Intracardiac Voltage Gradients during Transthoracic Defibrillation: Implications for Postshock Myocardial Injury

Abstract: In-vitro studies indicate that the electric-field intensity, or voltage gradient (VG), generated by a defibrillation shock is a determinant of defibrillation success as well as potential shock-induced cardiac injury. It is not clear how common descriptors of shock dose, e.g., joules (J), relate to VGs. Objectives: To assess the relationships between shock energy descriptors and VG. Methods: One monophasic and three biphasic waveforms were compared using transthoracic shocks and standard electrodes in five swin… Show more

“…This method has been previously reported. [13][14][15] The delivered energy, voltage, and peak current waveforms of all shocks were recorded using a digital oscilloscope (Tektronix TDS 5054) connected to a custom-built voltage and current sensor. Transthoracic voltage and current were measured 4 ms after defibrillator discharge.…”

A Percutaneous Catheter‐Based System for the Measurement of Potential Gradients Applicable to the Study of Transthoracic Defibrillation

“…This method has been previously reported. [13][14][15] The delivered energy, voltage, and peak current waveforms of all shocks were recorded using a digital oscilloscope (Tektronix TDS 5054) connected to a custom-built voltage and current sensor. Transthoracic voltage and current were measured 4 ms after defibrillator discharge.…”

A Percutaneous Catheter‐Based System for the Measurement of Potential Gradients Applicable to the Study of Transthoracic Defibrillation

The Role of Electroporation

An in-silico assessment of efficacy of two novel intra-cardiac electrode configurations versus traditional anti-tachycardia pacing therapy for terminating sustained ventricular tachycardia