The present invention provides a high throughput method for constructing and screening a compound library and a reaction device. Specifically, the method of the present invention comprises: (a) providing a reactor comprising n independent and addressable reaction chambers; (b) performing m independent synthesis reactions in said n reaction chambers, thereby constructing a compound library; and (c) performing activity tests in reaction chambers in which synthesis reactions are performed. In the present invention, the preparation and screening processes of a compound can be completed in the same reaction system. As the reactions of the present invention almost quantitatively generate products, the products can be directly used in enzymatic or even cytological activity test experiments without separation.

Aspects of the technology disclosed herein relate to methods of preparing and analyzing nucleic acids, e.g., cfDNA, and nucleic acids encoding immune receptors and immunoglobulins. In some embodiments, methods for preparing nucleic acids for sequence analysis (e.g., using next-generation sequencing) are provided herein.

The invention provides barcode libraries and methods of making and using them including obtaining a plurality of nucleic acid constructs in which each construct comprises a unique N-mer and a functional N-mer and segregating the constructs into a fluid compartments such that each compartment contains one or more copies of a unique construct. The invention further provides methods for digital PCR and for use of barcode libraries in digital PCR.

The invention provides barcode libraries and methods of making and using them including obtaining a plurality of nucleic acid constructs in which each construct comprises a unique N-mer and a functional N-mer and segregating the constructs into a fluid compartments such that each compartment contains one or more copies of a unique construct. The invention further provides methods for digital PCR and for use of barcode libraries in digital PCR.

The invention provides barcode libraries and methods of making and using them including obtaining a plurality of nucleic acid constructs in which each construct comprises a unique N-mer and a functional N-mer and segregating the constructs into a fluid compartments such that each compartment contains one or more copies of a unique construct. The invention further provides methods for digital PCR and for use of barcode libraries in digital PCR.

The invention provides barcode libraries and methods of making and using them including obtaining a plurality of nucleic acid constructs in which each construct comprises a unique N-mer and a functional N-mer and segregating the constructs into a fluid compartments such that each compartment contains one or more copies of a unique construct. The invention further provides methods for digital PCR and for use of barcode libraries in digital PCR.

The present invention relates to a parallel synthesis method and synthesizer of a compound library, and more specifically provides a parallel synthesis method and synthesizer of a compound library, which uniformly distribute a first reactant and perform independent reactions in separate spaces, and since it is possible to confirm the results for various reaction variables at once, the synthesis time of the compound library can be reduced with a high synthesis yield of the product.

The present invention relates to a parallel synthesis method and synthesizer of a compound library, and more specifically provides a parallel synthesis method and synthesizer of a compound library, which uniformly distribute a first reactant and perform independent reactions in separate spaces, and since it is possible to confirm the results for various reaction variables at once, the synthesis time of the compound library can be reduced with a high synthesis yield of the product.

The present disclosure provides methods, kits, and compositions for generating DNA molecules encoding CRISPR/Cas guide RNAs (e.g., Cas9 single guide RNAs or Cas9 targeter RNAs). A library of such DNA molecules can be generated from any DNA source. The methods include a step of contacting target DNA with one or more DNA endonucleases that specifically bind to and cleave within a recognition sequence that includes a PAM sequence, to generate a plurality of cleavage fragments, to which a DNA adapter can be attached. A distal-cleaving DNA endonuclease can be used that specifically binds to a recognition sequence in the DNA adapter and cleaves at a site within the attached DNA cleavage fragments to generate a library of CRISPR/Cas guide sequences. After removal of all or a portion of the DNA adapter, a constant region of a guide RNA can be attached to generate DNA molecules encoding CRISPR/Cas guide RNAs.

The present disclosure provides methods, kits, and compositions for generating DNA molecules encoding CRISPR/Cas guide RNAs (e.g., Cas9 single guide RNAs or Cas9 targeter RNAs). A library of such DNA molecules can be generated from any DNA source. The methods include a step of contacting target DNA with one or more DNA endonucleases that specifically bind to and cleave within a recognition sequence that includes a PAM sequence, to generate a plurality of cleavage fragments, to which a DNA adapter can be attached. A distal-cleaving DNA endonuclease can be used that specifically binds to a recognition sequence in the DNA adapter and cleaves at a site within the attached DNA cleavage fragments to generate a library of CRISPR/Cas guide sequences. After removal of all or a portion of the DNA adapter, a constant region of a guide RNA can be attached to generate DNA molecules encoding CRISPR/Cas guide RNAs.