According to one embodiment, a method for immobilizing a nucleic acid compound on a surface of a sensor element including graphene, graphene oxide, a carbon nanotube, or graphite, the method includes preparing an aqueous solution containing a nucleic acid compound and sodium chloride, wherein the nucleic acid compound includes a polycyclic aromatic moiety including a polycyclic aromatic skeleton and a linker structure bonded to the polycyclic aromatic skeleton, and a nucleic acid moiety bonded to the linker structure, and dropping the aqueous solution onto the surface of the sensor element.

The present invention generally relates to droplet libraries and to systems and methods for the formation of libraries of droplets. The present invention also relates to methods utilizing these droplet libraries in various biological, chemical, or diagnostic assays.

Method for immobilization of a labeled oligonucleotide on a non-modified polymer substrate, the method comprising the following steps: a) providing a mixture comprising liquid, and a labeled oligonucleotide b) applying the mixture of step a) on a non-modified polymer substrate, wherein the oligonucleotide is immobilized on the non-modified polymer substrate via physisorption conveyed by the label of the oligonucleotide and wherein the label for immobilization is covalently bound to the oligonucleotide; and microarrays achieved by this method. The invention further relates to the use of a label attached to an oligonucleotide for immobilization of the labeled oligonucleotide on a non-modified polymer substrate by physisorption. Furthermore the invention relates to the use of the microarrays achieved by the method describe herein for assays and diagnostic kits comprising such microarrays.

Methods are disclosed for tethering a biological entity to a substrate comprising: (a) forming a supported lipid bilayer on a surface of a substrate, wherein the supported lipid bilayer comprises an anchor molecule conjugated to a first affinity tag that is present in the lipid bilayer at a concentration greater than or equal to 5 mole percent; and (b) contacting the supported lipid bilayer with a biological entity, wherein the biological entity comprises an nonlinear-active label and a second affinity tag capable of binding to the first affinity tag, thereby tethering the biological entity to the supported lipid bilayer in an oriented fashion.

This invention relates to an apparatus for conducting immunoassay test. The apparatus includes a groove unit having a groove along a vertical direction configured to hold a rod-shaped portion of a probe along the vertical direction, and a push pin configured to move along a horizontal direction, the push pin being capable of residing at a first position and a second position. A tip of the push pin is capable of pressing the rod-shaped portion of the probe against the groove when the push pin resides at the first position. The distance between the tip of the push pin and the groove is larger than a diameter of the rod-shaped portion of the probe when the push pin resides at the second position.

Methods for detecting one or more analytes in a sample utilizing Electrochemical Impedance Spectroscopy (EIS) measurement. In one method, analyte detection includes comparing an imaginary impedance measurement to a calibration curve of concentrations for each target analyte. The calibration curve of concentrations for each target analyte is established at an optimal frequency. In another method, a signal decoupling algorithm is utilized for detection of more than one analyte on an electrode.

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.

The invention provides a method for immobilization of biological molecules such as nucleic acids, peptides and proteins onto the surface of a glass or plastic solid support.

The present invention relates to tri-functional crosslinking reagents carrying (i) a ligand-reactive group for conjugation to a ligand of interest having at least one binding site on a target glycoprotein receptor, (ii) a hydrazone group for the capturing of oxidized receptor-glycoproteins and (iii) an affinity group selected from azides and aklynes for the detection, isolation and purification of captured glycoproteins; as well as their manufacturing. The invention further provides for improved methods of detecting, identifying and characterizing interactions between ligands and their corresponding target glycoproteins on living cells and in biological fluids. The invention further provides for new uses of catalysts in such methods.

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.