Effects of pressure and temperature on the self-assembled fully hydrated nanostructures of monoolein - oil systems

Anan Yaghmur; Manfred Kriechbaum; Heinz Amenitsch; Milos Steinhart; Peter Laggner; Michael Rappolt

doi:10.1021/la9023019

Effects of pressure and temperature on the self-assembled fully hydrated nanostructures of monoolein - oil systems

Anan Yaghmur, Manfred Kriechbaum, Heinz Amenitsch, Milos Steinhart, Peter Laggner, Michael Rappolt

46 Citationer (Scopus)

Abstract

Synchrotron small-angle X-ray scattering (SAXS) was applied for studying the effects of hydrostatic pressure and temperature on the structural, behavior of fully hydrated tetradecane (TC)-loaded monoolein (MO) systems. Our main attention focused on investigating the impact of isobaric and isothermal changes on the stability of the inverted type discontinuous Fd3m cubic phase as compared to the inverted type hexagonal (H₂) liquid crystalline phase. The present results show that compressing the TC-loaded Fd3m phase under isothermal conditions induces a significant increase of its lattice parameter: it approximately increases by 1 A per 75 bar. Further, the Fd3m phase is more pressure-sensitive as compared to the Pn3m and the H₂ phases. At ambient temperatures, we observed the following structural, transitions as pressure increases: Fd3m →H₂→Pn3m. Our findings under isobaric conditions reveal more complicated structural transitions. At high pressures, we recorded the interesting temperature-induced structural transition of (Pn3m + L_α) → (Pn3m + L_α + H2) →(L_α + H₂) → H₂→Fd3m →traces of FdZm coexisting with. L₂. At high pressures and low temperatures, the TC molecules partially crystallize as indicated, by the appearance of an additional diffraction peak at q= 3.46 nm^-1. This crystallite disappears at high temperatures and also as the system gets decompressed. The appearance of the Pn3m and the L_α phases during compressing the fully hydrated MO/TC samples at high pressures and low temperatures is generally related to a growing hydrocarbon chain condensation, which leads to membrane leaflets with less negative interfacial curvatures (decreasing the spontaneous curvatures H_o). Both the effects of pressure and temperature are discussed in detail for all nonlamellar phases on the basis of molecular shape and packing concepts.

Originalsprog	Engelsk
Tidsskrift	Langmuir
Vol/bind	26
Udgave nummer	2
Sider (fra-til)	1177-1185
ISSN	0743-7463
DOI	https://doi.org/10.1021/la9023019
Status	Udgivet - 19 jan. 2010

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title = "Effects of pressure and temperature on the self-assembled fully hydrated nanostructures of monoolein - oil systems",

abstract = "Synchrotron small-angle X-ray scattering (SAXS) was applied for studying the effects of hydrostatic pressure and temperature on the structural, behavior of fully hydrated tetradecane (TC)-loaded monoolein (MO) systems. Our main attention focused on investigating the impact of isobaric and isothermal changes on the stability of the inverted type discontinuous Fd3m cubic phase as compared to the inverted type hexagonal (H2) liquid crystalline phase. The present results show that compressing the TC-loaded Fd3m phase under isothermal conditions induces a significant increase of its lattice parameter: it approximately increases by 1 A per 75 bar. Further, the Fd3m phase is more pressure-sensitive as compared to the Pn3m and the H2 phases. At ambient temperatures, we observed the following structural, transitions as pressure increases: Fd3m →H2→Pn3m. Our findings under isobaric conditions reveal more complicated structural transitions. At high pressures, we recorded the interesting temperature-induced structural transition of (Pn3m + Lα) → (Pn3m + Lα + H2) →(Lα + H2) → H2→Fd3m →traces of FdZm coexisting with. L2. At high pressures and low temperatures, the TC molecules partially crystallize as indicated, by the appearance of an additional diffraction peak at q= 3.46 nm-1. This crystallite disappears at high temperatures and also as the system gets decompressed. The appearance of the Pn3m and the Lα phases during compressing the fully hydrated MO/TC samples at high pressures and low temperatures is generally related to a growing hydrocarbon chain condensation, which leads to membrane leaflets with less negative interfacial curvatures (decreasing the spontaneous curvatures Ho). Both the effects of pressure and temperature are discussed in detail for all nonlamellar phases on the basis of molecular shape and packing concepts.",

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author = "Anan Yaghmur and Manfred Kriechbaum and Heinz Amenitsch and Milos Steinhart and Peter Laggner and Michael Rappolt",

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T1 - Effects of pressure and temperature on the self-assembled fully hydrated nanostructures of monoolein - oil systems

AU - Yaghmur, Anan

AU - Kriechbaum, Manfred

AU - Amenitsch, Heinz

AU - Steinhart, Milos

AU - Laggner, Peter

AU - Rappolt, Michael

PY - 2010/1/19

Y1 - 2010/1/19

N2 - Synchrotron small-angle X-ray scattering (SAXS) was applied for studying the effects of hydrostatic pressure and temperature on the structural, behavior of fully hydrated tetradecane (TC)-loaded monoolein (MO) systems. Our main attention focused on investigating the impact of isobaric and isothermal changes on the stability of the inverted type discontinuous Fd3m cubic phase as compared to the inverted type hexagonal (H2) liquid crystalline phase. The present results show that compressing the TC-loaded Fd3m phase under isothermal conditions induces a significant increase of its lattice parameter: it approximately increases by 1 A per 75 bar. Further, the Fd3m phase is more pressure-sensitive as compared to the Pn3m and the H2 phases. At ambient temperatures, we observed the following structural, transitions as pressure increases: Fd3m →H2→Pn3m. Our findings under isobaric conditions reveal more complicated structural transitions. At high pressures, we recorded the interesting temperature-induced structural transition of (Pn3m + Lα) → (Pn3m + Lα + H2) →(Lα + H2) → H2→Fd3m →traces of FdZm coexisting with. L2. At high pressures and low temperatures, the TC molecules partially crystallize as indicated, by the appearance of an additional diffraction peak at q= 3.46 nm-1. This crystallite disappears at high temperatures and also as the system gets decompressed. The appearance of the Pn3m and the Lα phases during compressing the fully hydrated MO/TC samples at high pressures and low temperatures is generally related to a growing hydrocarbon chain condensation, which leads to membrane leaflets with less negative interfacial curvatures (decreasing the spontaneous curvatures Ho). Both the effects of pressure and temperature are discussed in detail for all nonlamellar phases on the basis of molecular shape and packing concepts.

AB - Synchrotron small-angle X-ray scattering (SAXS) was applied for studying the effects of hydrostatic pressure and temperature on the structural, behavior of fully hydrated tetradecane (TC)-loaded monoolein (MO) systems. Our main attention focused on investigating the impact of isobaric and isothermal changes on the stability of the inverted type discontinuous Fd3m cubic phase as compared to the inverted type hexagonal (H2) liquid crystalline phase. The present results show that compressing the TC-loaded Fd3m phase under isothermal conditions induces a significant increase of its lattice parameter: it approximately increases by 1 A per 75 bar. Further, the Fd3m phase is more pressure-sensitive as compared to the Pn3m and the H2 phases. At ambient temperatures, we observed the following structural, transitions as pressure increases: Fd3m →H2→Pn3m. Our findings under isobaric conditions reveal more complicated structural transitions. At high pressures, we recorded the interesting temperature-induced structural transition of (Pn3m + Lα) → (Pn3m + Lα + H2) →(Lα + H2) → H2→Fd3m →traces of FdZm coexisting with. L2. At high pressures and low temperatures, the TC molecules partially crystallize as indicated, by the appearance of an additional diffraction peak at q= 3.46 nm-1. This crystallite disappears at high temperatures and also as the system gets decompressed. The appearance of the Pn3m and the Lα phases during compressing the fully hydrated MO/TC samples at high pressures and low temperatures is generally related to a growing hydrocarbon chain condensation, which leads to membrane leaflets with less negative interfacial curvatures (decreasing the spontaneous curvatures Ho). Both the effects of pressure and temperature are discussed in detail for all nonlamellar phases on the basis of molecular shape and packing concepts.

KW - Former Faculty of Pharmaceutical Sciences

U2 - 10.1021/la9023019

DO - 10.1021/la9023019

M3 - Journal article

C2 - 19681634

SN - 0743-7463

VL - 26

SP - 1177

EP - 1185

JO - Langmuir

JF - Langmuir

IS - 2

ER -

Effects of pressure and temperature on the self-assembled fully hydrated nanostructures of monoolein - oil systems

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