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Elucidating the mechanisms of microbubble formation in intracardiac pulsed field ablation
ID Mahnič-Kalamiza, Samo (Author), ID Miklavčič, Damijan (Author), ID Lombergar, Peter (Author), ID Mikuž, Blaž (Author), ID Mattison, Lars M. (Author), ID Sigg, Daniel C. (Author), ID Kos, Bor (Author)

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Abstract
Delivery of electrical energy for sensing or therapeutic purposes often involves electrochemical phenomena at the electrode-electrolyte solution interface. Release of gaseous bubbles that accompanies delivery of pulsed electric fields to tissues in applications such as electrochemotherapy of tumours and irreversible electroporation or pulsed field ablation in cardiac electrophysiology needs to be understood and characterized. We present an in vitro study using pulsed field delivery into saline, employing multiple different treatment protocols, two electrode geometries (pair of needles and a modified RF catheter), and two imaging systems to elucidate the complex relationship between the electrical treatment protocol, temperature changes at and around the electrodes, and gas release due to pulse delivery. Our primary objective was to identify the key parameters responsible for bubble formation and to highlight the importance of the treatment parameters and their interplay – ranging from the temperature to appropriate choice of electrode geometry, and, most importantly, to the choice of the treatment protocol. We found that bubbles originating from electrochemical reactions are more prevalent in monophasic pulsing protocols, whereas in high frequency biphasic pulsing protocols the bubbles are mainly caused by boiling of the medium. Degassing of liquid due to lower solubility of gasses at elevated temperatures does seems to play a role, though a minor one. We also observed that bubbles caused by boiling collapse very rapidly, whereas electrochemically produced bubbles or those produced through degassing appear to have longer lifetimes. Therefore, the treatment protocols most suited to minimizing gas release are biphasic trains of short ($\mu$s) pulses with a significant inter-pulse delay (i.e. low duty cycle) to prevent excessive heating. Moreover, electrodes must be designed to avoid high local current densities. Our findings have broad implications extending from lab-on-a-chip cell electroporation devices to intracorporeal pulsed field applications in the cardiovascular system, particularly pulsed field ablation procedures.

Language:English
Keywords:pulsed field ablation, gas release, electrochemistry, joule heating, water phase transition
Work type:Article
Typology:1.01 - Original Scientific Article
Organization:FE - Faculty of Electrical Engineering
Publication status:Published
Publication version:Version of Record
Year:2024
Number of pages:12 str.
Numbering:Vol. 497, art. 144550
PID:20.500.12556/RUL-159176 This link opens in a new window
UDC:602.621:544.6:616-089.87
ISSN on article:1873-3859
DOI:10.1016/j.electacta.2024.144550 This link opens in a new window
COBISS.SI-ID:200309251 This link opens in a new window
Publication date in RUL:02.07.2024
Views:224
Downloads:39
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Record is a part of a journal

Title:Electrochimica acta
Publisher:Elsevier, International Society of Electrochemistry
ISSN:1873-3859
COBISS.SI-ID:135479555 This link opens in a new window

Licences

License:CC BY 4.0, Creative Commons Attribution 4.0 International
Link:http://creativecommons.org/licenses/by/4.0/
Description:This is the standard Creative Commons license that gives others maximum freedom to do what they want with the work as long as they credit the author.

Secondary language

Language:Slovenian
Keywords:ablacija s pulznim električnim poljem, sproščanje plina, elektrokemija, Joulovo segrevanje, fazni prehod vode

Projects

Funder:Other - Other funder or multiple funders
Funding programme:Medtronic

Funder:ARIS - Slovenian Research and Innovation Agency
Project number:P2-0249
Name:Elektroporacija v biologiji, biotehnologiji in medicini

Funder:ARIS - Slovenian Research and Innovation Agency
Project number:P2-0026
Name:Reaktorska tehnika

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