Abstract: Embodiments of the present disclosure provide bisbiotin ligands and related conjugates and methods. The bisbiotin ligands, combined with streptavidin, can be used in the separation, labelling, targeting, and immobilization of biomolecules.

Abstract: A sensing device is provided that includes a tunnel junction created by forming a hole in a layered tunnel junction (for example). A chemically, well-defined surface may be formed by coupling affinity reagents to the electrodes, which, by these means, the surface may be configured to be selective for a particular analyte.

Abstract: An apparatus for identifying and/or sequencing one or more molecules including a first sensing electrode and a second sensing electrode separated from the first electrode by a gap. An electrolyte is contained within the gap. The surfaces of the first sensing electrode and the second sensing electrode are functionalized with adaptor molecules for solution contacting the one or more molecules. The apparatus also includes a reference electrode in contact with the electrolyte and coupled to one of the sensing electrodes.

Abstract: An system for recognition of a translocating polymetric target molecule includes a device having at least one constriction that is sized to permit translocation of only a single copy of the molecule. A pair of spaced apart sensing electrodes border the constriction, which may be a nonopore. The first electrode is connected to a first affinity element and the second electrode is connected to a second affinity element. Each affinity element may connected to its corresponding electrode via one or more intermediary compounds, such as a linker molecule and/or an electrode attachment molecule. The first and second affinity elements are configured to temporarily form hydrogen bonds with first and second portions of the target molecule as the latter passes through the constriction. During translocation, the electrodes affinity elements and first and second portions of the target molecule complete an electrical circuit and allow a measurable electrical current to pass between the first and second electrodes.

Abstract: Triazole-based molecules, methods of making and using the same are provided. Triazole-based molecules may be used as reading molecules and incorporated into or operatively-linked with electrodes, for example, and used in recognition tunneling systems to identify individual and/or sequences of molecules (e.g., DNA bases, carbohydrates, proteins, peptides, and/or amino-acids).

Abstract: The disclosure provides for methods and apparatuses relating to technology for monitoring chemical and/or biological reactions. Some methods provided herein relate to utilization of NAPPA technology to create large protein arrays suitable for use in combination with various ISFET arrays to enable massive parallel assays of kinase activity and inhibition. Some devices provided herein relate to CMOS chips which utilize the NAPPA array technology to build protein inventories of interest upon an ISFET architecture. Further devices provided herein are capable, inter alia, of processing the arrays created by the combination of NAPPA technology and ISFET architecture.

Abstract: Embodiments of the disclosure are directed to a device for molecule sensing. In some embodiments, the device includes a first electrode separated from a second electrode by a dielectric layer. The first electrode comprises a large area electrode and the second electrode comprises a small area electrode. At least one opening (e.g., trench) cut or otherwise created into the dielectric layer exposes a tunnel junction therebetween whereby target molecules in solution can bind across the tunnel junction.

Abstract: The present invention provides a device having at least one constriction that is sized to permit translocation of only a single copy of the molecule. The device has a pair of spaced apart sensing electrodes that border the constriction, which may be a nanopore. The first electrode is connected to a first affinity element and the second electrode is connected to a second affinity element. The first and second affinity elements are configured to temporarily form hydrogen bonds with first and second portions of the target molecule as the latter passes through the constriction.

Abstract: A device for sequencing single polymer molecules. The device includes a molecular clamp bound to a first electrode so as to hold the polymer in place with respect to the first electrode, which can be in close proximity to a second electrode so that a signal characteristic of each molecular residue on the polymer is generated as the polymer passes the gap between the electrodes. A third electrode may be biased with respect to the first two electrodes so as to exert a force that pulls the molecule through the molecular clamp and past the junction between the first two electrodes.

Abstract: A device for electronic sequencing of polymers consisting of a tunnel gap that is self-aligned with a nanochannel.

Abstract: Embodiments disclosed herein are directed to recognition tunneling systems, methods and devices, and more particularly, to chemical reactions for selectively labeling proteins and peptides and placing protein and/or peptides into, or onto a nanopore formed in a solid support and threading such in and/or through the nanopore, with such nanopores, in some embodiments, including a molecular motor to pull or otherwise force the protein/peptide through the nanopore.

Abstract: Some embodiments of the present disclosure are directed to a compound 5(6)-mercapto-1H-benzo[d]imidazole-2-carboxamide (“BIA”) which yields enhanced signals for recognition tunneling. Other embodiments are directed toward methods for producing such compounds as well as apparatuses and systems which utilize such compounds for recognition tunneling for molecule identification/sequencing (for example).

Abstract: The invention includes compositions, devices, and methods for analyzing a polymer and/or polymer unit. The polymer may be a homo or hetero-polymer such as DNA, RNA, a polysaccharide, or a peptide. The device includes electrodes that form a tunnel gap through which the polymer can pass. The electrodes are functionalized with a reagent attached thereto, and the reagent is capable of forming a transient bond to a polymer unit. When the transient bond forms between the reagent and the unit, a detectable signal is generated and used to analyze the polymer.

Abstract: Embodiments of the disclosure are directed to a device for molecule sensing. In some embodiments, the device includes a first electrode separated from a second electrode by a dielectric layer. The first electrode comprises a large area electrode and the second electrode comprises a small area electrode. At least one opening (e.g., trench) cut or otherwise created into the dielectric layer exposes a tunnel junction therebetween whereby target molecules in solution can bind across the tunnel junction.

Abstract: Some embodiments of the present disclosure are directed to systems, methods and devices for controlling the transit of a molecule across a nanopore. Some embodiments are directed to a device comprising a first compartment, a second compartment, a first pair of electrodes comprising a first electrode provided in the first compartment and a second electrode provided in the second compartment, a partition separating the first compartment from the second compartment, an orifice provided in the partition, a second pair of electrodes arranged proximate the orifice, the second pair of electrodes being functionalized with molecules, and a tunnel gap comprising the spacing between the second pair of electrodes.

Abstract: Embodiments of the present disclosure are directed to methods, systems and devices, for analyzing the molecules. For example, in some embodiments, a system is provided which includes a first volume of conducting fluid, a second volume of conducting fluid, an orifice in communication with said first and second volumes of fluid, and means for applying an electric potential difference between said first and second volumes of fluid. In some such embodiments, a conjugate product is provided which comprises charged polymers each having attached thereto at least one first molecule for analysis, where the product carries a predetermined charge greater than the charge on the first molecule, and upon dissolving a product in the first volume of fluid, the product is directed into the orifice.

Abstract: The invention includes compositions, devices, and methods for analyzing a polymer and/or polymer unit. The polymer may be a homo or hetero-polymer such as DNA, RNA, a polysaccharide, or a peptide. The device includes electrodes that form a tunnel gap through which the polymer can pass. The electrodes are functionalized with a reagent attached thereto, and the reagent is capable of forming a transient bond to a polymer unit. When the transient bond forms between the reagent and the unit, a detectable signal is generated and used to analyze the polymer.

Abstract: The present invention is directed to systems, devices and methods for identifying biopolymers, such as strands of DNA, as they pass through a constriction such as a carbon nanotube nanopore. More particularly, the invention is directed to such systems, devices and methods in which a newly translocated portion of the iopolymer forms a temporary electrical circuit between the nanotube nanopore and a second electrode, which may also be a nanotube. Further, the invention is directed to such systems, devices and methods in which the constriction is provided with a transnaionilized unit which, together with a newly translocated portion of the biopolymer, forms a temporary electrical circuit that can be used to characterize the portion of the biopolymer.

Abstract: Embodiments of the present disclosure are directed to recognition tunneling methods, systems and devices for the detection of carbohydrates by measuring tunneling currents of sugars which give distinct electronic signals in a tunnel gap functionalized respectively with, for example, in some embodiments, 4(5)-(2-mercaptoethyl)-1H imideazole-2-carboxamide and 4-mercaptophenylboronic acid molecules on at least one, and preferably each electrode.

Abstract: A method to identify a chemical target trapped in a tunnel junction with a high probability of a correct assignment based on, a single read of the tunnel current signal. The method recognizes and rejects background signals produced in the absence of target molecules, and do so accurately without rejecting useful signals from the target molecules. The identity of signals generated by electron tunneling through an analyte is provided and comprises determining a plurality of characteristics of each signal current spike, generating one or more training signals with a set of analytes, where the analytes may comprise a first analyte, and using the training signals to find one or more boundaries in a space of dimension equal to one or more parameters, wherein the space is partitioned such that a signal from the first analyte of interest is separated from a signal from the second analyte of interest.