The present invention concerns processes for barcoding nucleic acids from single cells and processes for genotyping single cells having a phenotype of interest.

An image sensor structure includes an image layer having an array of light detectors disposed therein. A device stack is disposed over the image layer. An array of light guides is disposed in the device stack. Each light guide is associated with a light detector. An array of nanowells is disposed over the device stack. Each nanowell is associated with a first light guide of the array of light guides. A first primer set is disposed throughout a first well region of each nanowell. A second primer set is disposed throughout a second well region of each nanowell. The second well region is adjacent the first well region. The first and second primer sets are operable to attach a forward strand cluster of forward polynucleotide strands in the first well region and a reverse strand cluster of reverse polynucleotide strands in the second well region.

An image sensor structure includes an image layer having an array of light detectors disposed therein. A device stack is disposed over the image layer. An array of light guides is disposed in the device stack. Each light guide is associated with a light detector. An array of nanowells is disposed over the device stack. Each nanowell is associated with a first light guide of the array of light guides. A first primer set is disposed throughout a first well region of each nanowell. A second primer set is disposed throughout a second well region of each nanowell. The second well region is adjacent the first well region. The first and second primer sets are operable to attach a forward strand cluster of forward polynucleotide strands in the first well region and a reverse strand cluster of reverse polynucleotide strands in the second well region.

In an example method, a series of time-based clustering images is generated for a plurality of library fragments from a genome sample. Each time-based clustering image in the series is sequentially generated. To generate each time-based clustering image in the series: i) a respective sample is introduced to a flow cell, the respective sample including contiguity preserved library fragments of the plurality of library fragments, wherein the contiguity preserved library fragments are attached to a solid support or are attached to each other; ii) the contiguity preserved library fragments are released from the solid support or from each other; iii) the contiguity preserved library fragments are amplified to generate a plurality of respective template strands; iv) the respective template strands are stained; and v) the respective template strands are imaged.

In an example method, a series of time-based clustering images is generated for a plurality of library fragments from a genome sample. Each time-based clustering image in the series is sequentially generated. To generate each time-based clustering image in the series: i) a respective sample is introduced to a flow cell, the respective sample including contiguity preserved library fragments of the plurality of library fragments, wherein the contiguity preserved library fragments are attached to a solid support or are attached to each other; ii) the contiguity preserved library fragments are released from the solid support or from each other; iii) the contiguity preserved library fragments are amplified to generate a plurality of respective template strands; iv) the respective template strands are stained; and v) the respective template strands are imaged.

The present invention, called Physical Characterization of Telomere (PCT), provides and advantageous, accurate and convenient new methods for the visualization, characterization and measurements of telomere sequences. It employs probes and dyes to create a pattern of physical images, classifies the images, and determines the lengths of telomere sequences. PCT brings to a deeper understanding of telomere modifications that occur either genome wide manner or in a chromosome specific way.

The present invention, called Physical Characterization of Telomere (PCT), provides and advantageous, accurate and convenient new methods for the visualization, characterization and measurements of telomere sequences. It employs probes and dyes to create a pattern of physical images, classifies the images, and determines the lengths of telomere sequences. PCT brings to a deeper understanding of telomere modifications that occur either genome wide manner or in a chromosome specific way.

Disclosed herein are methods and systems for detection and discrimination of optical signals from a densely packed substrate. These may have broad applications for biomolecule detection near or below the diffraction limit of optical systems, including in improving the efficiency and accuracy of polynucleotide sequencing applications.

Disclosed herein are methods and systems for detection and discrimination of optical signals from a densely packed substrate. These may have broad applications for biomolecule detection near or below the diffraction limit of optical systems, including in improving the efficiency and accuracy of polynucleotide sequencing applications.

Method and systems for identifying and distinguishing subjects using a biochip are described. Biochips comprising subject specific features comprising multiple non-overlapping probes are disclosed.