Preparation, characterization, and surface immobilization of native vesicles obtained by mechanical extrusion of mammalian cells.

Native vesicles or "reduced protocells" derived by mechanical extrusion concentrate selected plasma membrane components, while downsizing complexities of whole cells. We illustrate this technique, characterize the physical-chemical properties of these reduced configurations of whole cells, and demonstrate their surface immobilization and patternability. This simple detergent-free vesicularized membrane preparation should prove useful in fundamental studies of cellular membranes, and may provide a means to engineer therapeutic cells and enable high-throughput devices containing near-native, functional proteolipidic assemblies.

Cell attachment behavior on solid and fluid substrates exhibiting spatial patterns of physical properties.

The ability to direct proliferation and growth of living cells using chemically and topologically textured surfaces is finding many niche applications, both in fundamental biophysical investigations of cell-surface attachment and in developing design principles for many tissue engineering applications. Here we address cellular adhesion behavior on solid patterns of differing wettability (a static substrate) and fluid patterns of membrane topology (a dynamic substrate). We find striking differences in the cellular adhesion characteristics of lipid mono- and bilayers, despite their essentially identical surface chemical and structural character.

Optical detection of ion-channel-induced proton transport in supported phospholipid bilayers.

The integration of ion-channel transport functions with responses derived from nanostructured and nanoporous silica mesophase materials is demonstrated. Patterned thin-film mesophases consisting of alternating hydrophilic nanoporous regions and hydrophobic nanostructured regions allow for spatially localized proton transport via selective dimerization of gramicidin in lipid bilayers formed on the hydrophilic regions. The adjoining hydrophobic mesostructure doped with a pH sensitive dye reports the transport.

Lipid lateral mobility and membrane phase structure modulation by protein binding.

Using a combination of fluorescence correlation and infrared absorption spectroscopies, we characterize lipid lateral diffusion and membrane phase structure as a function of protein binding to the membrane surface. In a supported membrane configuration, cholera toxin binding to the pentasaccharaide headgroup of membrane-incorporated GM1 lipid alters the long-range lateral diffusion of fluorescently labeled probe lipids, which are not involved in the binding interaction. This effect is prominently amplified near the gel-fluid transition temperature, Tm, of the majority lipid component.

Direct photochemical patterning and refunctionalization of supported phospholipid bilayers.

A wet photolithographic route for micropatterning fluid phospholipid bilayers is demonstrated in which spatially directed illumination by short-wavelength ultraviolet radiation results in highly localized photochemical degradation of the exposed lipids. Using this method, we can directly engineer patterns of hydrophilic voids within a fluid membrane as well as isolated membrane corrals over large substrate areas. We show that the lipid-free regions can be refilled by the same or other lipids and lipid mixtures which establish contiguity with the existing membrane, thereby providing a synthetic means for manipulating membrane compositions, engineering metastable membrane microdomains, probing 2D lipid-lipid mixing, and designing membrane-embedded arrays of soluble proteins.