occur in fibrotic tissue) separated by less than 1 mm and 1 ms. A new flexible sensor for in vitro experiments was developed to measure the surface potential, Φ, and its gradient, E (electric near field), at given sites of the heart. During depolarisation, E describes a vector loop from which direction and magnitude of local conduction velocity θ can be computed. Four recording silver electrodes (14 μm × 14 μm) separated by 50 μm, conducting leads, and solderable pads were patterned on a 50 μm thick polyimide film. The conductive structures, except the electrodes, were isolated with polyimide, and electrodes were chlorided. Spacer pillars mounted on the tip fulfil two functions: they keep the electrodes 70 μm from the tissue allowing non-contact recording of Φ and prevent lateral slipping. The low mass (9.1 mg) and flexibility (6.33 N/m) of the sensor let it easily follow the movement of the beating heart without notable displacement. We examined the electrodes on criteria like rms-noise of Φ, signal-to-noise ratio of Φ and E, maximum peak-slope recording d Φ/d t, and deviation of local activation time (LAT) from a common signal and obtained values of 24–28 μV, 46 and 41 dB, 497–561 V/s and no differences, respectively. With appropriate data acquisition (sampling rate 100 kHz, 24-bit), we were able to record Φ and to monitor E and θ on-line from beat-to-beat even at heart rates of 600 beats/min. Moreover, this technique can discriminate between uncoupled cardiac activations (as occur in fibrotic tissue) separated by less than 1 mm and 1 ms. |
| Author | Climent, V. Sanchez-Quintana, D. Plank, G. Thurner, T. Hofer, E. Keplinger, F. Wiener, T. |
| Author_xml | – sequence: 1 givenname: E. surname: Hofer fullname: Hofer, E. email: ernst.hofer@meduni-graz.at organization: Institute of Biophysics, Center for Physiological Medicine, Medical University of Graz, Graz, Austria – sequence: 2 givenname: F. surname: Keplinger fullname: Keplinger, F. organization: Institute of Industrial Electronics and Material Science, University of Technology, Vienna, Austria – sequence: 3 givenname: T. surname: Thurner fullname: Thurner, T. organization: Institute of Electrical Measurement and Measurement Signal Processing, University of Technology, Graz, Austria – sequence: 4 givenname: T. surname: Wiener fullname: Wiener, T. organization: Institute of Electrical Measurement and Measurement Signal Processing, University of Technology, Graz, Austria – sequence: 5 givenname: D. surname: Sanchez-Quintana fullname: Sanchez-Quintana, D. organization: Department of Human Anatomy, Faculty of Medicine, University of Extremadura, Badajoz, Spain – sequence: 6 givenname: V. surname: Climent fullname: Climent, V. organization: Department of Human Anatomy, Faculty of Medicine, University of Extremadura, Badajoz, Spain – sequence: 7 givenname: G. surname: Plank fullname: Plank, G. organization: Institute of Biophysics, Center for Physiological Medicine, Medical University of Graz, Graz, Austria |
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| CitedBy_id | crossref_primary_10_1007_s10916_015_0409_x crossref_primary_10_1007_s11517_012_0880_1 crossref_primary_10_1016_j_compbiomed_2021_104214 crossref_primary_10_1515_bmt_2010_705 crossref_primary_10_1016_j_mee_2013_03_035 crossref_primary_10_1109_TBME_2007_912401 crossref_primary_10_1007_s10877_014_9597_z crossref_primary_10_1109_TBME_2013_2256359 crossref_primary_10_3389_fphys_2018_00546 crossref_primary_10_1109_TBME_2010_2055056 |
| Cites_doi | 10.1114/1.1320841 10.1114/1.1615573 10.1088/0960-1317/13/3/304 10.1114/1.1603258 10.1161/01.CIR.74.3.603 10.1161/01.RES.58.3.356 10.1016/j.bios.2003.10.011 10.1161/01.RES.0000130529.18016.35 10.1152/ajpheart.2000.279.1.H437 10.1161/01.RES.72.2.424 10.1161/01.RES.71.4.840 10.1109/10.125012 10.1161/01.RES.71.5.1254 10.1136/hrt.2003.011650 |
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| Keywords | High-density electrode array Conduction velocity Micro mapping Near field Heart Electrodes Array Electric field Measurement sensor Sensor array In vitro |
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Φ, and its gradient,
E (electric near field), at given sites of... A new flexible sensor for in vitro experiments was developed to measure the surface potential, Phi, and its gradient, E (electric near field), at given sites... A new flexible sensor for in vitro experiments was developed to measure the surface potential, [Phi], and its gradient, E (electric near field), at given sites... |
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| SubjectTerms | Animals Biological and medical sciences Biotechnology Body Surface Potential Mapping - instrumentation Body Surface Potential Mapping - methods Conduction velocity Electrodes, Implanted Electromagnetic Fields Equipment Design Equipment Failure Analysis Fundamental and applied biological sciences. Psychology Guinea Pigs Heart Conduction System - physiology Heart Rate - physiology High-density electrode array In Vitro Techniques Methods. Procedures. Technologies Mice Micro mapping Microelectrodes Others Transducers Various methods and equipments |
| Title | A new floating sensor array to detect electric near fields of beating heart preparations |
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