Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains

Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains

Picosecond pulse trains (psPTs) are emerging as a new characteristic diagnostic and therapeutic tool in biomedical fields. To specifically determine the stimulus provided to cells, in this article, we use a molecular dynamics (MD) model to show the molecular mechanisms of electroporation induced by...

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Main Authors: Tang, Jingchao, Ma, Jialu, Guo, Lianghao, Wang, Kaicheng, Yang, Yang, Bo, Wenfei, Yang, Lixia, Wang, Zhao, Jiang, Haibo, Wu, Zhe, Zeng, Baoqing, Gong, Yubin
Other Authors: School of Physical and Mathematical Sciences
Format: Article
Language:English
Published: 2021
Subjects:
Science::Physics
Electroporation
Molecular Dynamics
Online Access:https://hdl.handle.net/10356/152154
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1521542021-09-13T08:26:12Z Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains Tang, Jingchao Ma, Jialu Guo, Lianghao Wang, Kaicheng Yang, Yang Bo, Wenfei Yang, Lixia Wang, Zhao Jiang, Haibo Wu, Zhe Zeng, Baoqing Gong, Yubin School of Physical and Mathematical Sciences Science::Physics Electroporation Molecular Dynamics Picosecond pulse trains (psPTs) are emerging as a new characteristic diagnostic and therapeutic tool in biomedical fields. To specifically determine the stimulus provided to cells, in this article, we use a molecular dynamics (MD) model to show the molecular mechanisms of electroporation induced by symmetrical bipolar psPTs and predict a bipolar cancellation for the studied picosecond pulses. Electric field conditions that do not cause electroporation reveal that the interfacial water molecules continuously flip and redirect as the applied bipolar psPT reverses, and the molecules cannot keep moving in one direction or leave the lipid-water interface. Based on our simulation results, we determine the threshold for electroporation with symmetrical bipolar psPTs. For a fixed electric field intensity, a lower repetition frequency leads to more rapid electroporation. For a fixed repetition frequency, a higher electric field intensity leads to more rapid electroporation. We found that the water dipole relaxation time decreases as the electric field magnitude increases. Additionally, the influences of the symmetrical bipolar psPT intensity and frequency on the pore formation time are presented. Discrete nanoscale pores can form with the applied psPT at terahertz (THz) repetition frequency. When the psPT amplitude increases or the frequency decreases, the number of water bridges will increase. Moreover, for the first time, the molecular mechanism of bipolar cancellation for the studied picosecond pulse is discussed preliminarily. Our results indicate that the influence of the unipolar picosecond pulse on the interfacial water dipoles will accumulate in one direction, but the bipolar picosecond pulse does not cause this effect. 2021-09-13T08:26:11Z 2021-09-13T08:26:11Z 2020 Journal Article Tang, J., Ma, J., Guo, L., Wang, K., Yang, Y., Bo, W., Yang, L., Wang, Z., Jiang, H., Wu, Z., Zeng, B. & Gong, Y. (2020). Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains. Biochimica et Biophysica Acta - Biomembranes, 1862(5), 183213-. https://dx.doi.org/10.1016/j.bbamem.2020.183213 0005-2728 https://hdl.handle.net/10356/152154 10.1016/j.bbamem.2020.183213 32057755 2-s2.0-85079399622 5 1862 183213 en Biochimica et Biophysica Acta - Biomembranes © 2020 Elsevier B.V. All rights reserved.
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Science::Physics
Electroporation
Molecular Dynamics
spellingShingle Science::Physics
Electroporation
Molecular Dynamics
Tang, Jingchao
Ma, Jialu
Guo, Lianghao
Wang, Kaicheng
Yang, Yang
Bo, Wenfei
Yang, Lixia
Wang, Zhao
Jiang, Haibo
Wu, Zhe
Zeng, Baoqing
Gong, Yubin
Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains
description Picosecond pulse trains (psPTs) are emerging as a new characteristic diagnostic and therapeutic tool in biomedical fields. To specifically determine the stimulus provided to cells, in this article, we use a molecular dynamics (MD) model to show the molecular mechanisms of electroporation induced by symmetrical bipolar psPTs and predict a bipolar cancellation for the studied picosecond pulses. Electric field conditions that do not cause electroporation reveal that the interfacial water molecules continuously flip and redirect as the applied bipolar psPT reverses, and the molecules cannot keep moving in one direction or leave the lipid-water interface. Based on our simulation results, we determine the threshold for electroporation with symmetrical bipolar psPTs. For a fixed electric field intensity, a lower repetition frequency leads to more rapid electroporation. For a fixed repetition frequency, a higher electric field intensity leads to more rapid electroporation. We found that the water dipole relaxation time decreases as the electric field magnitude increases. Additionally, the influences of the symmetrical bipolar psPT intensity and frequency on the pore formation time are presented. Discrete nanoscale pores can form with the applied psPT at terahertz (THz) repetition frequency. When the psPT amplitude increases or the frequency decreases, the number of water bridges will increase. Moreover, for the first time, the molecular mechanism of bipolar cancellation for the studied picosecond pulse is discussed preliminarily. Our results indicate that the influence of the unipolar picosecond pulse on the interfacial water dipoles will accumulate in one direction, but the bipolar picosecond pulse does not cause this effect.
author2 School of Physical and Mathematical Sciences
author_facet School of Physical and Mathematical Sciences
Tang, Jingchao
Ma, Jialu
Guo, Lianghao
Wang, Kaicheng
Yang, Yang
Bo, Wenfei
Yang, Lixia
Wang, Zhao
Jiang, Haibo
Wu, Zhe
Zeng, Baoqing
Gong, Yubin
format Article
author Tang, Jingchao
Ma, Jialu
Guo, Lianghao
Wang, Kaicheng
Yang, Yang
Bo, Wenfei
Yang, Lixia
Wang, Zhao
Jiang, Haibo
Wu, Zhe
Zeng, Baoqing
Gong, Yubin
author_sort Tang, Jingchao
title Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains
title_short Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains
title_full Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains
title_fullStr Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains
title_full_unstemmed Interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains
title_sort interpretation of the molecular mechanism of the electroporation induced by symmetrical bipolar picosecond pulse trains
publishDate 2021
url https://hdl.handle.net/10356/152154
_version_ 1712300625891426304

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