pH fronts and tissue natural buffer interaction in gene electrotransfer protocols

Gene electrotransfer (GET) protocols, based on the introduction into the cells of genes encoding immunomodulatory molecules, constitute a safe and powerful strategy for inducing an immune response against cancer. But GET efficiency can be significantly affected by damage due to the products of elect...

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Detalles Bibliográficos
Publicado: 2017
Materias:
Electrochemotherapy
electrolytic ablation
Gene electrotransfer
irreversible electroporation
pH front tracking
Efficiency
Gene encoding
Genes
Ions
pH
Physiology
Trajectories
Electroporation
Electrotransfer
Front tracking
Nernst-Planck equations
Physiological pH
Physiological state
Theoretical modeling
Tissue
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00134686_v255_n_p463_Marino
http://hdl.handle.net/20.500.12110/paper_00134686_v255_n_p463_Marino
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_00134686_v255_n_p463_Marino
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spelling paper:paper_00134686_v255_n_p463_Marino2023-06-08T14:35:49Z pH fronts and tissue natural buffer interaction in gene electrotransfer protocols Electrochemotherapy electrolytic ablation Gene electrotransfer irreversible electroporation pH front tracking Efficiency Gene encoding Genes Ions pH Physiology Trajectories Electrochemotherapy Electroporation Electrotransfer Front tracking Nernst-Planck equations Physiological pH Physiological state Theoretical modeling Tissue Gene electrotransfer (GET) protocols, based on the introduction into the cells of genes encoding immunomodulatory molecules, constitute a safe and powerful strategy for inducing an immune response against cancer. But GET efficiency can be significantly affected by damage due to the products of electrolysis, in particular, pH fronts. To elucidate the role of pH fronts and damage in GET efficiency we present an analysis of the pH fronts-tissue natural buffer interaction through a theoretical model using the Nernst-Planck equations for ion transport assuming a tissue with a bicarbonate buffering system and its validation with experimental measurements. pH front-buffer interaction measurements unveil a remarkable behavior tuned by pulse length and frequency: during the ON pulse critical pH front trajectories (pH=8.5 or 5.5) jump forward, during the OFF pulse, they recede due to tissue natural buffer attenuation. Theory shows that they are intimately related to ion transport mode: during the ON pulse, ion transport is mainly governed by migration and trajectories jump forward in time; during the OFF pulse, migration ceases, ion transport is governed solely by diffusion and trajectories recede due to buffer attenuation. Experiments and theory show that regardless of the presence of buffer attenuation, pH fronts remain during several minutes in a non-physiological state after the treatment. These results suggest that regions enclosed by pH fronts trajectories (thus subjected to non-physiological pH values during a sufficiently long time) may be subjected to plasmid damage during a GET treatment. Ways to minimize this effect, thus optimizing GET efficiency are suggested. © 2017 2017 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00134686_v255_n_p463_Marino http://hdl.handle.net/20.500.12110/paper_00134686_v255_n_p463_Marino
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Electrochemotherapy
electrolytic ablation
Gene electrotransfer
irreversible electroporation
pH front tracking
Efficiency
Gene encoding
Genes
Ions
pH
Physiology
Trajectories
Electrochemotherapy
Electroporation
Electrotransfer
Front tracking
Nernst-Planck equations
Physiological pH
Physiological state
Theoretical modeling
Tissue
spellingShingle Electrochemotherapy
electrolytic ablation
Gene electrotransfer
irreversible electroporation
pH front tracking
Efficiency
Gene encoding
Genes
Ions
pH
Physiology
Trajectories
Electrochemotherapy
Electroporation
Electrotransfer
Front tracking
Nernst-Planck equations
Physiological pH
Physiological state
Theoretical modeling
Tissue
pH fronts and tissue natural buffer interaction in gene electrotransfer protocols
topic_facet Electrochemotherapy
electrolytic ablation
Gene electrotransfer
irreversible electroporation
pH front tracking
Efficiency
Gene encoding
Genes
Ions
pH
Physiology
Trajectories
Electrochemotherapy
Electroporation
Electrotransfer
Front tracking
Nernst-Planck equations
Physiological pH
Physiological state
Theoretical modeling
Tissue
description Gene electrotransfer (GET) protocols, based on the introduction into the cells of genes encoding immunomodulatory molecules, constitute a safe and powerful strategy for inducing an immune response against cancer. But GET efficiency can be significantly affected by damage due to the products of electrolysis, in particular, pH fronts. To elucidate the role of pH fronts and damage in GET efficiency we present an analysis of the pH fronts-tissue natural buffer interaction through a theoretical model using the Nernst-Planck equations for ion transport assuming a tissue with a bicarbonate buffering system and its validation with experimental measurements. pH front-buffer interaction measurements unveil a remarkable behavior tuned by pulse length and frequency: during the ON pulse critical pH front trajectories (pH=8.5 or 5.5) jump forward, during the OFF pulse, they recede due to tissue natural buffer attenuation. Theory shows that they are intimately related to ion transport mode: during the ON pulse, ion transport is mainly governed by migration and trajectories jump forward in time; during the OFF pulse, migration ceases, ion transport is governed solely by diffusion and trajectories recede due to buffer attenuation. Experiments and theory show that regardless of the presence of buffer attenuation, pH fronts remain during several minutes in a non-physiological state after the treatment. These results suggest that regions enclosed by pH fronts trajectories (thus subjected to non-physiological pH values during a sufficiently long time) may be subjected to plasmid damage during a GET treatment. Ways to minimize this effect, thus optimizing GET efficiency are suggested. © 2017
title pH fronts and tissue natural buffer interaction in gene electrotransfer protocols
title_short pH fronts and tissue natural buffer interaction in gene electrotransfer protocols
title_full pH fronts and tissue natural buffer interaction in gene electrotransfer protocols
title_fullStr pH fronts and tissue natural buffer interaction in gene electrotransfer protocols
title_full_unstemmed pH fronts and tissue natural buffer interaction in gene electrotransfer protocols
title_sort ph fronts and tissue natural buffer interaction in gene electrotransfer protocols
publishDate 2017
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00134686_v255_n_p463_Marino
http://hdl.handle.net/20.500.12110/paper_00134686_v255_n_p463_Marino
_version_ 1768545217163558912

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