Focused transhepatic electroporation mediated by hypersaline infusion through the portal vein in rat model. Preliminary results on differential conductivity

Pañella, C.; Castellví, Quim; Moll, Xavier; Quesada, Rita; Villanueva, Alberto; Iglesias, Mar; Naranjo, Dolores; Sánchez-Velázquez, Patricia; Andaluz, Anna; Grande, Luís; Ivorra, Antoni; Burdı́o, Fernando

doi:10.1515/raon-2017-0051

Cited by 6 publications

(16 citation statements)

References 30 publications

(41 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Thus, it would be possible to cause electroporation in tumor cells and avoid this phenomenon in healthy liver tissue 26 . HI concentrates the electric eld in tumor tissue, as we were able to observe conductivity changes of the liver up 1.4 folds higher than tumor tissue 22 , which could focus the treatment on tumor tissue and reduce unwanted damages in the healthy tissue 26 . These results proved that selective electroporation would be available while the electrical eld is modi ed by conductive uids such as HI through the portal vein 22 .…”

Section: Introductionmentioning

confidence: 76%

“…The tissue's physical properties, like impedance, could be a suitable material to reduce the electrical eld throughout the tissues and decrease the damage of the healthy tissues besides the tumor 29 . Following our previous studies on changes in the liver tissue conductivity and its safety, we started exploring various biocompatible materials with low toxicity and capable of manipulating tissue impedance to observe the results in the electrical impedance of the tissue 22,26,30 . Finally, GS5% was selected for model 31 .…”

Section: Discussionmentioning

confidence: 99%

“…However, it is a non-thermal technique to spare the extracellular matrix but induces apoptosis in healthy and tumor tissue where the electric eld applies 20,21 . Achieving perfect irreversible electroporation requires precision and improving the selectivity of the process 22 to raise the concentration of the ablation on tumor cells.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Glucose Solution Through the Hepatic Artery May Focus Irreversible Electroporation Into the Tumor. A Preliminary Safety and Efficacy Evaluation

Sarreshtehdari

Burdı́o

López-Alonso

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

Tissue electrical properties like impedance greatly impact irreversible electroporation (IRE) function. Infusion of glucose solution 5% (GS5%) through the Hepatic artery would focus IRE on scattered tumors of the liver. By creating a differential impedance between healthy and tumor tissue. This study aimed to determine the effects of the GS5% protocol on the liver and its safety. 21 male Athymic nude rats Hsd: RH-Foxn1mu were used in the study. Animals were split into two groups. In group 1, a continuous infusion through the gastroduodenal artery of GS5% was performed to measure the impedance with a dose of 0.008 mL/g for 16 minutes. In group 2, the animals were divided into two subgroups for infusions of GS5%. Group 2.1, at 0.008 mL/g for 16 minutes. Group 2.2 at 0.03 ml/g for 4 minutes. Blood samples were collected after anesthesia has been induced. The second sample, after catheterization of the artery, and the third after the GS5% infusion. All the animals were sacrificed to collect histological samples. The survival rate during the experiment was 100%. A considerable impact on the impedance of the tissue was noticed, on average up to 4.31 times more than the baseline, and no side effects were observed after GS5% infusion. In conclusion, to decrease IRE’s side effects on healthy tissue (without portal irrigation), GS5% could be a practical therapeutic solution.

show abstract

Section: Introductionmentioning

confidence: 76%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Glucose Solution Through the Hepatic Artery May Focus Irreversible Electroporation Into the Tumor. A Preliminary Safety and Efficacy Evaluation

Sarreshtehdari

Burdı́o

López-Alonso

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Also, this type of electrode normally requires several repositioning/application processes to treat large volumes [10,15]. For this reason, this paper is focused on the study of parallel-plate electrodes [3,[16][17][18] to achieve adequate electric field distribution [19,20], as can be seen in Figure 2fh Currently, the most commonly used electrodes are parallel-needle electrodes [10][11][12], as they normally allow quick and easy placement. The main limitation of needle-based electrodes is that they create an irregular electric field [13], which is concentrated in several points producing undesired thermal effects [14].…”

mentioning

confidence: 99%

mentioning

confidence: 99%

Multi-Electrode Architecture Modeling and Optimization for Homogeneous Electroporation of Large Volumes of Tissue

et al. 2021

View full text Add to dashboard Cite

Electroporation is a phenomenon that consists of increasing the permeability of the cell membrane by means of high-intensity electric field application. Nowadays, its clinical application to cancer treatment is one of the most relevant branches within the many areas of electroporation. In this area, it is essential to apply homogeneous treatments to achieve complete removal of tumors and avoid relapse. It is necessary to apply an optimized transmembrane potential at each point of the tissue by means of a homogenous electric field application and appropriated electric field orientation. Nevertheless, biological tissues are composed of wide variety, heterogeneous and anisotropic structures and, consequently, predicting the applied electric field distribution is complex. Consequently, by applying the parallel-needle electrodes and single-output generators, homogeneous and predictable treatments are difficult to obtain, often requiring several repositioning/application processes that may leave untreated areas. This paper proposes the use of multi-electrode structure to apply a wide range of electric field vectors to enhance the homogeneity of the treatment. To achieve this aim, a new multi-electrode parallel-plate configuration is proposed to improve the treatment in combination with a multiple-output generator. One method for optimizing the electric field pattern application is studied, and simulation and experimental results are presented and discussed, proving the feasibility of the proposed approach.

show abstract

Global sensitivity study for irreversible electroporation: Towards treatment planning under uncertainty

et al. 2023

View full text Add to dashboard Cite

Background: Electroporation-based cancer treatments are minimally invasive, nonthermal interventional techniques that leverage cell permeabilization to ablate the target tumor. However, the amount of permeabilization is susceptible to the numerous uncertainties during treatment, such as patient-specific variations in the tissue, type of the tumor, and the resolution of imaging equipment. These uncertainties can reduce the extent of ablation in the tissue, thereby affecting the effectiveness of the treatment. Purpose: The aim of this work is to understand the effect of these treatment uncertainties on the treatment outcome for irreversible electroporation (IRE) in the case of colorectal liver metastasis (CRLM). Understanding the nature and extent of these effects can help us identify the influential treatment parameters and build better models for predicting the treatment outcome. Methods: This is an in silico study using a static computational model with a custom applicator design, spherical tissue, and tumor geometry. A nonlinear electrical conductivity, dependent on the local electric field, is considered. Morris analysis is used to identify the influential treatment parameters on the treatment outcome. Seven treatment parameters pertaining to the relative tumor location with respect to the applicator, the tumor growth pattern, and the electrical conductivity of tissue are analyzed. The treatment outcome is measured in terms of the relative tumor ablation with respect to the target ablation volume and total ablation volume. Results: The Morris analysis was performed with 800 model evaluations, sampled from the seven dimensional input parameter space. Electrical properties of the tissue, especially the electrical conductivity of the tumor before ablation, were found to be the most influential parameter for relative tumor ablation and total ablation volume. This parameter was found to be about 4-15 times more influential than the least influential parameter, depending on the tumor size. The tumor border configuration was identified as the least important parameter for treatment effectiveness. The most desired treatment outcome is obtained by a combination of high healthy liver conductivity and low tumor conductivity. This information can be used to tackle worst-case scenarios in treatment planning. Finally, when the safety margins used in the clinical applications are accounted for, the effects of uncertainties in the treatment parameters reduce drastically. Conclusions:The results of this work can be used to create an efficient surrogate estimator for uncertainty quantification in the treatmentThis is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

show abstract

Focused transhepatic electroporation mediated by hypersaline infusion through the portal vein in rat model. Preliminary results on differential conductivity

Cited by 6 publications

References 30 publications

Glucose Solution Through the Hepatic Artery May Focus Irreversible Electroporation Into the Tumor. A Preliminary Safety and Efficacy Evaluation

Glucose Solution Through the Hepatic Artery May Focus Irreversible Electroporation Into the Tumor. A Preliminary Safety and Efficacy Evaluation

Multi-Electrode Architecture Modeling and Optimization for Homogeneous Electroporation of Large Volumes of Tissue

Global sensitivity study for irreversible electroporation: Towards treatment planning under uncertainty

Contact Info

Product

Resources

About