High-Voltage Electrical Pulses in Oncology: Irreversible Electroporation, Electrochemotherapy, Gene Electrotransfer, Electrofusion, and Electroimmunotherapy

Bart Geboers; Hester J Scheffer; Philip M Graybill; Alette H Ruarus; Sanne Nieuwenhuizen; Robbert S Puijk; Petrousjka M van den Tol; Rafael V Davalos; Boris Rubinsky; Tanja D de Gruijl; Damijan Miklavčič; Martijn R Meijerink

doi:https://doi.org/10.1148/radiol.2020192190

High-Voltage Electrical Pulses in Oncology: Irreversible Electroporation, Electrochemotherapy, Gene Electrotransfer, Electrofusion, and Electroimmunotherapy

Bart Geboers, Hester J Scheffer, Philip M Graybill, Alette H Ruarus, Sanne Nieuwenhuizen, Robbert S Puijk, Petrousjka M van den Tol, Rafael V Davalos, Boris Rubinsky, Tanja D de Gruijl, Damijan Miklavčič, Martijn R Meijerink

Research output: Contribution to journal › Review article › Academic › peer-review

211 Citations (Scopus)

Abstract

This review summarizes the use of high-voltage electrical pulses (HVEPs) in clinical oncology to treat solid tumors with irreversible electroporation (IRE) and electrochemotherapy (ECT). HVEPs increase the membrane permeability of cells, a phenomenon known as electroporation. Unlike alternative ablative therapies, electroporation does not affect the structural integrity of surrounding tissue, thereby enabling tumors in the vicinity of vital structures to be treated. IRE uses HVEPs to cause cell death by inducing membrane disruption, and it is primarily used as a radical ablative therapy in the treatment of soft-tissue tumors in the liver, kidney, prostate, and pancreas. ECT uses HVEPs to transiently increase membrane permeability, enhancing cellular cytotoxic drug uptake in tumors. IRE and ECT show immunogenic effects that could be augmented when combined with immunomodulatory drugs, a combination therapy the authors term electroimmunotherapy. Additional electroporation-based technologies that may reach clinical importance, such as gene electrotransfer, electrofusion, and electroimmunotherapy, are concisely reviewed. HVEPs represent a substantial advancement in cancer research, and continued improvement and implementation of these presented technologies will require close collaboration between engineers, interventional radiologists, medical oncologists, and immuno-oncologists.

Original language	English
Pages (from-to)	254-272
Number of pages	19
Journal	Radiology
Volume	295
Issue number	2
DOIs	https://doi.org/10.1148/radiol.2020192190
Publication status	Published - 1 May 2020

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Geboers, B., Scheffer, H. J., Graybill, P. M., Ruarus, A. H., Nieuwenhuizen, S., Puijk, R. S., van den Tol, P. M., Davalos, R. V., Rubinsky, B., de Gruijl, T. D., Miklavčič, D., & Meijerink, M. R. (2020). High-Voltage Electrical Pulses in Oncology: Irreversible Electroporation, Electrochemotherapy, Gene Electrotransfer, Electrofusion, and Electroimmunotherapy. Radiology, 295(2), 254-272. https://doi.org/10.1148/radiol.2020192190

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title = "High-Voltage Electrical Pulses in Oncology: Irreversible Electroporation, Electrochemotherapy, Gene Electrotransfer, Electrofusion, and Electroimmunotherapy",

abstract = "This review summarizes the use of high-voltage electrical pulses (HVEPs) in clinical oncology to treat solid tumors with irreversible electroporation (IRE) and electrochemotherapy (ECT). HVEPs increase the membrane permeability of cells, a phenomenon known as electroporation. Unlike alternative ablative therapies, electroporation does not affect the structural integrity of surrounding tissue, thereby enabling tumors in the vicinity of vital structures to be treated. IRE uses HVEPs to cause cell death by inducing membrane disruption, and it is primarily used as a radical ablative therapy in the treatment of soft-tissue tumors in the liver, kidney, prostate, and pancreas. ECT uses HVEPs to transiently increase membrane permeability, enhancing cellular cytotoxic drug uptake in tumors. IRE and ECT show immunogenic effects that could be augmented when combined with immunomodulatory drugs, a combination therapy the authors term electroimmunotherapy. Additional electroporation-based technologies that may reach clinical importance, such as gene electrotransfer, electrofusion, and electroimmunotherapy, are concisely reviewed. HVEPs represent a substantial advancement in cancer research, and continued improvement and implementation of these presented technologies will require close collaboration between engineers, interventional radiologists, medical oncologists, and immuno-oncologists.",

author = "Bart Geboers and Scheffer, {Hester J} and Graybill, {Philip M} and Ruarus, {Alette H} and Sanne Nieuwenhuizen and Puijk, {Robbert S} and {van den Tol}, {Petrousjka M} and Davalos, {Rafael V} and Boris Rubinsky and {de Gruijl}, {Tanja D} and Damijan Miklav{\v c}i{\v c} and Meijerink, {Martijn R}",

note = "Funding Information: Disclosures of Conflicts of Interest: B.G. Activities related to the present article: Angiodynamics indirectly supported conduction of the illustrations without influencing the content by providing financial support to Dana Hamers Scientific Art. Activities not related to the present article: institution has a pending grant from Adessium Foundation and Cancer Center Amsterdam for future research on pancreatic IRE research; PANFIRE III trial. Other relationships: disclosed no relevant relationships. H.J.S. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: institution has a pending grant from Adessium Foundation and Cancer Center Amsterdam for future research on pancreatic IRE research; PANFIRE III trial. Other relationships: disclosed no relevant relationships. P.M.G. disclosed no relevant relationships. A.H.R. disclosed no relevant relationships. S.N. disclosed no relevant relationships. R.S.P. disclosed no relevant relationships. P.M.v.d.T. disclosed no relevant relationships. R.V.D. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: is on the scientific advisory board of CytoRecovery; received a grant from AngioDynamics; receives royalties from patents licensed to AngioDynamics from Berkeley and Virginia Tech; received compensation and/or reimbursement for meeting sessions hosted by AngioDynamics and Novocure and was reimbursed for travel by AngioDynamics and VoltMed; has a start-up company, VoltMed. Other relationships: disclosed no relevant relationships. B.R. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: University of California Berkeley holds a patent on irreversible electroproration and receives royalties from AngioDynamics. Other relationships: disclosed no relevant relationships. T.D.d.G. disclosed no relevant relationships. D.M. Activities related to the present article: institution received a grant from IGEA; was a consultant for IGEA; receives royalties for patent licenses from IGEA. Activities not related to the present article: is a consultant for Medtronic; institution received a grant from Medtronic; gave a lecture for Medtronic at the S&T Conference in 2018; has a pending patent application for cardiac ablation by pulsed field ablation submitted by Medtronic. Other relationships: disclosed no relevant relationships. M.R.M. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: is a consultant and gives presentations for AngioDynamics; institution received a grant for the CROSS-FIRE trial; was an editor for Springer. Other relationships: disclosed no relevant relationships. Publisher Copyright: {\textcopyright} RSNA, 2020. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.",

year = "2020",

month = may,

day = "1",

doi = "https://doi.org/10.1148/radiol.2020192190",

language = "English",

volume = "295",

pages = "254--272",

journal = "Radiology",

issn = "0033-8419",

publisher = "Radiological Society of North America Inc.",

number = "2",

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Geboers, B , Scheffer, HJ, Graybill, PM, Ruarus, AH, Nieuwenhuizen, S, Puijk, RS , van den Tol, PM, Davalos, RV, Rubinsky, B, de Gruijl, TD, Miklavčič, D & Meijerink, MR 2020, 'High-Voltage Electrical Pulses in Oncology: Irreversible Electroporation, Electrochemotherapy, Gene Electrotransfer, Electrofusion, and Electroimmunotherapy', Radiology, vol. 295, no. 2, pp. 254-272. https://doi.org/10.1148/radiol.2020192190

TY - JOUR

T1 - High-Voltage Electrical Pulses in Oncology

T2 - Irreversible Electroporation, Electrochemotherapy, Gene Electrotransfer, Electrofusion, and Electroimmunotherapy

AU - Geboers, Bart

AU - Scheffer, Hester J

AU - Graybill, Philip M

AU - Ruarus, Alette H

AU - Nieuwenhuizen, Sanne

AU - Puijk, Robbert S

AU - van den Tol, Petrousjka M

AU - Davalos, Rafael V

AU - Rubinsky, Boris

AU - de Gruijl, Tanja D

AU - Miklavčič, Damijan

AU - Meijerink, Martijn R

N1 - Funding Information: Disclosures of Conflicts of Interest: B.G. Activities related to the present article: Angiodynamics indirectly supported conduction of the illustrations without influencing the content by providing financial support to Dana Hamers Scientific Art. Activities not related to the present article: institution has a pending grant from Adessium Foundation and Cancer Center Amsterdam for future research on pancreatic IRE research; PANFIRE III trial. Other relationships: disclosed no relevant relationships. H.J.S. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: institution has a pending grant from Adessium Foundation and Cancer Center Amsterdam for future research on pancreatic IRE research; PANFIRE III trial. Other relationships: disclosed no relevant relationships. P.M.G. disclosed no relevant relationships. A.H.R. disclosed no relevant relationships. S.N. disclosed no relevant relationships. R.S.P. disclosed no relevant relationships. P.M.v.d.T. disclosed no relevant relationships. R.V.D. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: is on the scientific advisory board of CytoRecovery; received a grant from AngioDynamics; receives royalties from patents licensed to AngioDynamics from Berkeley and Virginia Tech; received compensation and/or reimbursement for meeting sessions hosted by AngioDynamics and Novocure and was reimbursed for travel by AngioDynamics and VoltMed; has a start-up company, VoltMed. Other relationships: disclosed no relevant relationships. B.R. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: University of California Berkeley holds a patent on irreversible electroproration and receives royalties from AngioDynamics. Other relationships: disclosed no relevant relationships. T.D.d.G. disclosed no relevant relationships. D.M. Activities related to the present article: institution received a grant from IGEA; was a consultant for IGEA; receives royalties for patent licenses from IGEA. Activities not related to the present article: is a consultant for Medtronic; institution received a grant from Medtronic; gave a lecture for Medtronic at the S&T Conference in 2018; has a pending patent application for cardiac ablation by pulsed field ablation submitted by Medtronic. Other relationships: disclosed no relevant relationships. M.R.M. Activities related to the present article: disclosed no relevant relationships. Activities not related to the present article: is a consultant and gives presentations for AngioDynamics; institution received a grant for the CROSS-FIRE trial; was an editor for Springer. Other relationships: disclosed no relevant relationships. Publisher Copyright: © RSNA, 2020. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.

PY - 2020/5/1

Y1 - 2020/5/1

N2 - This review summarizes the use of high-voltage electrical pulses (HVEPs) in clinical oncology to treat solid tumors with irreversible electroporation (IRE) and electrochemotherapy (ECT). HVEPs increase the membrane permeability of cells, a phenomenon known as electroporation. Unlike alternative ablative therapies, electroporation does not affect the structural integrity of surrounding tissue, thereby enabling tumors in the vicinity of vital structures to be treated. IRE uses HVEPs to cause cell death by inducing membrane disruption, and it is primarily used as a radical ablative therapy in the treatment of soft-tissue tumors in the liver, kidney, prostate, and pancreas. ECT uses HVEPs to transiently increase membrane permeability, enhancing cellular cytotoxic drug uptake in tumors. IRE and ECT show immunogenic effects that could be augmented when combined with immunomodulatory drugs, a combination therapy the authors term electroimmunotherapy. Additional electroporation-based technologies that may reach clinical importance, such as gene electrotransfer, electrofusion, and electroimmunotherapy, are concisely reviewed. HVEPs represent a substantial advancement in cancer research, and continued improvement and implementation of these presented technologies will require close collaboration between engineers, interventional radiologists, medical oncologists, and immuno-oncologists.

AB - This review summarizes the use of high-voltage electrical pulses (HVEPs) in clinical oncology to treat solid tumors with irreversible electroporation (IRE) and electrochemotherapy (ECT). HVEPs increase the membrane permeability of cells, a phenomenon known as electroporation. Unlike alternative ablative therapies, electroporation does not affect the structural integrity of surrounding tissue, thereby enabling tumors in the vicinity of vital structures to be treated. IRE uses HVEPs to cause cell death by inducing membrane disruption, and it is primarily used as a radical ablative therapy in the treatment of soft-tissue tumors in the liver, kidney, prostate, and pancreas. ECT uses HVEPs to transiently increase membrane permeability, enhancing cellular cytotoxic drug uptake in tumors. IRE and ECT show immunogenic effects that could be augmented when combined with immunomodulatory drugs, a combination therapy the authors term electroimmunotherapy. Additional electroporation-based technologies that may reach clinical importance, such as gene electrotransfer, electrofusion, and electroimmunotherapy, are concisely reviewed. HVEPs represent a substantial advancement in cancer research, and continued improvement and implementation of these presented technologies will require close collaboration between engineers, interventional radiologists, medical oncologists, and immuno-oncologists.

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U2 - https://doi.org/10.1148/radiol.2020192190

DO - https://doi.org/10.1148/radiol.2020192190

M3 - Review article

C2 - 32208094

SN - 0033-8419

VL - 295

SP - 254

EP - 272

JO - Radiology

JF - Radiology

IS - 2

ER -

High-Voltage Electrical Pulses in Oncology: Irreversible Electroporation, Electrochemotherapy, Gene Electrotransfer, Electrofusion, and Electroimmunotherapy

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