@article {227, title = {First-in-human demonstration of floating EMG sensors and stimulators wirelessly powered and operated by volume conduction}, journal = {Journal of NeuroEngineering and Rehabilitation}, volume = {21}, year = {2024}, pages = {4}, chapter = {4}, doi = {10.1186/s12984-023-01295-5}, url = {https://doi.org/10.1186/s12984-023-01295-5}, author = {Laura Becerra-Fajardo and Jesus Minguillon and Krob, Marc O. and Camila Rogrigues and Miguel Gonz{\'a}lez-S{\'a}nchez and {\'A}lvaro Meg{\'\i}a-Garc{\'\i}a and Redondo Gal{\'a}n, Carolina and Guiti{\'e}rrez Henares, Francisco and Albert Comerma and del Ama, Antonio J. and {\'A}ngel Gil-Agudo and Francisco Grandas and Andreas Schneider and Filipe O. Barroso and Antoni Ivorra} } @article {214, title = {Floating EMG Sensors and Stimulators Wirelessly Powered and Operated by Volume Conduction for Networked Neuroprosthetics}, journal = {Journal of NeuroEngineering and Rehabilitation}, volume = {19}, year = {2022}, pages = {57}, chapter = {57}, doi = {10.1186/s12984-022-01033-3}, url = {https://doi.org/10.1186/s12984-022-01033-3}, author = {Laura Becerra-Fajardo and Krob, Marc O. and Jesus Minguillon and Camila Rogrigues and Christine Welsch and Marc Tudela-Pi and Albert Comerma and Filipe O. Barroso and Andreas Schneider and Antoni Ivorra} } @article {206, title = {Comparing High-Frequency With Monophasic Electroporation Protocols in an In Vivo Beating Heart Model}, journal = {JACC: Clinical Electrophysiology}, volume = {7}, year = {2021}, pages = {959-964}, chapter = {959}, doi = {10.1016/j.jacep.2021.05.003}, author = {Eyal Heller and Tomas Garcia-Sanchez and Yonatan Moshkovits and Raul Rabinovici and Dvora Grynberg and Amit Segev and Samuel Asirvatham and Antoni Ivorra and Elad Maor} } @conference {210, title = {In Vitro Evaluation of a Protocol and an Architecture for Bidirectional Communications in Networks of Wireless Implants Powered by Volume Conduction}, booktitle = {5th International Conference on Neurorehabilitation (ICNR2020)}, volume = {28}, year = {2020}, pages = {103-108}, publisher = {Springer Nature}, organization = {Springer Nature}, edition = {Converging Clinical and Engineering Research on Neurorehabilitation IV, Biosystems \& Biorobotics}, doi = {10.1007/978-3-030-70316-5_17}, author = {Laura Becerra-Fajardo and Jesus Minguillon and Camila Rogrigues and Filipe O. Barroso and Pons, Jos{\'e} Luis and Antoni Ivorra} } @article {174, title = {Design, Construction and Validation of an Electrical Impedance Probe with Contact Force and Temperature Sensors Suitable for in-vivo Measurements}, journal = {Scientific Reports}, volume = {8}, year = {2018}, pages = {14818}, chapter = {14818}, doi = {10.1038/s41598-018-33221-4}, author = {A. Ruiz-Vargas and Antoni Ivorra and J. W. Arkwright} } @article {168, title = {Impedance spectroscopy measurements as a tool for distinguishing different luminal content during bolus transit studies}, journal = {Neurogastroenterology and Motility}, volume = {30}, year = {2018}, pages = {e13274}, chapter = {e13274}, doi = {10.1111/nmo.13274}, author = {A. Ruiz-Vargas and R. Mohd Rosli and Antoni Ivorra and J. W. Arkwright} } @conference {181, title = {Monitoring the Effect of Contact Pressure on Bioimpedance Measurements}, booktitle = {018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)}, year = {2018}, month = {2019}, pages = {4949-4952}, doi = {10.1109/EMBC.2018.8513173}, author = {A. Ruiz-Vargas and Antoni Ivorra and J. W. Arkwright} } @article {167, title = {Relation between Denaturation Time Measured by Optical Coherence Reflectometry and Thermal Lesion Depth during Radiofrequency Cardiac Ablation: Feasibility Numerical Study}, journal = {Lasers in surgery and medicine}, volume = {50}, year = {2018}, pages = {222-229}, chapter = {222}, doi = {10.1002/lsm.22771}, author = {Gonz{\'a}lez-Su{\'a}rez, Ana and Herranz, David and Berjano, Enrique and Rubio-Guivernau, Jose L and Margallo-Balb{\'a}s, Eduardo} } @article {Gonzalez-Sosa2014, title = {{Fast flow-through non-thermal pasteurization using constant radiofrequency electric fields}}, journal = {Innovative Food Science and Emerging Technologies}, volume = {22}, year = {2014}, pages = {pp.116-123}, chapter = {116}, doi = {DOI: 10.1016/j.ifset.2014.01.003}, author = {J. Gonz{\'a}lez-Sosa and A. Ruiz-Vargas and G. Arias and Antoni Ivorra} } @conference {Gonzalez-Sosa2013, title = {{Fast flow-through non-thermal pasteurization using constant radiofrequency electric fields}}, booktitle = {Tenth International Bioelectrics Symposium (BIOELECTRICS 2013)}, year = {2013}, address = {Karlsruhe, Germany}, abstract = {

Pulsed Electric Field technologies have captured the attention of researchers on food pasteurization because of their non-thermal inactivation mechanism, which results in fresh-like products. Nevertheless, high voltage pulsing required by these technologies implies complex and costly generators. Here, as an alternative, it is proposed a method, partially inherited from research on cell electroporation for gene transfection, in which the liquid to be treated flows at high speed through a miniature chamber where the electric field is permanently applied. In particular, it is proposed that the constantly applied electric field consists of an AC signal (\> 100 kHz) so that electrochemical by-products are minimized. The method, while being compatible with batch processing, will allow use of lower voltages and will avoid the pulsation requirement.\ 

}, author = {J. Gonz{\'a}lez-Sosa and A. Ruiz-Vargas and G. Arias and Q. Castellv{\'\i} and Antoni Ivorra} } @article {Ivorra2010a, title = {{Electric field redistribution during tissue electroporation: its potential impact on treatment planning}}, journal = {Comptes Rendus Physique}, volume = {Accepted (still pending publication)}, year = {2010}, abstract = {
Electroporation is the phenomenon in which cell membrane permeability is increased by exposing the cell to short high electric field pulses. Electroporation is accompanied by an increase of tissue electrical conductivity during the pulses. Such conductivity increase results in a redistribution of the electric field magnitude that can be simulated with simple functions describing the change in tissue conductivity. Experiments on potato tuber reveal that the conductivity increase phenomenon has indeed a significant impact on field distribution, and validate the use of models that take into account such conductivity alteration. For instance, the error in electroporated area estimation can decrease from 30 \% to 3 \%.\ 
}, author = {Antoni Ivorra and Boris Rubinsky and L.M. Mir} } @article {Laufer2010, title = {{Electrical impedance characterization of normal and cancerous human hepatic tissue.}}, journal = {Physiological measurement}, volume = {31}, number = {7}, year = {2010}, pages = {995{\textendash}1009. {\textcopyright} 2010 Institute of Physics and IOP Publishing Limited.}, abstract = {

The four-electrode method was used to measure the ex vivo complex electrical impedance of tissues from 14 hepatic tumors and the surrounding normal liver from six patients. Measurements were done in the frequency range 1-400 kHz. It was found that the conductivity of the tumor tissue was much higher than that of the normal liver tissue in this frequency range (from 0.14 +/- 0.06 S m(-1) versus 0.03 +/- 0.01 S m(-1) at 1 kHz to 0.25 +/- 0.06 S m(-1) versus 0.15 +/- 0.03 S m(-1) at 400 kHz). The Cole-Cole models were estimated from the experimental data and the four parameters (rho(0), rho(infinity), alpha, f(c)) were obtained using a least-squares fit algorithm. The Cole-Cole parameters for the cancerous and normal liver are 9 +/- 4 Omega m(-1), 2.2 +/- 0.7 Omega m(-1), 0.5 +/- 0.2, 140 +/- 103 kHz and 50 +/- 28 Omega m(-1), 3.2 +/- 0.6 Omega m(-1), 0.64 +/- 0.04, 10 +/- 7 kHz, respectively. These data can contribute to developing bioelectric applications for tissue diagnostics and in tissue treatment planning with electrical fields such as radiofrequency tissue ablation, electrochemotherapy and gene therapy with reversible electroporation, nanoscale pulsing and irreversible electroporation.

}, keywords = {80 and over, Adult, Aged, Electric Impedance, Electrodes, Female, Humans, Liver, Liver Cirrhosis, Liver Cirrhosis: pathology, Liver Neoplasms, Liver Neoplasms: pathology, Liver: pathology, Male, Middle Aged}, issn = {1361-6579}, doi = {10.1088/0967-3334/31/7/009}, url = {http://www.ncbi.nlm.nih.gov/pubmed/20577035}, author = {Laufer, Shlomi and Antoni Ivorra and Reuter, Victor E and Boris Rubinsky and Solomon, Stephen B} } @inbook {Ivorra2010e, title = {{Historical Review of Irreversible Electroporation in Medicine}}, booktitle = {Irreversible Electroporation}, series = {Series in Biomedical Engineering}, year = {2010}, pages = {1{\textendash}21}, publisher = {Springer Berlin Heidelberg}, organization = {Springer Berlin Heidelberg}, address = {Berlin, Heidelberg}, abstract = {

The objective of this chapter is to present a historical review of the field of irreversible electroporation (IRE) in the context of its medical applications. Although relevant scientific observations were made since the 18th century, the electroporation phenomenon was not identified as an increase of membrane permeability until mid 20th century. After that, multiple applications of reversible electroporation emerged in vitro (DNA electrotransfer) and in vivo (electrogenetherapy and electrochemotherapy). Irreversible electroporation was tested commercially in the 60s as a bactericidal method for liquids and foods but its use in the context of medical applications was not studied until the early 2000s as an ablative method. The cell destruction mechanism of IRE is not based on thermal damage and this fact provides to IRE an important advantage over other physical ablation methods: the extracellular scaffolding, including the vessels, is preserved. Several surgical applications are now under study or even under clinical trial: ablation of hepatocarcinomas, ablation of prostate tumors, treatment of atrial fibrillation and treatment of vascular occurrences such as restenosis and atherosclerotic processes.

}, isbn = {978-3-642-05419-8}, doi = {10.1007/978-3-642-05420-4}, url = {http://link.springer.com/10.1007/978-3-642-05420-4}, author = {Antoni Ivorra and Boris Rubinsky}, editor = {Boris Rubinsky} } @inbook {Ivorra2010d, title = {{Irreversible Electroporation}}, booktitle = {Irreversible Electroporation}, series = {Series in Biomedical Engineering}, year = {2010}, pages = {23{\textendash}61}, publisher = {Springer Berlin Heidelberg}, organization = {Springer Berlin Heidelberg}, address = {Berlin, Heidelberg}, abstract = {

Electroporation is the phenomenon in which cell membrane permeability to ions and macromolecules is increased by exposing the cell to short (microsecond to millisecond) high electric field pulses. In living tissues, such permeabilization boost can be used in order to enhance the penetration of drugs (electrochemotherapy) or DNA plasmids (electrogenetherapy) or to destroy undesirable cells (irreversible electroporation). The main purpose of the present chapter is to provide an overview of the electrical concepts related to electroporation for those not familiar with electromagnetism. It is explained that electroporation is a dynamic phenomenon that depends on the local transmembrane voltage and it is shown how a voltage difference applied though a pair of electrodes generates an electric field which in turn induces the required transmembrane voltage for electroporation to occur. Quite exhaustive details are given on how electroporation changes the passive electrical properties of living tissues. Furthermore, some remarks are given about the effects of electroporation on other bioelectric phenomena such as cardiac arrhythmias.

}, isbn = {978-3-642-05419-8}, doi = {10.1007/978-3-642-05420-4}, url = {http://link.springer.com/10.1007/978-3-642-05420-4}, author = {Antoni Ivorra}, editor = {Boris Rubinsky} }