Abstract: Provided herein are methods of detecting an analyte of interest to interrogate spatial gene expression in a sample using RNA-templated ligation.

Abstract: A sample holder includes a first member featuring a first retaining mechanism configured to retain a first substrate that includes a sample, a second member featuring a second retaining mechanism configured to retain a second substrate that includes a reagent medium, and an alignment mechanism connected to at least one of the first and second members, and configured to align the first and second members such that the sample contacts at least a portion of the reagent medium when the first and second members are aligned.

Abstract: The present disclosure in some aspects relates to methods and compositions for improved detection and quantification of one or more analytes present in a biological sample. In some aspects, the methods and compositions provided herein address issues associated with the heterogeneity of rolling circle amplification (RCA) products during in situ analyses. In some aspects, the methods and compositions disclosed herein provide more homogenous RCA products for improved sample imaging.

Abstract: This disclosure relates to methods for increasing capture efficiency of a spatial array using rolling circle amplification of a padlock probe that hybridizes to a capture probe. Also provided are methods for using such spatial arrays to detect a biological analyte in a biological sample.

Abstract: A sample holder is provided. The sample holder includes a first member including a first retaining mechanism configured to retain a first substrate comprising a sample. The first retaining mechanism configured to retain the first substrate disposed in a first plane. The sample holder further includes a second member including a second retaining mechanism configured to retain a second substrate including a reagent medium disposed in a second plane. The sample holder further includes an alignment mechanism connected to one or both of the first member and the second member. The alignment mechanism configured to align the first and second members along the first plane and/or the second plane such that the sample contacts at least a portion of the reagent medium when the first and second members are aligned and within a threshold distance along an axis orthogonal to the second plane.

Abstract: In some aspects, the present disclosure relates to methods for reducing the detection of false positive events during analysis of a biological sample. In some aspects, the method comprises use of a decoy oligonucleotide that can hybridize to a probe or to a target nucleic acid. The methods herein have particular applicability in reducing the detection of false positive events and in combining hybridization and ligation reactions into a single step. Also provided are kits comprising probes for use in such methods.

Abstract: Disclosed herein are methods of amplifying an analyte in a biological sample using a bridging oligonucleotide that hybridizes to a captured analyte. The methods disclosed herein include steps of (a) contacting a biological sample with a substrate having capture probes comprising a capture domain and a spatial barcode; (b) hybridizing the analyte to the capture domain; and (c) contacting the analyte to a bridging oligonucleotide comprising (i) a capture-probe-binding sequence, and (ii) an analyte-binding sequence; (d) extending the bridging oligonucleotide; and (e) determining (i) all or a part of the sequence of the analyte, or a complement thereof, and (ii) the spatial barcode, or a complement thereof, and using the determined sequence of (i) and (ii) to determine the location of the analyte in the biological sample.

Abstract: In some aspects disclosed herein are methods and compositions for detecting an analyte such as a target nucleic acid in a biological sample, said method comprising generating and analyzing a detectable signal associated with the target nucleic acid and a separate signal associated with a region of interest in the target nucleic acid.

Abstract: Provided herein are methods, compositions, and systems for improved in situ detection of analytes and spatial analysis using, e.g., a sequencing readout.

Abstract: Disclosed are methods, compositions and kits for contacting a sample containing a biological particle with a catalyst associated with or attached to a support. The biological particle may be cells and/or nuclei. The catalyst may be an enzyme configured to digest an extracellular molecule, such as an extracellular biological molecule, including extracellular nucleic acid molecules. In some examples, the biological particle is an aggregate of cells that is processed to single cells with a nuclease that is attached to a bead support. The bead and nuclease may subsequently be removed from the system. The single cells that result from the method can be used in single cell-based droplet systems for obtaining genome or transcriptome profiles of single cells.

Abstract: This disclosure relates to compositions and methods for analyzing a tissue section from a biological sample.

Abstract: This disclosure relates to compositions and methods for analyzing a tissue section from a biological sample.

Abstract: A method for aligning a sample to an array is provided. An image of sample image of a sample can be received by a data processor. The sample image having a first resolution. An array image including an overlay of an array with the sample and an array fiducial can be received by the data processor. The array image having a second resolution lower than the first resolution of the sample image. The sample image can be registered to the array image by aligning the sample image and the array image. An aligned image can be generated based on the registering. The aligned image can include an overlay of the sample image with the array. The aligned image can be provided by the data processor. A method for detecting fiducials associated with an array is provided. Systems and non-transitory computer readable mediums performing the method are also provided.

Abstract: Disclosed herein are systems for receiving a biological sample for analysis and methods for preparing and/or analyzing a biological sample. In various embodiments, a system includes a first layer comprising a first region configured to receive a sample, a gasket disposed on the first layer such that the gasket surrounds the first region, and a housing layer. The first layer is disposed between the gasket and the housing layer. The system further includes a clamp configured to apply a force on the gasket to form a liquid tight seal against the first layer.

Abstract: The present disclosure relates in some aspects to methods, probes, and kits for detection of a target analyte in a sample. In some embodiments, disclosed herein are methods in which a biological sample is contacted with a pre-formed detectable probe comprising a concatemeric region, e.g., a rolling circle amplification (RCA) product, comprising multiple copies of a unit sequence. Also disclosed herein are related probes and kits.

Abstract: A method for aligning a sample to an array is provided. An image of sample image of a sample can be received by a data processor. The sample image having a first resolution. An array image including an overlay of an array with the sample and an array fiducial can be received by the data processor. The array image having a second resolution lower than the first resolution of the sample image. The sample image can be registered to the array image by aligning the sample image and the array image. An aligned image can be generated based on the registering. The aligned image can can include an overlay of the sample image with the array. The aligned image can be provided by the data processor. A method for detecting fiducials associated with an array is provided. Systems and non-transitory computer readable mediums performing the method are also provided.

Abstract: Disclosed herein are methods of amplifying an analyte in a biological sample using a bridging oligonucleotide that hybridizes to a captured analyte. The methods disclosed herein include steps of (a) contacting a biological sample with a substrate having capture probes comprising a capture domain and a spatial barcode; (b) hybridizing the analyte to the capture domain; and (c) contacting the analyte to a bridging oligonucleotide comprising (i) a capture-probe-binding sequence, and (ii) an analyte-binding sequence; (d) extending the bridging oligonucleotide; and (e) determining (i) all or a part of the sequence of the analyte, or a complement thereof, and (ii) the spatial barcode, or a complement thereof, and using the determined sequence of (i) and (ii) to determine the location of the analyte in the biological sample.

Abstract: A sample holder includes a first member featuring a first retaining mechanism configured to retain a first substrate that includes a sample, a second member featuring a second retaining mechanism configured to retain a second substrate that includes a reagent medium, and an alignment mechanism connected to at least one of the first and second members, and configured to align the first and second members such that the sample contacts at least a portion of the reagent medium when the first and second members are aligned.

Abstract: Various implementations of electrophoretic systems and instruments are provided to improve electrophoresis and ease of use. Various electrophoretic systems and instruments utilize different electrode designs that can result in uniform electromigration of analytes. The electrophoretic systems and instrumentations optimize the size and/or location of electrodes relative to a sample, thereby increasing uniformity of electric field and reducing or minimizing drift of analyte migration. In addition, the electrophoresis systems and instruments provide a solution to conveniently check for electrical connections in the systems and instruments, and alert users of potential improper electrical connections, prior to performing electrophoresis.

Abstract: The present application provides methods and compositions for analyzing biological samples involving sequential decoding of barcode regions of nucleic acid probes, wherein the barcode regions comprise barcode sequences that define a sequential signal code. In particular, the present application provides a method wherein probe hybridization generates a double-stranded recognition site for a nuclease. Cleavage of the double-stranded recognition site releases a sequence associated with the probe, thus releasing a detectable label associated with the probe.