Litcius/Paper detail

OpenEP: an open-source simulator for electroporation-based tumor treatments

M. Marino, Emmanuel Luján, Esteban Mocskos, Guillermo Marshall

2021Scientific Reports23 citationsDOIOpen Access PDF

Abstract

Electroporation (EP), the increase of cell membrane permeability due to the application of electric pulses, is a universal phenomenon with a broad range of applications. In medicine, some of the foremost EP-based tumor treatments are electrochemotherapy (ECT), irreversible electroporation, and gene electrotransfer (GET). The electroporation phenomenon is explained as the formation of cell membrane pores when a transmembrane cell voltage reaches a threshold value. Predicting the outcome of an EP-based tumor treatment consists of finding the electric field distribution with an electric threshold value covering the tumor (electroporated tissue). Threshold and electroporated tissue are also a function of the number of pulses, constituting a complex phenomenon requiring mathematical modeling. We present OpenEP, an open-source specific purpose simulator for EP-based tumor treatments, modeling among other variables, threshold, and electroporated tissue variations in time. Distributed under a free/libre user license, OpenEP allows the customization of tissue type; electrode geometry and material; pulse type, intensity, length, and frequency. OpenEP facilitates the prediction of an optimal EP-based protocol, such as ECT or GET, defined as the critical pulse dosage yielding maximum electroporated tissue with minimal damage. OpenEP displays a highly efficient shared memory implementation by taking advantage of parallel resources; this permits a rapid prediction of optimal EP-based treatment efficiency by pulse number tuning.

Topics & Concepts

ElectroporationElectrochemotherapyComputer scienceElectric fieldBiomedical engineeringPulse (music)Materials scienceBiological systemBioinformaticsSimulationChemistryPhysicsBiologyGeneMedicineTelecommunicationsDetectorBiochemistryQuantum mechanicsMicrobial Inactivation MethodsMicrofluidic and Bio-sensing TechnologiesPulsed Power Technology Applications