Yeh Wei Kho scite author profile

The surface activities of lysozyme and dipalmitoyl phosphatidylcholine (DPPC) vesicles at aqueous/compressed fluid interfaces are examined via high-pressure interfacial tension measurements using the pendant drop technique. The density and interfacial tension in compressible fluid systems vary significantly with pressure, providing a versatile medium for elucidating interactions between biomolecules and fluid interfaces and a method to elicit pressure-dependent interfacial morphological responses. The effects of lysozyme concentration (0.0008, 0.01, and 1 mg/mL) and pressure (> or = 7 MPa) on the dynamic surface response in the presence of ethane, propane, N2, and CO2 at 298 K were examined. Interfacial lysozyme adsorption reduced the induction phase and quickly led to interfacial tensions consistent with protein conformational changes and monolayer saturation at the compressed fluid interfaces. Protein adsorption, as indicated by surface pressure, correlated with calculated Hamaker constants for the compressed gases, denoting the importance of dispersion interactions. For DPPC at aqueous/compressed or aqueous/supercritical CO2 interfaces (1.8-20.7 MPa, 308 K), 2-3-fold reductions in interfacial tension were observed relative to the pure binary fluid system. The resulting surface pressures infer pressure-dependent morphological changes within the DPPC monolayer.

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Phase Behavior of CO₂-Expanded Fluorinated Microemulsions

Kho

Conrad

Knutson

2004

Langmuir

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The formation of CO2-expanded, fluorinated reverse microemulsions is demonstrated for the system of perfluoropolyether (PFPE) surfactant (ClPFPE-NH4, MW = 632) and PFPE oil (PFPE, MW = 580). The phase behavior of this system is examined as a function of temperature (25-45 degrees C), pressure, CO2 concentration, and water to surfactant molar ratios (W0 = 10 and 20). Visual observations of one-phase behavior consistent with reverse microemulsion formation are further supported by spectroscopic measurements that establish the existence of a bulk water environment within the aqueous core. Microemulsion formation is not observed in the absence of CO2 for this PFPE surfactant/PFPE oil system, and a CO2 content greater than 70 mol % is required to induce microemulsion formation. Over the range of water loadings and temperatures investigated, the lowest cloud point pressure is observed at 46 bar (5 wt % ClPFPE-NH4 in PFPE oil, W0 = 20, xCO2 = 0.7, T = 25 degrees C). In the regions where one-phase behavior is observed, the cloud point pressures increase with temperature, water loadings, and CO2 content. The driving forces of microemulsion formation in the CO2-expanded fluorinated solvent are discussed relative to traditional reverse microemulsions and CO2-continuous microemulsions.

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Solvent Strength Characterization of Carbon Dioxide Expanded Fluorinated Solvents

Kho

Conrad

Shick

et al. 2003

Ind. Eng. Chem. Res.

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Yeh Wei Kho

Precipitation of Nylon 6 membranes using compressed carbon dioxide

Phase equilibria and thermophysical properties of carbon dioxide-expanded fluorinated solvents

Surface Activity of Lysozyme and Dipalmitoyl Phosphatidylcholine Vesicles at Compressed and Supercritical Fluid Interfaces

Phase Behavior of CO₂-Expanded Fluorinated Microemulsions

Solvent Strength Characterization of Carbon Dioxide Expanded Fluorinated Solvents

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About

Yeh Wei Kho

Precipitation of Nylon 6 membranes using compressed carbon dioxide

Phase equilibria and thermophysical properties of carbon dioxide-expanded fluorinated solvents

Surface Activity of Lysozyme and Dipalmitoyl Phosphatidylcholine Vesicles at Compressed and Supercritical Fluid Interfaces

Phase Behavior of CO2-Expanded Fluorinated Microemulsions

Solvent Strength Characterization of Carbon Dioxide Expanded Fluorinated Solvents

Contact Info

Product

Resources

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Phase Behavior of CO₂-Expanded Fluorinated Microemulsions