S. Chiruvolu scite author profile

The phase behavior and aggregate morphology of mixtures of the oppositely charged surfactants cetyltrimethylammonium bromide (CTAB) and sodium octyl sulfate (SOS) are explored with cryotransmission electron microscopy, quasielastic light scattering, and surface tensiometry. Differences in the lengths of the two hydrophobic chains stabilize vesicles relative to other microstructures (e.g., liquid crystalline and precipitate phases), and vesicles form spontaneously over a wide range of compositions in both CTAB-rich and SOS-rich solutions. Bilayer properties of the vesicles depend on the ratio of CTAB to SOS, with CTAB-rich bilayers stiffer than SOS-rich ones. We observe two modes of microstructural transition between micelles and vesicles. The first transition, between rodlike micelles and vesicles, is first order, and so there is macroscopic phase separation. This transition occurs in CTAB-rich solutions and in SOS-rich solutions at higher surfactant concentrations. In the second transition mode, mixtures rich in SOS at low surfactant concentrations exhibit no phase separation. Instead, small micelles abruptly transform into vesicles over a narrow range of surfactant concentration. Since the vesicles that form in mixtures of oppositely charged surfactants are equilibrium microstructures, the microstructural evolution is related solely to the phase transition and is thus under thermodynamic control. This differs from experiments reported on the dissolution of metastable vesicles, such as the detergent solubilization of biological phospholipid membranes, which may be controlled by kinetics. Despite these differences, we find that the evolution in microstructure in our mixtures of oppositely charged surfactants is analogous to that reported for biological membrane solubilization.

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Phase behavior of aqueous mixtures of dodecyltrimethylammonium bromide (DTAB) and sodium dodecyl sulfate (SDS)

Herrington¹,

Kaler²,

Miller³

et al. 1993

J. Phys. Chem.

367

386

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Higher Order Self-Assembly of Vesicles by Site-Specific Binding

Chiruvolu

Walker

Israelachvili

et al. 1994

Science

198

188

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The association of lipid molecules into spherical vesicles in solution as a result of non-specific intermolecular forces constitutes a primary self-assembly process. Such vesicles can undergo a secondary self-assembly into higher order structures in a controlled and reversible manner by means of site-specific ligand-receptor (biotin-streptavidin) coupling. Cryoelectron microscopy shows these structures to be composed of tethered, rather than adhering, vesicles in their original, unstressed state. In contrast, vesicles aggregated by nonspecific, such as van der Waals, forces are deformed and stressed, producing unstable structures. Vesicle association by site-specific binding provides a practical mechanism for the production of stable, yet controllable, microstructured biomaterials.

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Conformations of a Tethered Membrane: Crumpling in Graphitic Oxide?

et al. 1994

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A Phase of Liposomes with Entangled Tubular Vesicles

Chiruvolu

Warriner

Naranjo

et al. 1994

Science

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An equilibrium phase belonging to the family of bilayer liposomes in ternary mixtures of dimyristoylphosphatidylcholine (DMPC), water, and geraniol (a biological alcohol derived from oil-soluble vitamins that acts as a cosurfactant) has been identified. Electron and optical microscopy reveal the phase, labeled L tv , to be composed of highly entangled tubular vesicles. In situ x-ray diffraction confirms that the tubule walls are multilamellar with the lipids in the chain-melted state. Macroscopic observations show that the L tv phase coexists with the well-known L 4 phase of spherical vesicles and a bulk L α phase. However, the defining characteristic of the L tv phase is the Weissenberg rod climbing effect under shear, which results from its polymer-like entangled microstructure.

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S. Chiruvolu

Phase Behavior of Aqueous Mixtures of Cetyltrimethylammonium Bromide (CTAB) and Sodium Octyl Sulfate (SOS)

Phase behavior of aqueous mixtures of dodecyltrimethylammonium bromide (DTAB) and sodium dodecyl sulfate (SDS)

Higher Order Self-Assembly of Vesicles by Site-Specific Binding

Conformations of a Tethered Membrane: Crumpling in Graphitic Oxide?

A Phase of Liposomes with Entangled Tubular Vesicles

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