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Ferroelectrics Volume 220, 1999 - Issue 1
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Original Articles

Theoretical models of conformational transitions and ion conduction in voltage-dependent ion channels: Bioferroelectricity and superionic conduction

H. Richard Leuchtag Department of Biology, Texas Southern University, Houston, Texas, USA
&
Vladimir S. Bystrov Institute of Mathematical Problems of Biology, Pushchino State University, Moscow Region, Russia
Pages 157-204 | Published online: 15 Mar 2011

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F. V. Podgornov, R. Wipf, B. Stühn, A. V. Ryzhkova & W. Haase. (2016) Low-frequency relaxation modes in ferroelectric liquid crystal/gold nanoparticle dispersion: impact of nanoparticle shape. Liquid Crystals 43:11, pages 1536-1547.
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V.S. Bystrov, E. Seyedhosseini, I.K. Bdikin, S. Kopyl, A.L. Kholkin, S.G. Vasilev, P.S. Zelenovskiy, D.S. Vasileva & V.Ya. Shur. (2016) Glycine nanostructures and domains in beta-glycine: computational modeling and PFM observations. Ferroelectrics 496:1, pages 28-45.
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V. S. Bystrov, E. Seyedhosseini, I. Bdikin, S. Kopyl, S. M. Neumayer, J. Coutinho & A. L. Kholkin. (2015) Bioferroelectricity in Nanostructured Glycine and Thymine: Molecular Modeling and Ferroelectric Properties at the Nanoscale. Ferroelectrics 475:1, pages 107-126.
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V.S. Bystrov, E. Paramonova, I. Bdikin, S. Kopyl, A. Heredia, R.C. Pullar & A.L. Kholkin. (2012) BioFerroelectricity: Diphenylalanine Peptide Nanotubes Computational Modeling and Ferroelectric Properties at the Nanoscale. Ferroelectrics 440:1, pages 3-24.
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A. Jákli. (2010) Electro-mechanical effects in liquid crystals. Liquid Crystals 37:6-7, pages 825-837.
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N. Amdursky, P. Beker, J. Schklovsky, E. Gazit & G. Rosenman. (2010) Ferroelectric and Related Phenomena in Biological and Bioinspired Nanostructures. Ferroelectrics 399:1, pages 107-117.
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VLADIMIRS. BYSTROV, NATALIAK. BYSTROVA, EKATHERINAV. PARAMONOVA & ALLAV. SAPRONOVA. (2006) Computational Nanostructures and Physical Properties of the Ultra-Thin Ferroelectric Langmuir-Blodgett Films. Ferroelectrics Letters Section 33:5-6, pages 153-162.
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V.S. Bystrov, G.I. Ovtchinnikova, T.R. Tazieva, A.N. Soloshenko, Yu.A. Pirogov & V.K. Novik. (2001) Bioferroelectricity and related problems: Hydrogen-bonded ferroelectric-like systems. Ferroelectrics 258:1, pages 79-88.
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VladimirS. Bystrov. (2000) Models of proton dynamics and superprotonic/ionic conduction in hydrogen-bonded ferroelectrics and related (biological) systems. 1. Soliton dynamics in hydrogen-bonded systems. Ferroelectrics Letters Section 27:5-6, pages 147-159.
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H. Richard Leuchtag. (2000) Bioferroelectricity in models of voltage-dependent ion channels. Ferroelectrics 236:1, pages 23-33.
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Articles from other publishers (30)

H. Richard Leuchtag. (2023) On molecular steps that activate a voltage sensitive ion channel at critical depolarization. Biophysical Chemistry 301, pages 107078.
Crossref
A.K. Bystrov. The IMPB RAS is 50 years old. Group of Computer Modeling of Nanostructures and Biosystems. The IMPB RAS is 50 years old. Group of Computer Modeling of Nanostructures and Biosystems.
Oleg V. Gradov, Margaret A. Gradova & Valentin V. Kochervinskii. 2022. Organic Ferroelectric Materials and Applications. Organic Ferroelectric Materials and Applications 571 619 .
Yao Sun, Tao Li, Qiaomei Sun, Yuan Cheng & Kaiyang Zeng. (2020) Chain substitution caused sub-fibril level differences in electromechanical structure and property of wild-type and oim/oim collagen fibers. Journal of Applied Physics 128:23.
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Yao Sun, KaiYang Zeng & Tao Li. (2020) Piezo-/ferroelectric phenomena in biomaterials: A brief review of recent progress and perspectives. Science China Physics, Mechanics & Astronomy 63:7.
Crossref
V.S. Bystrov. (2018) Photoferroelectricity in di-phenylalanine peptide nanotubes. Computational Condensed Matter 14, pages 94-100.
Crossref
V.S. Bystrov, I.K. Bdikin, V.A. Tverdislov, O.A. Zhulyabina, P.S. Zelenovskiy & S.A. Kopyl. Physical ferroelectric and chiral properties of various dipeptide nanotubes and nanostructures. Physical ferroelectric and chiral properties of various dipeptide nanotubes and nanostructures.
A S Kalinin, V V Polyakov & V A Bykov. (2017) Hybrid mode piezoresponse force microscopy for compositional electromechanical study of biopiezoelectrics. Journal of Physics: Conference Series 917, pages 042018.
Crossref
X. Y. Liu, F. Yan, L. L. Niu, Q. N. Chen, H. R. Zheng & J. Y. Li. (2016) Strong correlation between early stage atherosclerosis and electromechanical coupling of aorta. Nanoscale 8:13, pages 6975-6980.
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Alok S. Tayi, Adrien Kaeser, Michio Matsumoto, Takuzo Aida & Samuel I. Stupp. (2015) Supramolecular ferroelectrics. Nature Chemistry 7:4, pages 281-294.
Crossref
V. S. Bystrov, E. Seyedhosseini, S. Kopyl, I. K. Bdikin & A. L. Kholkin. (2014) Piezoelectricity and ferroelectricity in biomaterials: Molecular modeling and piezoresponse force microscopy measurements. Journal of Applied Physics 116:6.
Crossref
Yuanming LiuHong-Ling CaiMatthew ZeliskoYunjie WangJinglan Sun, Fei Yan, Feiyue MaPeiqi WangQian Nataly ChenHairong Zheng, Xiangjian Meng, Pradeep SharmaYanhang ZhangJiangyu Li. (2014) Ferroelectric switching of elastin. Proceedings of the National Academy of Sciences 111:27.
Crossref
Jiangyu Li, Yuanming Liu, Yanhang Zhang, Hong-Ling Cai & Ren-Gen Xiong. (2013) Molecular ferroelectrics: where electronics meet biology. Physical Chemistry Chemical Physics 15:48, pages 20786.
Crossref
Igor Bdikin, Vladimir Bystrov, Svitlana Kopyl, Rui P. G. Lopes, Ivonne Delgadillo, José Gracio, Elena Mishina, Alexander Sigov & Andrei L. Kholkin. (2012) Evidence of ferroelectricity and phase transition in pressed diphenylalanine peptide nanotubes. Applied Physics Letters 100:4.
Crossref
Vladimir S. Bystrov, Igor K. Bdikin, Alejandro Heredia, Robert C. Pullar, Elena D. Mishina, Alexander S. Sigov & Andrei L. Kholkin. 2012. Piezoelectric Nanomaterials for Biomedical Applications. Piezoelectric Nanomaterials for Biomedical Applications 187 211 .
M. V. Sataric, L. Budinski-Petkovic, I. Loncarevic & J. A. Tuszynski. (2008) Modelling the Role of Intrinsic Electric Fields in Microtubules as an Additional Control Mechanism of Bi-directional Intracellular Transport. Cell Biochemistry and Biophysics 52:2, pages 113-124.
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. (2008) Voltage-gated Na Channels. Biophysical Journal 94:2, pages 1031-1041.
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. 2008. Voltage-Sensitive Ion Channels. Voltage-Sensitive Ion Channels 483 508 .
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V S Bystrov, N K Bystrova, E V Paramonova, G Vizdrik, A V Sapronova, M Kuehn, H Kliem & A L Kholkin. (2007) First principle calculations of molecular polarization switching in P(VDF–TrFE) ferroelectric thin Langmuir–Blodgett films. Journal of Physics: Condensed Matter 19:45, pages 456210.
Crossref
C. Halperin, S. Mutchnik, A. Agronin, M. Molotskii, P. Urenski, M. Salai & G. Rosenman. (2004) Piezoelectric Effect in Human Bones Studied in Nanometer Scale. Nano Letters 4:7, pages 1253-1256.
Crossref
Sugat Abeygunaratne, Antal Jákli, Götz Milkereit, Hans Sawade & Volkmar Vill. (2004) Antiferroelectric ordering of amphiphilic glycolipids in bent-core liquid crystals. Physical Review E 69:2.
Crossref
V. Bystrov, N. Bystrova, G. Ovtchinnikova, Yu. Pirogov & Yu. Dekhtyar. (2002) BioFerroelectricity and BioMedicine: new results and approaches. BioFerroelectricity and BioMedicine: new results and approaches.
V. Bystrov, M. Green, A. Sapronova, G. Ovtchinnikova, T. Tazieva, A. Soloshenko & B. Zapol. (2002) Hydrogen bonds and proton transfer in ferroelectrics and related materials (Molecular chains, proteins, DNA): ab initio Gaussian-98 calculations and soliton models. Hydrogen bonds and proton transfer in ferroelectrics and related materials (Molecular chains, proteins, DNA): ab initio Gaussian-98 calculations and soliton models.
O. Helluin, M. Beyermann, H.R. Leuchtag & H. Duclohier. (2001) A critical role for the branched sidechain adjacent to the third arginine of the sodium channel voltage sensor. IEEE Transactions on Dielectrics and Electrical Insulation 8:4, pages 637-643.
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George A. Samara. 2001. 239 458 .
S.B. Lang. (2000) Piezoelectricity, pyroelectricity and ferroelectricity in biomaterials: Speculation on their biological significance. IEEE Transactions on Dielectrics and Electrical Insulation 7:4, pages 466-473.
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S.B. Lang. (1999) Do the piezoelectric, pyroelectric and ferroelectric properties of biological materials have any physiological significance?. Do the piezoelectric, pyroelectric and ferroelectric properties of biological materials have any physiological significance?.

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