Abstract: The invention relates to a method for modifying a template double stranded polynucleotide, especially for characterisation using nanopore sequencing. The method produces from the template a plurality of modified double stranded polynucleotides. These modified polynucleotides can then be characterised.

Abstract: The present disclosure relates to compositions and methods for generating capture probes on a substrate for identifying the location of analytes in a biological sample.

Abstract: Provided herein, in some aspects, are methods of imaging molecules without a microscope or other specialized equipment, referred to herein as “microscope-free imaging (MFI).” Herein, “molecular instruments” (e.g., DNA-based and protein-based molecules) are used, instead of microscopes, in a “bottom-up” approach for inspecting molecular targets.

Abstract: Provided herein are methods for preparing and treating an analyte (e.g., a macromolecule or a plurality of macromolecules, peptides, polypeptides, and proteins) for analysis. In some embodiments, the analyte is prepared and treated in a method that includes the use of bait and capture nucleic acids, solid supports, and reaction mixtures including the bait and capture nucleic acids. In some embodiments, the analyte is coupled to a solid support. Also provided are kits containing components for performing the provided methods for preparing the analytes. In some embodiments, the methods are for preparing an analyte for sequencing. Provided herein are methods for preparing and treating an analyte (e.g., a macromolecule or a plurality of macromolecules, peptides, polypeptides, and proteins) for analysis. In some embodiments, the analyte is prepared and treated in a method that includes the use of bait and capture nucleic acids, solid supports, and reaction mixtures including the bait and capture nucleic acids.

Abstract: Provided herein are oligonucleotide probes for detecting 2019 novel coronavirus (2019-nCoV). The probes are modified at their 5? ends with a fluorophore (e.g., fluorescein), and are also modified (e.g., at their 3? ends) with a moiety capable of quenching fluorescence from the fluorophore. The moiety is based on the IQ-4 or IQ-2 quencher. Also provided are kits including one or more of such oligonucleotide probes, and methods of detecting 2019-nCoV and/or diagnosing COVID-19 using the oligonucleotide probes and kits described herein.

Abstract: The invention relates to a new method of characterizing a target polynucleotide. The method uses a pore and a Hel308 helicase or amolecular motor which is capable of binding to the target polynucleotide at an internal nucleotide. The helicase or molecular motor controls the movement of the target polynucleotide through the pore.

Abstract: Nucleic acid sequencing methods and systems, the systems including nanochannel chip including: a nanochannel formed in an upper surface of the nanochannel chip and; a roof covering the nanochannel and comprising nanopores and a field enhancement structure; and a barrier disposed in the nanochannel. The method including: introducing a buffer solution including long-chain nucleic acids to the nanochannel chip; applying a voltage potential across the nanochannel chip to drive the nucleic acids through the nanochannel, towards the barrier, and to translocate the nucleic acids through nanopores adjacent to the barrier, such that bases of each of the nucleic acids pass through the field enhancement structure one base at a time and emerge onto an upper surface of the roof; detecting the Raman spectra of the bases of the nucleic acids as each base passes through the electromagnetic-field enhancement structure; and sequencing the nucleic acids based on the detected Raman spectra.

Abstract: The present disclosure provides methods and assay systems for use in spatially encoded biological assays, including assays to determine a spatial pattern of abundance, expression, and/or activity of one or more biological targets across multiple sites in a sample. In particular, the biological targets comprise proteins, and the methods and assay systems do not depend on imaging techniques for the spatial information of the targets. The present disclosure provides methods and assay systems capable of high levels of multiplexing where reagents are provided to a biological sample in order to address tag the sites to which reagents are delivered; instrumentation capable of controlled delivery of reagents; and a decoding scheme providing a readout that is digital in nature.

Abstract: NAzyme activity surface plasmon resonance sensors include a first DNA probe that is covalently connected to a sensing surface, and a second DNA probe that is covalently connected to a nanoparticle or a nanoparticle cluster. The first DNA probe and the second DNA probe are ligated together to provide a selected single strand DNA probe connected to the sensing surface and the nanoparticle. The single strand DNA probe includes a ligation zone within a selected NAzyme substrate. The sensor measures DNAzyme activity by NAzyme binding at the NAzyme substrate and cleavage at the ligation zone. Fiber optic surface plasmon resonance sensor tips are adapted to measure activity of a NAzyme when the NAzyme substrate is recognized by the selected NAzyme through hybridization and the metallic nanoparticle is released from the sensor by cleavage of the single strand DNA at the ligation zone by the selected NAzyme.

Abstract: Nucleic acid memory strands encoding digital data using a sequence of homopolymer tracts of repeated nucleotides provides a cheaper and faster alternative to conventional digital DNA storage techniques. The use of homopolymer tracts allows for lower fidelity, high throughput sequencing techniques such as nanopore sequencing to read data encoded in the memory strands. Specialized synthesis techniques allow for synthesis of long memory strands capable of encoding large volumes of data despite the reduced data density afforded by homopolymer tracts as compared to conventional single nucleotide sequences.

Abstract: The invention relates to a new method of delivering an analyte to a transmembrane pore in a membrane. The method involves the use of microparticles.

Abstract: The present invention provides recovering an extracellular vesicle(s) having high purity from an extracellular vesicle-containing sample. Specifically, the present invention provides a method of recovering an extracellular vesicle(s), comprising: (1) treating an extracellular vesicle-containing sample with a chelating agent; and (2) separating the extracellular vesicle(s) from the extracellular vesicle-containing sample treated with the chelating agent.

Abstract: The disclosure provides methods for separating and/or purifying one or more molecules released from one or more fluid compartments or partitions, such as one or more droplets. Molecules can be released from a fluid compartment(s) and bound to supports that can be isolated via any suitable method, including example methods described herein. The disclosure also provides devices that can aid in isolating supports bound to molecules.

Abstract: Disclosed herein is a novel method of producing monodisperse aqueous droplets, as well as a novel microfluidic droplet generator. In some examples, the method comprises flowing an aqueous solution through a microchannel and into a sample reservoir of the microfluidic droplet generator, wherein monodisperse droplets of the aqueous solution form by step-emulsification at a step change in height at an intersection of a reservoir end of the microchannel and a sidewall of the sample reservoir. In some examples, the aqueous solution is a hydrogel precursor solution and monodisperse droplets of the hydrogel precursor solution form by step-emulsification at the step change in height at the intersection of the reservoir end of the microchannel and the sidewall of the sample reservoir. In some examples, the monodisperse droplets of the hydrogel precursor solution are incubated under conditions suitable for gelation to form hydrogel beads.

Abstract: The invention relates to the field of biotechnology and pharmaceutics. Proposed is a method for ultra-high performance screening of biological objects which is based on microfluidic generation of droplets of a biocompatible water-in-oil-in-water double emulsion, and also a method for producing a monodisperse biocompatible water-in-oil-in-water double emulsion. The invention can be used in diagnosing conditions and diseases in mammals, as well as for investigating biological objects.

Abstract: The present invention generally relates to a combination of molecular barcoding and emulsion-based microfluidics to isolate, lyse, barcode, and prepare nucleic acids from individual cells in a high-throughput manner.

Abstract: The present invention relates to a method for preparing a DNA oligomer into which a single nucleotide is incorporated using a terminal deoxynucleotidyl transferase. According to the present invention, by using a base hydrolysis reaction or a ribose-borate complex formation method, single incorporation of normal and modified nucleotides in a TdT enzyme-based DNA oligomer modification method can be facilitated. In addition, the method simultaneously provides the usability of TdT and the quantitativeness of modification group incorporation, thereby being effectively usable in the development of a quantitative detection technique or in a crosslinking reaction, both of which require quantitativeness and, according to the present invention, a DNA oligomer, into which a single nucleotide which is a product of a TdT reaction is incorporated, has an exposed a 3? hydroxyl terminus, which is an enzyme recognition site, such that an additional enzymatic technique such as primer extension or ligation can be introduced.

Abstract: A polynucleotide sequencing method comprises (i) removing a label and a blocking moiety from a blocked, labeled nucleotide incorporated into a copy polynucleotide strand that is complementary to at least a portion of a template polynucleotide strand; and (ii) washing the removed label and blocking moiety away from the copy strand with a wash solution comprising a first buffer comprising a scavenger compound. Removing the label and blocking moieties may comprise chemically removing the moieties. The first buffer may also comprise an antioxidant and may be used in a scanning buffer used during a nucleotide detection step.

Abstract: A device for treatment of cells with particles is disclosed. The device includes a semi-permeable membrane positioned between two plates, the first plate defining a first flow chamber and comprising a port, a flow channel, a transverse port, and a transverse flow channel, the first flow chamber constructed and arranged to deliver fluid in a transverse direction along the first side of the semi-permeable membrane, the second plate defining a second flow chamber and comprising a port. A method for transducing cells is disclosed. The method includes introducing a fluid with cells and viral particles into a flow chamber adjacent a semi-permeable membrane such that the cells and the viral particles are substantially evenly distributed on the semi-permeable membrane. The method also includes introducing a recovery fluid to suspend the cells and the viral particles, and separating the cells from the viral particles. A method of activating cells is disclosed.

Abstract: The present invention provides a use of a Cas protein, and a method and a kit for detecting target nucleic acid molecules. The method for detecting target nucleic acid molecules comprises adding a guide RNA, a Cas12a, and a nucleic acid probe into a reaction system containing target nucleic acid molecules to be detected, and detecting it after the reaction is completed.