Abstract: The present invention provides devices and methods for detection of analytes based on measuring the anchoring strength of liquid crystals having distorted geometries. Methods for detecting an analyte in a sample include the steps of: (a) capturing an analyte on a substrate surface wherein the substrate surface defines an easy axis when in contact with a liquid crystal. Substrate surface and liquid crystal are brought into contact and an analyte-dependent departure in the orientation of the liquid crystal from the easy axis of the substrate surface is measured. This departure indicates the presence of the analyte in the sample.

Abstract: The present invention is directed to liquid crystalline substrates useful in the culture of cells and methods of their use. In certain embodiments, the invention provides methods and devices for imaging changes (e.g., reorganization) of extracellular matrix components by living cells.

Abstract: A method of forming a liquid crystal device, includes: contacting an aqueous solution comprising a surfactant and a receptor molecule with a top surface of a liquid crystal. The liquid crystal is in a holding compartment of a substrate, and the receptor molecule is adsorbed on the top surface of the liquid crystal forming an interface between the liquid crystal and the aqueous solution. The receptor molecule is different than the surfactant. A method of detecting a compound in a flowing stream includes passing an aqueous solution over a top surface of a liquid crystal in a holding compartment of a substrate. The method also includes determining whether a change in the orientation of the liquid crystal occurs as the aqueous solution is passed over the top surface of the liquid crystal. A change in the orientation of the liquid crystal indicates the presence of the compound in the flowing stream.

Abstract: The present invention provides devices and methods for detection of analytes based on measuring the anchoring strength of liquid crystals having distorted geometries. Methods for detecting an analyte in a sample include the steps of: (a) capturing an analyte on a substrate surface wherein the substrate surface defines an easy axis when in contact with a liquid crystal. Substrate surface and liquid crystal are brought into contact and an analyte-dependent departure in the orientation of the liquid crystal from the easy axis of the substrate surface is measured. This departure indicates the presence of the analyte in the sample.

Abstract: Colloidal liquid crystal gels (CLCGs), sensors incorporating the CLCGs, culture substrates made from the CLCGs, and patterned films and molded articles made from the CLCGs are provided. The CLCGs are composite liquid crystal materials comprising networks of particles having liquid crystal domains dispersed therein.

Abstract: Detection apparatus for use in the detection of the presence of a selected pathogen in a sample are disclosed. Such apparatus include: a substrate with a detection region on a surface thereof, the detection region having microstructures including grooves formed therein that will align liquid crystal material in contact therewith, the width and depth of the grooves being in the range of 10 ?m or less; a blocking layer on the surface of the detection region of the substrate that does not disrupt the alignment of liquid crystal material in contact therewith, the blocking layer blocking nonspecific adsorption of pathogens to the surface; and a binding agent on the surface of the detection region of the substrate, the binding agent specifically binding the selected pathogen.

Abstract: The present invention provides materials and methods that make liquid crystal phases accessible with relatively short ?-peptides in aqueous solvents.

Abstract: The invention provides oil emulsion droplets and a general and facile method for providing same through the use of templating multilayer capsules. The oil emulsion droplets are further useful in fabricating liquid crystal droplet-based biosensors for the detection of target analytes such as bacteria or viruses in a sample.

Abstract: The present invention provides systems and methods for data acquisition and image analysis that utilize twisted nematic liquid crystals (“TNLCs”) to create maps of bio/chemical functionality patterned on surfaces. The method involves the acquisition of a series of images of TNLC film that contacts the analytic surface followed by analysis of the series of images to yield maps of twist angle of the liquid crystal across the surface. This analysis technique effectively condenses a large data set (stack of images) into a compact form (map of twist angle), revealing features on the surface that were not apparent in the individual images comprising the original stack.

Abstract: A method of forming a liquid crystal device, includes: contacting an aqueous solution comprising a surfactant and a receptor molecule with a top surface of a liquid crystal. The liquid crystal is in a holding compartment of a substrate, and the receptor molecule is adsorbed on the top surface of the liquid crystal forming an interface between the liquid crystal and the aqueous solution. The receptor molecule is different than the surfactant. A method of detecting a compound in a flowing stream includes passing an aqueous solution over a top surface of a liquid crystal in a holding compartment of a substrate. The method also includes determining whether a change in the orientation of the liquid crystal occurs as the aqueous solution is passed over the top surface of the liquid crystal. A change in the orientation of the liquid crystal indicates the presence of the compound in the flowing stream.

Abstract: A method of forming a liquid crystal device, includes: contacting an aqueous solution comprising a surfactant and a receptor molecule with a top surface of a liquid crystal. The liquid crystal is in a holding compartment of a substrate, and the receptor molecule is adsorbed on the top surface of the liquid crystal forming an interface between the liquid crystal and the aqueous solution. The receptor molecule is different than the surfactant. A method of detecting a compound in a flowing stream includes passing an aqueous solution over a top surface of a liquid crystal in a holding compartment of a substrate. The method also includes determining whether a change in the orientation of the liquid crystal occurs as the aqueous solution is passed over the top surface of the liquid crystal. A change in the orientation of the liquid crystal indicates the presence of the compound in the flowing stream.

Abstract: A DNA hybridization surface includes a support having a self assembled monolayer on a metallized surface. The self assembled monolayer includes an alkanethiol and a strand of nucleic acids comprising a functional group that binds to the metallized surface. A method for detecting DNA hybridization in a sample includes (a) incubating a DNA hybridization surface with an aqueous sample that includes a fragment of DNA to produce an incubated DNA hybridization surface; (b) rinsing the incubated DNA hybridization surface to produce a rinsed incubated DNA hybridization surface; (c) contacting the rinsed incubated DNA hybridization surface with a liquid crystal; and (d) determining whether the liquid crystal is uniformly anchored on the rinsed incubated DNA hybridization surface.

Abstract: Liquid crystal compositions that exhibit little or no toxicity with respect to cells include liquid crystals with chemical functional groups such as fluorine atoms, fluorophenyl groups, or difluorophenyl groups. Liquid crystals with little or no toxicity to cell lines may be added to cell culture media or added to components used in cell culture media. Cells may be grown in cell culture media that includes liquid crystals that exhibit little or no toxicity to cells.

Abstract: A device for detecting a compound in a sample includes a substrate and a self-assembled monolayer. The substrate includes a support with a metallized top surface, and the self-assembled monolayer includes an alkanethiol attached to the metallized top surface of the substrate and having a functional group that reversibly or irreversibly interacts with the compound. A liquid crystal is disposed on the self-assembled monolayer opposite the side of the self-assembled monolayer attached to the metallized top surface of the substrate. The liquid crystal includes a moiety that interacts with the functional group of the alkanethiol. When the compound is present in a sample that that contacts the self-assembled monolayer, the orientation of the liquid crystal is altered.

Abstract: Interactions between molecules which are components of self-assembled monolayers and other molecules can be amplified and transduced into an optical signal through the use of a mesogenic layer. The invention provides a device and methods for detecting analytes. The device comprises a substrate onto which a self-assembled monolayer is attached and a mesogenic layer which is anchored by the self-assembled monolayer. The mesogenic layer undergoes a change in conformation in response to the molecular interaction.

Abstract: Interactions between molecules which are components of self-assembled monolayers and other molecules can be amplified and transduced into an optical signal through the use of a mesogenic layer. The invention provides a device and methods for detecting analytes. The device comprises a substrate onto which a self-assembled monolayer is attached and a mesogenic layer which is anchored by the self-assembled monolayer. The mesogenic layer undergoes a change in conformation in response to the molecular interaction.

Abstract: A method for preparing a metallized surface that possesses gradients in surface topography includes obliquely depositing a metal from a metal source onto a surface of a support. The surface of the support includes a first end, a second end, and a region between the first and second ends. The second end of the surface is located nearer to the metal source than is the first end, and the metal is deposited onto the first end of the surface at a first angle of incidence and the metal is deposited onto the second end of the surface at a second angle of incidence. The first angle of incidence is greater than the second angle of incidence, and the metal is deposited onto the region between the first and second ends at angles of incidence that vary over the region to produce the metallized surface with gradients in surface topography. The angles of incidence are measured from the normal of the support.

Abstract: Detection apparatus for use in the detection of the presence of a selected pathogen in a sample are disclosed. Such apparatus include: a substrate with a detection region on a surface thereof, the detection region having microstructures including grooves formed therein that will align liquid crystal material in contact therewith, the width and depth of the grooves being in the range of 10 &mgr;m or less; a blocking layer on the surface of the detection region of the substrate that does not disrupt the alignment of liquid crystal material in contact therewith, the blocking layer blocking nonspecific adsorption of pathogens to the surface; and a binding agent on the surface of the detection region of the substrate, the binding agent specifically binding the selected pathogen.

Abstract: A method for preparing a rubbed substrate structure suitable for use in a liquid crystal assay device, includes reacting a biochemical blocking compound that includes at least one reactive group with an activated modified surface of a support, the activated modified surface of the support having at least one functional group capable of reacting with the reactive group of the biochemical blocking compound, wherein a covalent bond is formed between the biochemical blocking compound and the support producing a support with a surface comprising the biochemical blocking compound. The method also includes rubbing the surface having the biochemical blocking compound to produce a rubbed surface that possesses features that drive uniform anchoring of liquid crystals when the liquid crystals contact the rubbed surface.

Abstract: A method for preparing a metallized surface that possesses gradients in surface topography includes obliquely depositing a metal from a metal source onto a surface of a support. The surface of the support includes a first end, a second end, and a region between the first and second ends. The second end of the surface is located nearer to the metal source than is the first end, and the metal is deposited onto the first end of the surface at a first angle of incidence and the metal is deposited onto the second end of the surface at a second angle of incidence. The first angle of incidence is greater than the second angle of incidence, and the metal is deposited onto the region between the first and second ends at angles of incidence that vary over the region to produce the metallized surface with gradients in surface topography. The angles of incidence are measured from the normal of the support.