The disclosure relates to an apparatus and associated method for concentration of polarizable molecules within a fluid medium. The apparatus comprising a structure defining a cavity, having a cross-sectional dimension of 200 nm or less; at least two translocation electrodes positioned relative to the structure to enable generation of a DC electric field passing through the cavity; and at least two trapping electrodes positioned relative to the structure to enable generation of a time-varying electric field proximal to the cavity inlet.

The techniques relate to methods and apparatus for sensing an analyte. At least one sensor element is configured to sense an analyte, the at least one sensor element comprising a first portion and a second portion. A first current electrode is attached to the first portion and a second current electrode is attached to the second portion. A first measurement electrode is attached to the first portion and a second measurement electrode is attached to the second portion.

A method for translocation of a peptide through a nanopore, wherein the method comprises translocating the peptide in the presence of an oligonucleotide translocase, wherein the peptide is comprised by a peptide-oligonucleotide complex, wherein the peptide is linked to an oligonucleotide, wherein the oligonucleotide translocase is associated to the oligonucleotide during at least part of the translocation.

Detection of viral nucleic acids (NAs) and their variants is effected using nanopore technology. If the target wild type viral NA is single-stranded, it is mixed with its complementary NA, and also the unknown viral NA sample to be analyzed, followed by hybridization; while if the target wild type viral NA is double-stranded, it is mixed with the unknown viral NA sample only, then denatured and followed by hybridization. The hybridized products from either case are then subjected to translocation in the form of a translocation analysis, experiment or test through a nanopore device that measures the electrical signals induced through translocation events. The corresponding signal train is characteristic of an individual virus or variant and acts as a “fingerprint” facilitating rapid virus identification and discovery of a new variant.

Various aspects of the present disclosure provide methods, apparatus and systems for single-molecule biosensors having nanowire or nanoribbon bridges between electrodes for sequencing and information storage and reading. In various embodiments, the present disclosure provides nanofabrication of biomolecular sensing devices beginning with parallel arrangements of transferable nanowires or nanoribbons, and provides in general methods of manufacturing biosensor devices for sequencing DNA or RNA and analyzing biomolecules.

The present invention provides a new and improved multiplexed oligonucleotide detection method based on the nanopore technology with one or more probes containing a sequence with complementarity to the target oligonucleotide, a terminal extension at the probe's 3′ terminus, 5′ terminus, or both termini and a label attached to the terminus. The improved probes and probe sets enable sensitive, selective, and direct multiplex detection, differentiation and quantification of distinct target oligonucleotides such as miRNAs. The inventive detection method may also be employed as a non-invasive and cost-effective diagnostic method based on miRNA levels in the patient's tissue sample.

Gene editing can be performed by introducing gene-editing components into a cell by mechanical cell disruption. Related apparatus, systems, techniques, and articles are also described. The methods and systems of the invention solve the problem of intracellular delivery of gene editing components and gene editing complexes to target cells. The results described herein indicate that delivery of gene editing components, e.g., protein, ribonucleic acid (RNA), and deoxyribonucleic acid (DNA), by mechanical disruption of cell membranes leads to successful gene editing. Because intracellular delivery of gene editing materials is a current challenge, the methods provide a robust mechanism to engineer target cells without the use of potentially harmful viral vectors or electric fields.

A method for producing a membrane device includes: forming an insulating film as a first film on a Si substrate; forming a Si film as a second film on the entire surface or a part of the first film; forming an insulating film as a third film on the second film; forming an aperture so as to pass through a part of the third film positioned on the second film and not to pass through the second film; etching a part of the substrate on one side of the first film with a solution that does not etch the first film; and etching a part or all of the second film on the other side of the first film with a gas or a solution that does not etch the first film and has an etching rate for the third film lower than an etching rate for the second film.

Devices, systems, and methods for applying a dielectrophoretic force on a particle include: a cell defining at least one channel for confining the particle; and a first electrode and a second electrode electrically isolated from the first electrode, at least one of the first and second electrodes being formed from a two-dimensional (2D) material providing an atomically sharp edge. The first and second electrodes are arranged sufficiently close to one another and sufficiently close to the channel such that application of a sufficient voltage across the first and second electrodes generates an electric field in at least part of the channel, the electric field having an electric field gradient sufficient to apply the dielectrophoretic force on the particle in the channel.

Disclosed are methods and devices for detection of ion migration and binding, utilizing a nanopipette adapted for use in an electrochemical sensing circuit. The nanopipette may be functionalized on its interior bore with metal chelators for binding and sensing metal ions or other specific binding molecules such as boronic acid for binding and sensing glucose. Such a functionalized nanopipette is comprised in an electrical sensor that detects when the nanopipette selectively and reversibly binds ions or small molecules. Also disclosed is a nanoreactor, comprising a nanopipette, for controlling precipitation in aqueous solutions by voltage-directed ion migration, wherein ions may be directed out of the interior bore by a repulsing charge in the bore.