The present invention relates to a method for the diagnosis of a disease comprising contacting a donor tissue section with a liquid capable of extracting an antibody from said donor tissue section and contacting said liquid with an acceptor material comprising an antigen, followed by detection of a complex comprising the antibody and the antigen, and a diagnostically useful carrier comprising a donor tissue section and an acceptor material comprising an antigen.

The invention relates to a process for preparation of an unpassivated cantilever comprising the steps of: 1) providing a silicon cantilever sensor having two sides; 2) coating one side of the cantilever with at least a gold layer; and 3) functionalizing both sides of the cantilever with a self-assembled monolayer (SAM) of a probe molecule by incubating the cantilever in a solution having a concentration of the probe molecule of between 1 to 1000 μM.

The invention also relates to an unpassivated cantilever sensor comprising a silicon layer coated on one side with a coating comprising Au and being uncoated or unpassivated on the opposite side, wherein the Au coated surface comprises a self-assembled monolayer of a probe molecule and wherein the surface area occupied per probe molecule is in the range 0.4-1.5 nm.sup.2.

Apparatus, sensor chips and techniques for optical sensing of substances by using optical sensors on sensor chips.

The present invention relates to a colorimetric detection system for rapid detection of lung diseases. The detection system comprises antibodies and/or aptamers coupled to a substrate for capturing a lung disease specific antigen. The colorimetric system further comprises dyed microspheres modified with the antibodies and/or aptamers for visually detecting the lung disease specific antigen. The present invention also relates to a method of producing said detection system and a mask with such a detection system.

A microdevice for monitoring a target analyte is provided. The microdevice can include a field effect transistor comprising a substrate, a gate electrode, and a microfluidic channel including graphene. The microfluidic channel can be formed between drain electrodes and source electrodes on the substrate. The microdevice can also include at least one aptamer functionalized on a surface of the graphene. The at least one aptamer can be adapted for binding to the target analyte. Binding of the target analyte to the at least one aptamer can alter the conductance of the graphene.

[Problem ] Provided is a means for detecting and quantifying a biological substance of interest with an improved accuracy by inhibiting non-specific adsorption of fluorescent nanoparticles and thereby reducing the background noise in immunostaining with fluorescent nanoparticles. [Means for Solution] Immunostaining is carried out upon diluting fluorescent nanoparticles with a fluorescent nanoparticle diluent which contains 1 to 5% (W/W) of a protein having a molecular weight of 40,000 or higher (e,g., BSA) and 1 to 3% (W/W) of a protein having a molecular weight of less than 40,000 (eg ., casein) and, when casein is used as a low-molecular-weight protein, it is preferred that the κ-casein content in the casein is 10% (W/W) or less and the ratio of α-casein and β-casein (α-casein:β-casein) contained in the casein is 40:60 to 60:40 ( taking the total amount of α-casein and β-casein as 100).

This invention relates to a surface coating for capture circulating rare cells, comprising a nonfouling composition to prevent the binding of non-specific cells and adsorption of serum components; a bioactive composition for binding the biological substance, such as circulating tumor cells; with or without a linker composition that binds the nonfouling and bioactive compositions. The invention also provide a surface coating for capture and purification of a biological substance, comprising a releasable composition to release the non-specific cells and other serum components; a bioactive composition for binding the biological substance, such as circulating tumor cells; with or without a linker composition that binds the releasable and bioactive compositions. The present invention also discloses a novel microfluidic chip, with specific patterned microstructures to create a flow disturbance and increase the capture rate of the biological substance.

Enantiomeric pairs of molecular wires comprised of oligomeric nucleic acids, wherein the oligomers of each wire possess identical nucleobase pair sequences and thus identical conductivity as between wires, are constructed and used to sense biological or chemical entities of interest at the cellular or molecular level. The oligomeric molecular wires conduct voltage inputs to sensing subsystem integrated circuitry, either from an electrostatic potential arising from a targeting agent (i.e., a capture agent) binding to an intended biological or chemical target molecule, or from an electrostatic potential associated with a reference molecule that has non-specific interactions with the environment. The chirality of the oligomers imparts selectivity to either the targeting agent or the reference molecule during assembly of the sensing subsystem.

Cross-linked amphiphile constructs that form self-assembled monolayers (SAMs) on metal surfaces such as gold surfaces are disclosed. These new SAMs generate well packed and highly oriented monolayer films on gold surfaces. A method for using the SAMs in the fabrication of biomolecule sensors is also disclosed.

A solid phase for use in separation has been modified using an aqueous phase adsorption of a headgroup-modified lipid to generate analyte specific surfaces for use as a stationary phase in separations such as high performance liquid chromatography (HPLC) or solid phase extraction (SPE). The aliphatic moiety of the lipid adsorbs strongly to a hydrophobic solid surface, with the hydrophilic and active headgroups orienting themselves toward the more polar mobile phase, thus allowing for interactions with the desired solutes. The surface modification approach is generally applicable to a diversity of selective immobilization applications such as protein immobilization clinical diagnostics and preparative scale HPLC as demonstrated on capillary-channeled fibers, though the general methodology could be implemented on any hydrophobic solid support material.