This invention provides methods of amplifying genomic DNA to obtain an amplified representative population of genome fragments. Methods are further provided for obtaining amplified genomic DNA representations of a desired complexity. The invention further provides methods for simultaneously detecting large numbers of typable loci for an amplified representative population of genome fragments. Accordingly the methods can be used to genotype individuals on a genome-wide scale.

This invention provides methods of amplifying genomic DNA to obtain an amplified representative population of genome fragments. Methods are further provided for obtaining amplified genomic DNA representations of a desired complexity. The invention further provides methods for simultaneously detecting large numbers of typable loci for an amplified representative population of genome fragments. Accordingly the methods can be used to genotype individuals on a genome-wide scale.

Disclosed embodiments include illustrative piezoelectric element array assemblies, methods of fabricating a piezoelectric element array assembly, and systems and methods for shearing cellular material. Given by way of non-limiting example, an illustrative piezoelectric element array assembly includes at least one piezoelectric element configured to produce ultrasound energy responsive to amplified driving pulses. A lens layer is bonded to the at least one piezoelectric element. The lens layer has a plurality of lenses formed therein that are configured to focus ultrasound energy created by single ones of the at least one piezoelectric element into a plurality of wells of a microplate disposable in ultrasonic communication with the lens layer, wherein more than one of the plurality of lenses overlie single ones of the at least one piezoelectric element.

Disclosed embodiments include illustrative piezoelectric element array assemblies, methods of fabricating a piezoelectric element array assembly, and systems and methods for shearing cellular material. Given by way of non-limiting example, an illustrative piezoelectric element array assembly includes at least one piezoelectric element configured to produce ultrasound energy responsive to amplified driving pulses. A lens layer is bonded to the at least one piezoelectric element. The lens layer has a plurality of lenses formed therein that are configured to focus ultrasound energy created by single ones of the at least one piezoelectric element into a plurality of wells of a microplate disposable in ultrasonic communication with the lens layer, wherein more than one of the plurality of lenses overlie single ones of the at least one piezoelectric element.

The present invention may provide a small RNA detection sensor comprising: at one end thereof, a first sensing region comprising nucleotides having a sequence complementary to target small RNA; and a PCR-capable region that is coupled to the first sensing region, the small RNA detection sensor to synthesize a replication region complementary to the PCR-capable region by a DNA polymerase by using the target small RNA as a primer, and amplify the PCR-capable region and the replication region.

A method for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding is disclosed.

A method for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding is disclosed.

The present invention provides a method for integrally detecting nondestructive measurement information and genome-related information of single cells. More specifically, the present invention uses a method including: preparing a plurality of compartments containing single cell or a derivative thereof, a first bead(s), and a second bead(s) per compartment; detecting both nondestructive measurement information of single cell and imaging information of the first bead(s) and associating the nondestructive measurement information of single cell with the imaging information of the first bead(s) before preparation of each compartment or in each compartment; obtaining a hybridized complex; producing an amplified product derived from the hybridized complex; and integrally detecting nondestructive measurement information and genome-related information in single cell.

The present invention provides a method for integrally detecting nondestructive measurement information and genome-related information of single cells. More specifically, the present invention uses a method including: preparing a plurality of compartments containing single cell or a derivative thereof, a first bead(s), and a second bead(s) per compartment; detecting both nondestructive measurement information of single cell and imaging information of the first bead(s) and associating the nondestructive measurement information of single cell with the imaging information of the first bead(s) before preparation of each compartment or in each compartment; obtaining a hybridized complex; producing an amplified product derived from the hybridized complex; and integrally detecting nondestructive measurement information and genome-related information in single cell.

Provided includes methods, compositions and systems for single molecule seeding and amplification on a flow cell. In some embodiments, nucleic acids are isothermally seeded and amplified on a flow cell comprising multiple binding areas (e.g., pads), resulting in an ensemble of substantially the same amplified molecules on each of the binding areas.