Advanced electroporation techniques in biology and medicine by Andrei G. Pakhomov, Damijan Miklavcic, Marko S. Markov

By Andrei G. Pakhomov, Damijan Miklavcic, Marko S. Markov

"A mirrored image of the serious learn of the consequences of electromagnetic fields on dwelling tissues that has taken position over the past numerous many years, this publication discusses the theoretical and experimental proof and concerns the consequences of sturdy electromagnetic fields and/or electrical pulses and their significance in drugs and biology. The authors current the elemental concepts utilized in electroporation and the complicated equipment for production of nanopores, highlighting their uncomplicated technology and scientific purposes. subject matters contain nano electroporation, vintage electroporaiton, experimental facts for electroporation of residing cells, and electroporation for melanoma and wound healing"--Provided by way of writer. learn more... content material: fundamentals of Electroporation actual Chemical thought of Membrane Electroporation and Electrotransfer of Biogenic brokers, E. Neumann and S. Kakorin Bioelectric influence of severe Nanosecond Pulses, K.H. Schoenbach prompted Transmembrane Voltage-Theory, Modeling, and Experiments, T. Kotnik and G. Pucihar Electroporation: A overview of easy difficulties in thought and test, M.S. Markov Mechanisms of Electroporation in Lipid platforms Electrodeformation, Electroporation, and Electrofusion of Cell-Sized Lipid Vesicles, R. Dimova Fluorescent equipment in review of Nanopore Conductivity and Their Computational Validation, M. Kotulska, W. Dyrka, and P. Sadowski Electroporation of Lipid Membranes: Insights from Molecular Dynamics Simulations, M. Tarek and L. Delemotte Nanoscale Restructuring of Lipid Bilayers in Nanosecond electrical Fields, P.T. Vernier Mechanisms of Electroporation of Cells Nanopores: a unique Transmembrane Passageway in Electroporated Cells, A.G. Pakhomov and O.N. Pakhomova version of mobile Membrane Electroporation and Transmembrane Molecular shipping, D. Miklavcic and L. Towhidi Kinetics of Pore Formation and Disappearance within the phone in the course of Electroporation, G. Saulis the heart beat Intensity-Duration Dependency for cellphone Membrane Electroporation, D. Miklavcic, G. Pucihar, A.M. Lebar, J. Krmelj, and L. Towhidi Mechanisms of Electroporation in Tissues Drug-Free, sturdy Tumor Ablation via Electroporating Pulses: Mechanisms That Couple to Necrotic and Apoptotic cellphone loss of life Pathways, A.T. Esser, K.C. Smith, T.R. Gowrishankar, and J.C. Weaver Gene Electrotransfer: From easy strategies to Preclinical purposes, J.-M. Escoffre, A. Paganin-Gioanni, E. Bellard, M. Golzio, M.-P. Rols, and J. Teissie Technical issues Modeling electrical box Distribution In Vivo, N. Pavselj, A. Zupanic, and D. Miklavcic techniques of Electroporation Pulse iteration and assessment of electrical Pulse turbines for mobilephone and Tissue Electroporation, M. Rebersek and D. Miklavcic iteration of Ultrashort Pulses, J.F. Kolb Nanosecond Pulsed electrical box supply to organic Samples: problems and capability recommendations, A. Silve, J. Villemejane, V. Joubert, A. Ivorra, and L.M. Mir purposes of Electroporation Translation of Electroporation-Mediated DNA supply to the health facility, L.C. Heller and R. Heller scientific Electrochemotherapy: The Italian event, C.R. Rossi and L.G. Campana Tumor Blood Flow-Modifying results of Electroporation and Electrochemotherapy-Experimental facts and Implications for the treatment, T. Jarm, M. Cemazar, and G. Sersa lectrochemotherapy as a part of an Immunotherapy process within the therapy of melanoma, J. Gehl ombined electric box and Ultrasound: A Nondrug-Based technique for Tumor Ablation, P.F. Forde, C. Twomey, G.C. O' Sullivan, and D. M. Soden mixed Modality treatment: Electrochemotherapy with Tumor Irradiation, G. Sersa, S. Kranjc, and M. Cemazar Irreversible Electroporation in drugs, B. Rubinsky nutrition and Biomaterials Processing Assisted by means of Electroporation, N. Lebovka and E. Vorobiev In Vivo Electroporation: a huge harm Mechanism in electric surprise Trauma, I. Barakat, J. Gallaher, H. Chen, and R.C. Lee Index summary: Reflecting the serious learn of the consequences of electromagnetic fields on dwelling tissues that has taken position through the years, this name summarizes the experimental findings and theories concerning permeabilization of biomembranes by way of pulsed electrical fields. it's meant largely for biomedical and actual scientists, engineers, and clinicians. learn more...

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Initially, the cells took up the dye. After a certain time, generally about 1 h, the membranes of most of the cells seemed to have lost their permeability and the dye was excluded. These results indicate that nsPEFs have significant effects on the structure of the plasma ­membrane, but under certain conditions the structural changes are reversible. The time required to return to the control state can be considered as a recovery time, presumably to allow for “repair” of the structure and function.

Electr. , 16, 1224, 2009a. ) © 2010 by Taylor and Francis Group, LLC Bioelectric Effect of Intense Nanosecond Pulses 43 for Qn = 1 can be considered to be a “strength-duration” relationship between the threshold electric field intensity of a square wave pulse and its duration (Reilly, 1998). What is obvious from these curves is that for En large compared to one, which is the case in most of the bioelectric studies with pulse durations below 100 ns, the product of E and τ is constant. That means that electropermeabilization at high electric fields can be considered an electric impulse effect, rather than a dose effect.

E, 72, 031902-1–031902-10. , 2001, Self-consistent simulations of electroporation dynamics in biological cells subjected to ultrafast electrical pulses, Phys. Rev. E, 64, 11913-01–11913-03. , 2002, Improved energy model for membrane electroporation in biological cells subjected to electrical pulses, Phys. Rev. E, 65, 041920-01–041920-07. , 2004a, Energy-landscape-model analysis for irreversibility and its pulse-width dependence in cells subjected to a high-intensity ultrashort electrical pulse, Phys.

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