The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers: A theoretical study

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers : A theoretical study. / Zuckermann, M. J.; Mouritsen, O. G.

In: European Biophysics Journal, Vol. 15, No. 2, 1987, p. 77-86.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Zuckermann, MJ & Mouritsen, OG 1987, 'The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers: A theoretical study', European Biophysics Journal, vol. 15, no. 2, pp. 77-86. https://doi.org/10.1007/BF00257501

APA

Zuckermann, M. J., & Mouritsen, O. G. (1987). The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers: A theoretical study. European Biophysics Journal, 15(2), 77-86. https://doi.org/10.1007/BF00257501

Vancouver

Zuckermann MJ, Mouritsen OG. The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers: A theoretical study. European Biophysics Journal. 1987;15(2):77-86. https://doi.org/10.1007/BF00257501

Author

Zuckermann, M. J. ; Mouritsen, O. G. / The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers : A theoretical study. In: European Biophysics Journal. 1987 ; Vol. 15, No. 2. pp. 77-86.

Bibtex

@article{5ae0e117f91543788c05db1889b72173,
title = "The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers: A theoretical study",
abstract = "The main gel-fluid phase transition of wet lipid bilayers is examined in terms of a microscopic interaction model which incorporates both trans-gauche isomerism of the lipid acyl chains and crystal orientation variables for the lipid molecules. The model gives two scenarios for the phase behavior of wet lipid bilayers in terms of temperature: (i) chain melting occurs at a higher temperature than crystallization, or (ii) chain melting and crystallization occur at the same temperature. Experimental data for lipid bilayers is consistent with the second scenario. In this case, computer simulation is used to investigate the non-equilibrium behaviour of the model. The numerical data is intepreted in terms of interfacial melting on heating and grain formation on cooling through the main phase transition. Interfacial melting is a non-equilibrium process in which the grains of a polycrystalline bilayer melt inwards from the boundaries. The prediction of interfacial melting in wet lipid bilayers is examined in relation to data from both equilibrium and nonequilibrium measurements, to corresponding phase behavior in monolayers, and to previous theoretical work.",
keywords = "acyl chain ordering, crystallization, grain-boundary formation, interfacial melting, Lipid bilayer",
author = "Zuckermann, {M. J.} and Mouritsen, {O. G.}",
year = "1987",
doi = "10.1007/BF00257501",
language = "English",
volume = "15",
pages = "77--86",
journal = "European Biophysics Journal",
issn = "0175-7571",
publisher = "Springer",
number = "2",

}

RIS

TY - JOUR

T1 - The effects of acyl chain ordering and crystallization on the main phase transition of wet lipid bilayers

T2 - A theoretical study

AU - Zuckermann, M. J.

AU - Mouritsen, O. G.

PY - 1987

Y1 - 1987

N2 - The main gel-fluid phase transition of wet lipid bilayers is examined in terms of a microscopic interaction model which incorporates both trans-gauche isomerism of the lipid acyl chains and crystal orientation variables for the lipid molecules. The model gives two scenarios for the phase behavior of wet lipid bilayers in terms of temperature: (i) chain melting occurs at a higher temperature than crystallization, or (ii) chain melting and crystallization occur at the same temperature. Experimental data for lipid bilayers is consistent with the second scenario. In this case, computer simulation is used to investigate the non-equilibrium behaviour of the model. The numerical data is intepreted in terms of interfacial melting on heating and grain formation on cooling through the main phase transition. Interfacial melting is a non-equilibrium process in which the grains of a polycrystalline bilayer melt inwards from the boundaries. The prediction of interfacial melting in wet lipid bilayers is examined in relation to data from both equilibrium and nonequilibrium measurements, to corresponding phase behavior in monolayers, and to previous theoretical work.

AB - The main gel-fluid phase transition of wet lipid bilayers is examined in terms of a microscopic interaction model which incorporates both trans-gauche isomerism of the lipid acyl chains and crystal orientation variables for the lipid molecules. The model gives two scenarios for the phase behavior of wet lipid bilayers in terms of temperature: (i) chain melting occurs at a higher temperature than crystallization, or (ii) chain melting and crystallization occur at the same temperature. Experimental data for lipid bilayers is consistent with the second scenario. In this case, computer simulation is used to investigate the non-equilibrium behaviour of the model. The numerical data is intepreted in terms of interfacial melting on heating and grain formation on cooling through the main phase transition. Interfacial melting is a non-equilibrium process in which the grains of a polycrystalline bilayer melt inwards from the boundaries. The prediction of interfacial melting in wet lipid bilayers is examined in relation to data from both equilibrium and nonequilibrium measurements, to corresponding phase behavior in monolayers, and to previous theoretical work.

KW - acyl chain ordering

KW - crystallization

KW - grain-boundary formation

KW - interfacial melting

KW - Lipid bilayer

U2 - 10.1007/BF00257501

DO - 10.1007/BF00257501

M3 - Journal article

AN - SCOPUS:0011788757

VL - 15

SP - 77

EP - 86

JO - European Biophysics Journal

JF - European Biophysics Journal

SN - 0175-7571

IS - 2

ER -

ID: 238391393