A labeled nucleotide includes a nucleotide, a linking molecule attached to a phosphate group of the nucleotide, and a redox-active charge tag attached to the linking molecule. The redox-active charge tag is to be oxidized or reduced by an electrically conductive channel when maintained in proximity of a sensing zone of the electrically conductive channel.

The invention relates to the field of nanopores and the use thereof in analyzing biopolymers, including polypeptides and polynucleotides. Provided is an artificial nanopore comprising a multimeric assembly of subunits, each subunit comprising (i) the transmembrane (TM) sequence of a β-barrel or α-helical pore forming protein fused to the amino acid sequence of (ii) a subunit of a ring-forming protein capable of controlling the transport of a polypeptide or polynucleotide across the TM region of the assembly.

Phosphoramidate-based monomers are provided for use in the synthesis of expandable polymers for nanopore-based sensing. Such monomers comprising a reporter construct that contain a first reporter code, a symmetrical chemical brancher bearing a translocation control element, and a second reporter code, wherein the ends of the reporter construct are attached to phosphoramidate-nucleoside. Related methods and products are also provided.

A composition having one or more nanoneedles is provided, where each nanoneedle has a silver tip and one or more of the silver tips comprise an AgCl layer. In one approach, one or more of the silver tips further include a layer of thiol-polyethylene glycol. A method of resistive pulse detection involving a protein pore is also provided. The method involves reconstituting one or more protein pores in a lipid membrane formed on the tip of a nanoneedle, then applying a potential across the membrane and detecting resistive pulses.

Droplet interfaces are formed between droplets in an electro-wetting device comprising an array of actuation electrodes. Actuation signals are applied to selected actuation electrodes to place the droplets into an energised state in which the shape of the droplets is modified compared to a shape of the droplets in a lower energy state and to bring the two droplets into proximity. The actuation signals are then changed to lower the energy of the droplets into the lower energy state so that the droplets relax into the gap and the two droplets contact each other thereby forming a droplet interface. The use of sensing electrodes in the device permit electrical current measurements across the droplet interface. The sensing electrodes can be used for either (i) applying a reference signal during droplet actuation or (ii) recording electrical current measurements.

Aspects of the present disclosure include methods of making barcoded solid supports. In some embodiments, the methods include producing a concatemer by rolling circle amplification (RCA) of a circular nucleic acid template, where the circular nucleic acid template includes a barcode and a stem-loop forming region, and where the concatemer includes a plurality of linked units, each unit including the barcode and a stem-loop structure formed from the stem-loop forming region. Such methods further include disposing the concatemer on a solid support to produce a barcoded solid support including a plurality of the stem-loop structures extending from the surface of the solid support. The methods may further include treating the stem-loop structures with an agent that produces stem structures having ends compatible with target nucleic acids, and attaching the target nucleic acids to the stem structures. Barcoded solid supports and methods of using the barcoded solid supports are also provided.

Embodiments of the present disclosure provide dual pore sensors and methods for producing these dual pore sensors. The method includes forming a film stack, where the film stack contains two silicon layers and two membrane layers, and then etching the film stack to produce a channel extending therethrough and having two reservoirs and two nanopores. The method also includes depositing a oxide layer on inner surfaces of the reservoirs and nanopores, depositing a dielectric layer on the oxide layer, and forming a metal contact extending through a portion of the stack. The method further includes etching the dielectric layers to form wells, etching the first silicon layer to reveal the protective oxide layer deposited on the inner surfaces of a reservoir, and etching the protective oxide layer deposited on the inner surfaces of the reservoirs and the nanopores.

Constricted nanochannel devices suitable for use in analysis of macromolecular structure, including DNA sequencing, are disclosed. Also disclosed are methods for fabricating such devices and for analyzing macromolecules using such devices.

A method of detecting a lipid bilayer formed in a cell of a nanopore based sequencing chip is disclosed. An integrating capacitor is coupled with a lipid membrane, wherein the lipid membrane is between a working electrode and a counter electrode. An alternating current (AC) voltage is applied to the counter electrode. A voltage across the integrating capacitor is periodically sampled by an analog-to-digital converter (ADC). A change in the sampled voltage across the integrating capacitor in response to a change in the AC voltage is determined. Whether the lipid membrane comprises a lipid bilayer is detected based on the determined change in the sampled voltage across the integrating capacitor in response to the change in the AC voltage.

The present invention provides methods, compositions, and systems for distributing molecules and complexes into reaction sites. In particular, the methods, compositions, and systems of the present invention result in an active loading of molecules and complexes into reaction sites with improved efficiency over loading by passive diffusion methods alone.