Abstract
BackgroundIrreversible electroporation (IRE) therapy relies on pulsed electric fields to non-thermally ablate cancerous tissue. Methods for evaluating IRE ablation in situ are critical to assessing treatment outcome. Analyzing changes in tissue impedance caused by electroporation has been proposed as a method for quantifying IRE ablation. In this paper, we assess the hypothesis that irreversible electroporation ablation outcome can be monitored using the impedance change measured by the electrode pairs not in use, getting more information about the ablation size in different directions.MethodsUsing a square four-electrode configuration, the two diagonal electrodes were used to electroporate potato tissue. Next, the impedance changes, before and after treatment, were measured from different electrode pairs and the impedance information was extracted by fitting the data to an equivalent circuit model. Finally, we correlated the change of impedance from various electrode pairs to the ablation geometry through the use of fitted functions; then these functions were used to predict the ablation size and compared to the numerical simulation results.ResultsThe change in impedance from the electrodes used to apply pulses is larger and has higher deviation than the other electrode pairs. The ablation size and the change in resistance in the circuit model correlate with various linear functions. The coefficients of determination for the three functions are 0.8121, 0.8188 and 0.8691, respectively, showing satisfactory agreement. The functions can well predict the ablation size under different pulse numbers, and in some directions it did even better than the numerical simulation method, which used different electric field thresholds for different pulse numbers.ConclusionsThe relative change in tissue impedance measured from the non-energized electrodes can be used to assess ablation size during treatment with IRE according to linear functions.
Highlights
Irreversible electroporation (IRE) therapy relies on pulsed electric fields to non-thermally ablate cancerous tissue
Electroporation is a phenomenon that causes an increase in the plasma membrane permeability due to the application of short (~ 100 μs), high voltage pulsed electric fields (PEFs) (~ 1000 V/cm) across the cell [1, 2]
Regarding the tumor therapy of IRE, assessment of ablation outcome is critical for successful treatment
Summary
Irreversible electroporation (IRE) therapy relies on pulsed electric fields to non-thermally ablate cancerous tissue. Analyzing changes in tissue impedance caused by electroporation has been proposed as a method for quantifying IRE ablation. We assess the hypothesis that irreversible electroporation ablation outcome can be monitored using the impedance change measured by the electrode pairs not in use, getting more information about the ablation size in different directions. Electroporation is a phenomenon that causes an increase in the plasma membrane permeability due to the application of short (~ 100 μs), high voltage pulsed electric fields (PEFs) (~ 1000 V/cm) across the cell [1, 2]. Regarding the tumor therapy of IRE, assessment of ablation outcome is critical for successful treatment
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