Towards Low Energy Atrial Defibrillation

A wireless powered implantable atrial defibrillator consisting of a battery driven hand-held radio frequency (RF) power transmitter (ex vivo) and a passive (battery free) implantable power receiver (in vivo) that enables measurement of the intracardiac impedance (ICI) during internal atrial defibril...

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Main Authors: Philip Walsh, Vivek Kodoth, David McEneaney, Paola Rodrigues, Jose Velasquez, Niall Waterman, Omar Escalona
Format: Article
Language:English
Published: MDPI AG 2015-09-01
Series:Sensors
Subjects:
RF
Online Access:http://www.mdpi.com/1424-8220/15/9/22378
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spelling doaj-63376a93003345aca1317e02b51998b32020-11-24T22:50:02ZengMDPI AGSensors1424-82202015-09-01159223782240010.3390/s150922378s150922378Towards Low Energy Atrial DefibrillationPhilip Walsh0Vivek Kodoth1David McEneaney2Paola Rodrigues3Jose Velasquez4Niall Waterman5Omar Escalona6Centre for Advanced Cardiovascular Research, Ulster University, BT37 0QB, UKThe Heart Centre, Royal Victoria Hospital, Belfast, BT12 6BA, UKCraigavon Area Hospital, Craigavon, BT63 5QQ, UKCentre for Advanced Cardiovascular Research, Ulster University, BT37 0QB, UKCentre for Advanced Cardiovascular Research, Ulster University, BT37 0QB, UKCentre for Advanced Cardiovascular Research, Ulster University, BT37 0QB, UKCentre for Advanced Cardiovascular Research, Ulster University, BT37 0QB, UKA wireless powered implantable atrial defibrillator consisting of a battery driven hand-held radio frequency (RF) power transmitter (ex vivo) and a passive (battery free) implantable power receiver (in vivo) that enables measurement of the intracardiac impedance (ICI) during internal atrial defibrillation is reported. The architecture is designed to operate in two modes: Cardiac sense mode (power-up, measure the impedance of the cardiac substrate and communicate data to the ex vivo power transmitter) and cardiac shock mode (delivery of a synchronised very low tilt rectilinear electrical shock waveform). An initial prototype was implemented and tested. In low-power (sense) mode, >5 W was delivered across a 2.5 cm air-skin gap to facilitate measurement of the impedance of the cardiac substrate. In high-power (shock) mode, >180 W (delivered as a 12 ms monophasic very-low-tilt-rectilinear (M-VLTR) or as a 12 ms biphasic very-low-tilt-rectilinear (B-VLTR) chronosymmetric (6ms/6ms) amplitude asymmetric (negative phase at 50% magnitude) shock was reliably and repeatedly delivered across the same interface; with >47% DC-to-DC (direct current to direct current) power transfer efficiency at a switching frequency of 185 kHz achieved. In an initial trial of the RF architecture developed, 30 patients with AF were randomised to therapy with an RF generated M-VLTR or B-VLTR shock using a step-up voltage protocol (50–300 V). Mean energy for successful cardioversion was 8.51 J ± 3.16 J. Subsequent analysis revealed that all patients who cardioverted exhibited a significant decrease in ICI between the first and third shocks (5.00 Ω (SD(σ) = 1.62 Ω), p < 0.01) while spectral analysis across frequency also revealed a significant variation in the impedance-amplitude-spectrum-area (IAMSA) within the same patient group (|∆(IAMSAS1-IAMSAS3)[1 Hz − 20 kHz] = 20.82 Ω-Hz (SD(σ) = 10.77 Ω-Hz), p < 0.01); both trends being absent in all patients that failed to cardiovert. Efficient transcutaneous power transfer and sensing of ICI during cardioversion are evidenced as key to the advancement of low-energy atrial defibrillation.http://www.mdpi.com/1424-8220/15/9/22378wirelessbattery-freeimplantableimpedanceRFdefibrillator
collection DOAJ
language English
format Article
sources DOAJ
author Philip Walsh
Vivek Kodoth
David McEneaney
Paola Rodrigues
Jose Velasquez
Niall Waterman
Omar Escalona
spellingShingle Philip Walsh
Vivek Kodoth
David McEneaney
Paola Rodrigues
Jose Velasquez
Niall Waterman
Omar Escalona
Towards Low Energy Atrial Defibrillation
Sensors
wireless
battery-free
implantable
impedance
RF
defibrillator
author_facet Philip Walsh
Vivek Kodoth
David McEneaney
Paola Rodrigues
Jose Velasquez
Niall Waterman
Omar Escalona
author_sort Philip Walsh
title Towards Low Energy Atrial Defibrillation
title_short Towards Low Energy Atrial Defibrillation
title_full Towards Low Energy Atrial Defibrillation
title_fullStr Towards Low Energy Atrial Defibrillation
title_full_unstemmed Towards Low Energy Atrial Defibrillation
title_sort towards low energy atrial defibrillation
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2015-09-01
description A wireless powered implantable atrial defibrillator consisting of a battery driven hand-held radio frequency (RF) power transmitter (ex vivo) and a passive (battery free) implantable power receiver (in vivo) that enables measurement of the intracardiac impedance (ICI) during internal atrial defibrillation is reported. The architecture is designed to operate in two modes: Cardiac sense mode (power-up, measure the impedance of the cardiac substrate and communicate data to the ex vivo power transmitter) and cardiac shock mode (delivery of a synchronised very low tilt rectilinear electrical shock waveform). An initial prototype was implemented and tested. In low-power (sense) mode, >5 W was delivered across a 2.5 cm air-skin gap to facilitate measurement of the impedance of the cardiac substrate. In high-power (shock) mode, >180 W (delivered as a 12 ms monophasic very-low-tilt-rectilinear (M-VLTR) or as a 12 ms biphasic very-low-tilt-rectilinear (B-VLTR) chronosymmetric (6ms/6ms) amplitude asymmetric (negative phase at 50% magnitude) shock was reliably and repeatedly delivered across the same interface; with >47% DC-to-DC (direct current to direct current) power transfer efficiency at a switching frequency of 185 kHz achieved. In an initial trial of the RF architecture developed, 30 patients with AF were randomised to therapy with an RF generated M-VLTR or B-VLTR shock using a step-up voltage protocol (50–300 V). Mean energy for successful cardioversion was 8.51 J ± 3.16 J. Subsequent analysis revealed that all patients who cardioverted exhibited a significant decrease in ICI between the first and third shocks (5.00 Ω (SD(σ) = 1.62 Ω), p < 0.01) while spectral analysis across frequency also revealed a significant variation in the impedance-amplitude-spectrum-area (IAMSA) within the same patient group (|∆(IAMSAS1-IAMSAS3)[1 Hz − 20 kHz] = 20.82 Ω-Hz (SD(σ) = 10.77 Ω-Hz), p < 0.01); both trends being absent in all patients that failed to cardiovert. Efficient transcutaneous power transfer and sensing of ICI during cardioversion are evidenced as key to the advancement of low-energy atrial defibrillation.
topic wireless
battery-free
implantable
impedance
RF
defibrillator
url http://www.mdpi.com/1424-8220/15/9/22378
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