Disclosed herein are methods, compositions and systems for the interrogation of macromolecules, more particularly for preparation of isolated single macromolecules for subsequent processing of specific regions of interest within said macromolecule based on an analysis of the molecule's physical map. The disclosure is further related to the controlled segmentation of long nucleic acid parent molecules into smaller child molecules in a targeted manner such that further processing on said children may be performed with the knowledge of their origin within the parent, in a controlled environment enabled by purposefully designed microfluidic devices. Also disclosed is binding of regional specific barcodes along the length of a long nucleic acid molecule such that upon cleavage of said molecule into child molecules, the regional origin of the children can be tracked, in a controlled environment enabled by purposefully designed microfluidic devices. Finally, the disclosure is further related to droplet devices and method to control the encapsulation of long nucleic acid molecules or specific subregions thereof into a droplet, and further tracking said droplets with their contents.

Disclosed herein are methods, compositions and systems for the interrogation of macromolecules, more particularly for preparation of isolated single macromolecules for subsequent processing of specific regions of interest within said macromolecule based on an analysis of the molecule's physical map. The disclosure is further related to the controlled segmentation of long nucleic acid parent molecules into smaller child molecules in a targeted manner such that further processing on said children may be performed with the knowledge of their origin within the parent, in a controlled environment enabled by purposefully designed microfluidic devices. Also disclosed is binding of regional specific barcodes along the length of a long nucleic acid molecule such that upon cleavage of said molecule into child molecules, the regional origin of the children can be tracked, in a controlled environment enabled by purposefully designed microfluidic devices. Finally, the disclosure is further related to droplet devices and method to control the encapsulation of long nucleic acid molecules or specific subregions thereof into a droplet, and further tracking said droplets with their contents.

Provided herein are compositions and methods for sequencing using at least altering electrical characteristics of polymer ridges. In some examples, the bridges may span the space between first and second electrodes and may include a single-stranded conjugated polymer chain. A plurality of nucleotides may be coupled to corresponding labels. A polymerase may be coupled to the bridge and may add nucleotides to a first polynucleotide using at least a sequence of a second polynucleotide. The labels corresponding to those nucleotides respectively may alter an electrical characteristic of the conjugated polymer chain. Detection circuitry may detect a sequence in which the polymerase adds the nucleotides to the first polynucleotide using at least changes in an electrical signal through the bridge, the changes being responsive to the respective alterations of hybridization using the labels corresponding to those nucleotides.

Provided herein are compositions and methods for sequencing using at least altering electrical characteristics of polymer ridges. In some examples, the bridges may span the space between first and second electrodes and may include a single-stranded conjugated polymer chain. A plurality of nucleotides may be coupled to corresponding labels. A polymerase may be coupled to the bridge and may add nucleotides to a first polynucleotide using at least a sequence of a second polynucleotide. The labels corresponding to those nucleotides respectively may alter an electrical characteristic of the conjugated polymer chain. Detection circuitry may detect a sequence in which the polymerase adds the nucleotides to the first polynucleotide using at least changes in an electrical signal through the bridge, the changes being responsive to the respective alterations of hybridization using the labels corresponding to those nucleotides.

The present disclosure is based in part on probes, compositions, methods, and kits for simultaneous, multiplexed spatial detection and quantification of protein and/or nucleic acid expression in a user-defined region of a tissue, user-defined cell, and/or user-defined subcellular structure within a cell.--

The present disclosure is based in part on probes, compositions, methods, and kits for simultaneous, multiplexed spatial detection and quantification of protein and/or nucleic acid expression in a user-defined region of a tissue, user-defined cell, and/or user-defined subcellular structure within a cell.--

The present disclosure provides methods, systems, and kits for processing nucleic acid molecules. A method may comprise providing a template nucleic acid fragment (e.g., within a cell, cell bead, or cell nucleus) within a partition (e.g., a droplet or well) and subjecting the template nucleic acid fragment to one or more processes including a barcoding process and a single primer extension or amplification process. The processed template nucleic acid fragment may then be recovered from the partition and subjected to further amplification to provide material for subsequent sequencing analysis. The methods provided herein may permit simultaneous processing and analysis of both DNA and RNA molecules originating from the same cell, cell bead, or cell nucleus.

The present disclosure provides methods, systems, and kits for processing nucleic acid molecules. A method may comprise providing a template nucleic acid fragment (e.g., within a cell, cell bead, or cell nucleus) within a partition (e.g., a droplet or well) and subjecting the template nucleic acid fragment to one or more processes including a barcoding process and a single primer extension or amplification process. The processed template nucleic acid fragment may then be recovered from the partition and subjected to further amplification to provide material for subsequent sequencing analysis. The methods provided herein may permit simultaneous processing and analysis of both DNA and RNA molecules originating from the same cell, cell bead, or cell nucleus.

Provided herein are methods for generating circular nucleic acid molecules and circular nucleic acid libraries. The methods can be used to generate clonal populations of target nucleic acid molecules for downstream applications such as sequencing. Nucleic acid sequence methods, systems and kits are also provided for sequencing circular nucleic acid molecules.

Provided herein are methods for generating circular nucleic acid molecules and circular nucleic acid libraries. The methods can be used to generate clonal populations of target nucleic acid molecules for downstream applications such as sequencing. Nucleic acid sequence methods, systems and kits are also provided for sequencing circular nucleic acid molecules.