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Items: 1 to 20 of 87

1.

Modeling the induction of lipid membrane electropermeabilization.

Kotulska M, Kubica K, Koronkiewicz S, Kalinowski S.

Bioelectrochemistry. 2007 Jan;70(1):64-70. Epub 2006 Apr 5.

PMID:
16731051
2.

Computer simulation studies on the significance of lipid polar head charge.

Kubica K.

Cell Mol Biol Lett. 2002;7(4):971-82. Erratum in: Cell Mol Biol Lett. 2003;8(3):857.

PMID:
12511966
3.

Model of cell electrofusion. Membrane electroporation, pore coalescence and percolation.

Sugar IP, Förster W, Neumann E.

Biophys Chem. 1987 May 9;26(2-3):321-35.

PMID:
3607233
4.

Interface water dynamics and porating electric fields for phospholipid bilayers.

Ziegler MJ, Vernier PT.

J Phys Chem B. 2008 Oct 30;112(43):13588-96. doi: 10.1021/jp8027726. Epub 2008 Oct 7. Erratum in: J Phys Chem B. 2008 Dec 25;112(51):17003.

PMID:
18837540
5.

Stochastic model for electric field-induced membrane pores. Electroporation.

Sugar IP, Neumann E.

Biophys Chem. 1984 May;19(3):211-25.

PMID:
6722274
6.

Monte Carlo simulation towards ripple phase modelling.

Kubica K.

Comput Chem. 2001 May;25(3):245-50.

PMID:
11339407
7.

The effect of resting transmembrane voltage on cell electropermeabilization: a numerical analysis.

Valic B, Pavlin M, Miklavcic D.

Bioelectrochemistry. 2004 Jun;63(1-2):311-5.

PMID:
15110294
8.

A pore creation in a triangular network model membrane.

Kubica K.

Comput Biol Chem. 2008 Jun;32(3):163-6. doi: 10.1016/j.compbiolchem.2008.02.001. Epub 2008 Feb 12.

PMID:
18356110
9.

Osmotically induced membrane tension facilitates the triggering of living cell electropermeabilization.

Barrau C, Teissié J, Gabriel B.

Bioelectrochemistry. 2004 Jun;63(1-2):327-32.

PMID:
15110297
10.

Membrane electroporation theories: a review.

Chen C, Smye SW, Robinson MP, Evans JA.

Med Biol Eng Comput. 2006 Mar;44(1-2):5-14. Review.

PMID:
16929916
11.

Quantitative model of small molecules uptake after in vitro cell electropermeabilization.

Puc M, Kotnik T, Mir LM, Miklavcic D.

Bioelectrochemistry. 2003 Aug;60(1-2):1-10.

PMID:
12893304
12.

Lipids, proteins, and their interplay in the dynamics of temperature-stressed membranes of a cyanobacterium, Synechocystis PCC 6803.

Laczkó-Dobos H, Szalontai B.

Biochemistry. 2009 Oct 27;48(42):10120-8. doi: 10.1021/bi9011034.

PMID:
19788309
13.

Numerical modeling for in vivo electroporation.

Semrov D, Miklavčič D.

Methods Mol Med. 2000;37:63-81. doi: 10.1385/1-59259-080-2:63.

PMID:
21445729
14.

Lateral diffusion of molecules in two-component lipid bilayer: a Monte Carlo simulation study.

Sugár IP, Biltonen RL.

J Phys Chem B. 2005 Apr 21;109(15):7373-86.

PMID:
16851844
15.

Theoretical and experimental analysis of conductivity, ion diffusion and molecular transport during cell electroporation--relation between short-lived and long-lived pores.

Pavlin M, Miklavcic D.

Bioelectrochemistry. 2008 Nov;74(1):38-46. doi: 10.1016/j.bioelechem.2008.04.016. Epub 2008 Apr 18.

PMID:
18499534
16.

Determination of the lipid bilayer breakdown voltage by means of linear rising signal.

Kramar P, Miklavcic D, Lebar AM.

Bioelectrochemistry. 2007 Jan;70(1):23-7. Epub 2006 Apr 5.

PMID:
16713748
17.

How lipids and proteins interact in a membrane: a molecular approach.

Lee AG.

Mol Biosyst. 2005 Sep;1(3):203-12. Epub 2005 Jul 14. Review.

PMID:
16880984
18.
19.

Effect of pore size on the calculated pressure at biological cells pore wall.

El-Hag AH, Zheng Z, Boggs SA, Jayaram SH.

IEEE Trans Nanobioscience. 2006 Sep;5(3):157-63.

PMID:
16999240
20.

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