An Updated Numerical Workflow for Predicting Clinical Outcomes of Irreversible Electroporation in Hepatocellular Carcinoma

Abstract

Background and Objectives:

Electroporation ablation is a promising nonsurgical and minimally invasive technique for tumor ablation; however, no monitoring is currently available. In this article, we present recent advances in the numerical workflow toward a peroperative numerical evaluation of clinical irreversible electroporation (IRE) procedures of liver tumors. The objective of this study is to propose an updated numerical workflow for the digital twin of electroporation ablation, to provide relevant information to physicians performing IRE for hepatocellular carcinoma (HCC).

Methods:

The workflow consists of four main steps: (1) an image registration algorithm to align the contrast-enhanced cone beam computed tomography (CBCT), where the region of interest are visible, with the lower-quality CBCT acquired after needle insertion; (2) extraction of needles position by manual selection directly on the CBCT containing the needles; (3) accurate and efficient numerical computation of the electric field (EF) distribution, using a static linear model and the finite difference method to simulate the EF at the maximum voltage applied between each electrode pair; and (4) numerical assessment of the tumor coverage by the 3D EF.

Results:

We propose a criterion for electrical heterogeneity of the medium near the electrode thanks to the measurements provided by the Nanoknife IRE device. The full protocol was tested on three representative patients with nodular HCCs <5 cm. The complete numerical workflow, from image registration and needle detection to the computation, requires at most less than 15 min following image acquisitions, making it suitable for clinical use. Interestingly, the number of finite difference computations increases linearly with the number of needles N, despite the number of electrode pairs increasing as $N (N - 1) / 2$ . In addition, the pulse amplitude can be modified without the need for full recomputation, enabling online adjustment of the treatment plan.

Keywords

computational tissue electroporation clinical electroporation ablation peroperative numerical assessments

Get full access to this article

View all access options for this article.

References

Padia

, Johnson

, Yeung

, et al. Irreversible electroporation in patients with hepatocellular carcinoma: Immediate versus delayed findings at MR imaging. Radiology, 2016; 278(1):285–294.

Sutter

, Calvo

, N’Kontchou

, et al. Safety and efficacy of irreversible electroporation for the treatment of hepatocellular carcinoma not amenable to thermal ablation techniques: A retrospective single-center case series. Radiology, 2017; 284(3):877–886.

Bhutiani

, Philips

, Scoggins

, et al. Evaluation of tolerability and efficacy of irreversible electroporation (IRE) in treatment of Child-Pugh B (7/8) hepatocellular carcinoma (HCC). HPB, 2016; 18(7):593–599.

Perera-Bel

, Aycock

, Salameh

, et al. PIRET—A platform for treatment planning in electroporation-based therapies. IEEE Trans Biomed Eng, 2023; 70(6):1902–1910.

Geboers

, Scheffer

, Graybill

, et al. High-voltage electrical pulses in oncology: Irreversible electroporation, electrochemotherapy, gene electrotransfer, electrofusion, and electroimmunotherapy. Radiology, 2020; 295(2):254–272.

Gallinato

, Denis de Senneville

, Seror

, et al. Numerical workflow of irreversible electroporation for deep-seated tumor. Phys Med Biol, 2019; 64(5):055016.

Sutter

, Denis de Senneville

, Lafitte

, et al. Toward perioperative, numerically assisted irreversible electroporation for hepatocellular carcinoma: Clinical outcomes informed by numerical simulations. Eur Radiol, 2025.

Sutter

, Lafitte

, Seror

et al. Correlation between computed electric dose maps and early post-operative MRI for the evaluation of irreversible electroporation. Phys Med Biol, 2025; 70(22):225010; doi: 10.1088/1361-6560/ae1802

Gallinato

, de Senneville

, Seror

, et al. Numerical modelling challenges for clinical electroporation ablation technique of liver tumors. Math Model Nat Phenom, 2020; 15:11.

10.

Collin

, Corridore

, Poignard

. Floating potential boundary condition in smooth domains in an electroporation context. In: Methods of Mathematical Oncology. Springer Singapore: Singapore; 2021.

11.

Sel

, Cukjati

, Batiuskaite

, et al. Sequential finite element model of tissue electropermeabilization. IEEE Trans Biomed Eng, 2005; 52(5):816–827.

12.

Davalos

, Mir

, Rubinsky

. Tissue ablation with irreversible electroporation. Ann Biomed Eng, 2005; 33(2):223–231.

13.

Ivorra

, Al-Sakere

, Rubinsky

, et al. In vivo electrical conductivity measurements during and after tumor electroporation: Conductivity changes reflect the treatment outcome. Phys Med Biol, 2009; 54(19):5949–5963.

14.

Neal

, Millar

, Kavnoudias

, et al. In vivo characterization and numerical simulation of prostate properties for non-thermal irreversible electroporation ablation: Characterized and simulated prostate IRE. Prostate, 2014; 74(5):458–468.

15.

Neal

, Garcia

, Kavnoudias

, et al. In vivo irreversible electroporation kidney ablation: Experimentally correlated numerical models. IEEE Trans Biomed Eng, 2015; 62(2):561–569.

16.

Garcia

, Davalos

, Miklavcic

. A numerical investigation of the electric and thermal cell kill distributions in electroporation-based therapies in tissue. PLoS One, 2014; 9(8):e103083.

17.

Voyer

, Silve

, Mir

, et al. Dynamical modeling of tissue electroporation. Bioelectrochemistry, 2018; 119:98–110.

18.

Jankowiak

, Taing

, Poignard

, et al. Comparison and calibration of different electroporation models. Application to rabbit livers experiments. ESAIM: ProcS, 2020; 67:242–260.

19.

Breton

, Buret

, Krähenbühl

, et al. Non-linear steady-state electrical current modeling for the electropermeabilization of biological tissue. IEEE Trans Magn, 2015; 51(3):1–4.

20.

Pennes

. Analysis of Tissue and Arterial Blood Temperatures in the Resting Human Forearm. Journal of Applied Physiology, 1948; 1(2):93–122; doi: 10.1152/jappl.1948.1.2.93

21.

Aycock

, Davalos

. Irreversible electroporation: Background, theory, and review of recent developments in clinical oncology. Bioelectricity, 2019; 1(4):214–234.

22.

Cindric

, Mariappan

, Beyer

, et al. Retrospective study for validation and improvement of numerical treatment planning of irreversible electroporation ablation for treatment of liver tumors. IEEE Trans Biomed Eng, 2021; 68(12):3513–3524.

23.

Séror

, Poignard

, Gallinato

, et al. Irreversible electroporation: Disappearance of observable changes at imaging does not always imply complete reversibility of the underlying causal tissue changes. Radiology, 2017; 282(1).

24.

Sutter

, Fihri

, Ourabia-Belkacem

, et al. Real-time 3D virtual target fluoroscopic display for challenging hepatocellular carcinoma ablations using cone beam CT. Technol Cancer Res Treat, 2018; 17:1533033818789634.

25.

Pescatori

, Dessain

, N’Kontchou

, et al. The role of early MRI in assessing the risk of local tumor progression following irreversible electroporation for hepatocellular carcinoma treatment. Int J Hyperthermia, 2025; 42(1).

26.

Desier

, Lafitte

, Facq

, et al. Deep modelling of electric field distribution for clinical electroporation ablation therapies. In: 22nd IEEE International Symposium on Biomedical Imaging (ISBI). IEEE: Houston, TX; 2025; pp. e01–e05.

27.

Sutter

, Voyer

, Tasu

, et al. How impedance measurements and imaging can be used to characterize the conductivity of tissues during the workflow of an electroporation-based therapy. IEEE Trans Biomed Eng, 2024; 71(4):1370–1377.

28.

Denis de Senneville

, Zachiu

, Ries

, et al. EVolution: An edgebased variational method for non-rigid multi-modal image registration. Phys Med Biol, 2016; 61(20):7377–7396.

29.

Gallinato

, Poignard

. IRENA: A finite volume method based software for the numerical assessment of clinical IRE. Version 1.0. 2018.

30.

Denis de Senneville

, Lafitte

, Poignard

. Evo estimator: 3D slicer plugin for non-rigid multimodal registration. Version 1.0. APP: IDDN.FR.001.500006.000.S.P.2024.000.312301. 2024.

31.

Denis de Senneville

, Lafitte

, Poignard

. Clinical IRE: A 3D slicer plugin for calculating the electric field during an irreversible electroporation (IRE) ablation procedure. Version 1.0. APP: IDDN.FR.001.500007.000.S.A.2024.000.31230. 2024.

32.

Inacio

, Lafitte

, Sutter

, et al. Automated needle localisation for electric field computation during an electroporation ablation. In: 21st IEEE Mediterranean Electrotechnical Conference. IEEE: Palermo, Italy; 2022; pp. 1279–1284.

33.

Isensee

, Jaeger

, Kohl

SAA

, et al. nnU-Net: A self-configuring method for deep learning-based biomedical image segmentation. Nat Methods, 2021; 18(2):203–211.