Nianhuan Chen

Correlation of AFM and SFA Measurements Concerning the Stability of Supported Lipid Bilayers

Phospholipid bilayers were studied by means of atomic force microscopy (AFM) and a surface force apparatus (SFA). The stability of the supported bilayers was described by the amount of irregularities in the topography of the membrane by means of AFM and by the occurrence of hemifusion in the SFA, which is an indicator of defective bilayers. The bilayers, composed of lipids having the same headgroup but different chain lengths in the two leaflets, were prepared by Langmuir-Blodgett deposition and transferred at different surface pressures. The topography of the supported bilayers in aqueous solution, as imaged by AFM, revealed an increasing number of defects in the supported lipid membranes with decreased deposition pressure of the outer lipid layer. These defects, which appeared in the form of monolayer and bilayer (self-assembled) thick holes within the membrane, were energetically favorable over an evenly depleted bilayer. We found that the quantity of these defects (holes of </=0.5 micro m diameter and covering up to 30% of the surface area) correlated well with the stability of the bilayers as measured by SFA, a truly complementary instrument.

Static Forces, Structure and Flow Properties of Complex Fluids in Highly Confined Geometries

The Surface Forces Apparatus has been successfully used to measure the static and dynamic forces between surfaces across ultra-thin films of water and aqueous electrolyte solutions, and—more recently—polyelectrolyte-coated and articular cartilage surfaces in various solutions including hyaluronan, lubricin, and synovial fluid. The results give new insights into the lubricating action of biological lubricants such as synovial fluid and hyaluronan (a polysaccharide in synovial fluid), and biological surfaces such as phospholipid bilayers and cartilage surfaces. Contrary to earlier indications of long-range water-structuring at biological surfaces, more recent measurements clearly show that the viscosity of physiologically concentrated water (saline) is bulk-like beyond the first 1 or 2 layers from a single surface, and beyond 4–6 layers in thin films between two surfaces (the structure and forces may, however, be affected to larger distances). This implies that most structural, interaction force, and viscosity-related phenomena are determined—not only by the properties of the solvent (water) per se—but also by the surfaces and the water, ions, solutes, and macromolecules (proteins, polymers) exposed or adsorbed at the surfaces and, to a lesser degree, dissolved in the solvent. However, sometimes it is difficult to make a clear differentiation, e.g., one could consider hydration or surface-bound ‘structured’ water as part of the surface or as part of the intervening water between the two surfaces.

Thickness and refractive index measurements using multiple beam interference fringes (FECO)

We report on the use of optical interferometry employing fringes of equal chromatic order (FECO) in a surface force apparatus (SFA) to determine film thicknesses and refractive indices of confined media for a wide range of separations. In particular, we show how to calculate the surface separation (film thickness) based on two fringes whose contact position was not measured. We discuss the measurement accuracy, and though the theoretical accuracy is 1 A for all separations, we show that in practice, for large separations, it is very hard to get to this accuracy.