The present disclosure is directed to methods and/or uses of oligonucleotide conjugates for assays and flow cytometry detections and related systems and/or kits. Certain methods are directed to a method for detecting one or more biological targets of a sample in a detection assay, comprising: providing a molecular probe, comprising a binding moiety and an oligonucleotide sequence, to a sample comprising one or more biological targets; binding the one or more biological targets with the binding moiety; providing a detectable component to the sample, wherein the detectable component comprises a signal generating moiety conjugated to an oligonucleotide sequence complementary to the oligonucleotide sequence of the molecular probe; hydridizing the oligonucleotide sequence of the target-bound molecular probe to the detectable component; and detecting a signal generated from the hydridized detectable component. Various other embodiments, applications etc. are disclosed herein.

Provided herein are methods, compositions, and systems for transposon loading. Transposons are loaded with nucleic acid molecules, allowing for transposition reactions of cellular nucleic acids. The present invention may improve transposon loading, yield of productive fragments, while minimizing potential nucleic acid fragment loss or cross-contamination.

Provided herein are methods, compositions, and systems for transposon loading. Transposons are loaded with nucleic acid molecules, allowing for transposition reactions of cellular nucleic acids. The present invention may improve transposon loading, yield of productive fragments, while minimizing potential nucleic acid fragment loss or cross-contamination.

Random arrays of single molecules are provided for carrying out large scale analyses, particularly of biomolecules, such as genomic DNA, cDNAs, proteins, and the like. In one aspect, arrays of the invention comprise concatemers of DNA fragments that are randomly disposed on a regular array of discrete spaced apart regions, such that substantially all such regions contain no more than a single concatemer.

Random arrays of single molecules are provided for carrying out large scale analyses, particularly of biomolecules, such as genomic DNA, cDNAs, proteins, and the like. In one aspect, arrays of the invention comprise concatemers of DNA fragments that are randomly disposed on a regular array of discrete spaced apart regions, such that substantially all such regions contain no more than a single concatemer.

Provided is a PCR-free library construction and sequencing method. A PCR-free high-throughput sequencing method is provided, including the following steps: obtaining a DNA fragment of target size by performing or not performing, based on a size of a nucleic acid sample, fragmentation on the nucleic acid sample; performing end repair and an A-tailing reaction; ligating an adapter containing a barcode; obtaining DNA nanoballs by performing single-strand cyclization and rolling circle replication; and loading and sequencing.

Provided is a PCR-free library construction and sequencing method. A PCR-free high-throughput sequencing method is provided, including the following steps: obtaining a DNA fragment of target size by performing or not performing, based on a size of a nucleic acid sample, fragmentation on the nucleic acid sample; performing end repair and an A-tailing reaction; ligating an adapter containing a barcode; obtaining DNA nanoballs by performing single-strand cyclization and rolling circle replication; and loading and sequencing.

Described herein is a method to create dendritic biocompatible polymers from pairs of complementary dendritic nucleic acid monomers in a controlled manner, using polymerization triggers. The dendritic monomers are constituted of nucleic acids and an organic polymer capable of self-assembly. A variety of additional improvements are described herein, including processes not requiring snap cooling, “wobble clamp” designs to confer a transitory measure of hairpin stability prior to branch migration, and multiple assemblies of amplifying systems. Depending on the context this technology could be used to reveal the presence of a large variety of analytes such as specific nucleic acid molecules, small molecules, proteins, and peptides.

Described herein is a method to create dendritic biocompatible polymers from pairs of complementary dendritic nucleic acid monomers in a controlled manner, using polymerization triggers. The dendritic monomers are constituted of nucleic acids and an organic polymer capable of self-assembly. A variety of additional improvements are described herein, including processes not requiring snap cooling, “wobble clamp” designs to confer a transitory measure of hairpin stability prior to branch migration, and multiple assemblies of amplifying systems. Depending on the context this technology could be used to reveal the presence of a large variety of analytes such as specific nucleic acid molecules, small molecules, proteins, and peptides.

Disclosed herein are erasable label systems that involve nanocage molecules positioned around nanoparticles, which can be loaded with, bound to, or adsorbed with imaging agents. The nanocages can contain targeting arms composed of ssDNA or ssRNA that can be used to target biomolecules. For DNA or RNA targeting, this can be done directly. Antibodies can be targeted using avidin-biotin coupling to ssDNA or direct ssDNA conjugation to the antibody surface. ssDNA or ssRNA complementary to one of the arms can then be used to “erase” the label.