Methods, devices, and systems for performing digital assays are provided. In certain aspects, the digital assays comprise compartmentalized volumes. In certain aspects, the methods, devices, and systems can be used for the amplification and detection of nucleic acids. In certain aspects, the methods, devices, and systems can be used for the recognition, detection, and sizing of droplets in a volume.

Methods, devices, and systems for performing digital assays are provided. In certain aspects, the digital assays comprise compartmentalized volumes. In certain aspects, the methods, devices, and systems can be used for the amplification and detection of nucleic acids. In certain aspects, the methods, devices, and systems can be used for the recognition, detection, and sizing of droplets in a volume.

Disclosed are methods for screening biological samples for the presence unknown microbes, such as bacteria and archaea or unknown eukaryotes using rRNA gene sequences or other highly conserved genetic regions, across multiple biological samples using a unique sequence tag (barcode) corresponding to the sample. The screening process tracks the unknown microbe or eukaryote in a diluted sample where the DNA has been prepared using whole genome amplification. The whole genome of the unknown microbe or eukaryote is then sequenced and assembled.

Disclosed are methods for screening biological samples for the presence unknown microbes, such as bacteria and archaea or unknown eukaryotes using rRNA gene sequences or other highly conserved genetic regions, across multiple biological samples using a unique sequence tag (barcode) corresponding to the sample. The screening process tracks the unknown microbe or eukaryote in a diluted sample where the DNA has been prepared using whole genome amplification. The whole genome of the unknown microbe or eukaryote is then sequenced and assembled.

Methods and apparatus for separating, concentrating and/or detecting molecules based on differences in binding affinity to a probe are provided. The molecules may be differentially modified. The molecules may be differentially methylated nucleic acids. The methods can be used in fields such as epigenetics or oncology to selectively concentrate or detect the presence of specific biomolecules or differentially modified biomolecules, to provide diagnostics for disorders such as fetal genetic disorders, to detect biomarkers in cancer, organ failure, disease states, infection or the like.

Methods and apparatus for separating, concentrating and/or detecting molecules based on differences in binding affinity to a probe are provided. The molecules may be differentially modified. The molecules may be differentially methylated nucleic acids. The methods can be used in fields such as epigenetics or oncology to selectively concentrate or detect the presence of specific biomolecules or differentially modified biomolecules, to provide diagnostics for disorders such as fetal genetic disorders, to detect biomarkers in cancer, organ failure, disease states, infection or the like.

Techniques are provided for determining settings of a dPCR experiment for the detection of a chromosomal aneuploidy in a plasma sample from a female pregnant with a fetus. Data about the sample, the dPCR process, and a desired accuracy can be used to determine the settings. Such settings can include a minimal input number of control chromosome molecules for the dPCR experiment, a minimal number of control chromosome molecules for a pre-amplification procedure, and a number of PCR cycles in the pre-amplification procedure. These settings can be used to satisfy the accuracy specified by the accuracy data. Thus, the dPCR experiment can be designed to achieve the desired accuracy while reducing cost, e.g., by not using more of a sample than needed and not performing more pre-amplification than needed or performing more manipulations than needed.

Techniques are provided for determining settings of a dPCR experiment for the detection of a chromosomal aneuploidy in a plasma sample from a female pregnant with a fetus. Data about the sample, the dPCR process, and a desired accuracy can be used to determine the settings. Such settings can include a minimal input number of control chromosome molecules for the dPCR experiment, a minimal number of control chromosome molecules for a pre-amplification procedure, and a number of PCR cycles in the pre-amplification procedure. These settings can be used to satisfy the accuracy specified by the accuracy data. Thus, the dPCR experiment can be designed to achieve the desired accuracy while reducing cost, e.g., by not using more of a sample than needed and not performing more pre-amplification than needed or performing more manipulations than needed.

Described and featured herein are isolated oligonucleotides containing, from 5 to 3, a nicking enzyme recognition sequence, at least 9 nucleotides that specifically bind a target nucleic acid molecule, and 2 modified nucleotides. The isolated oligonucleotides may be used in compositions and methods for quantifying detection of a target oligonucleotide in a sample in real time. These methods are compatible with target oligonucleotides amplified using a Nicking and Extension Amplification Reaction (NEAR) reaction.

Described and featured herein are isolated oligonucleotides containing, from 5 to 3, a nicking enzyme recognition sequence, at least 9 nucleotides that specifically bind a target nucleic acid molecule, and 2 modified nucleotides. The isolated oligonucleotides may be used in compositions and methods for quantifying detection of a target oligonucleotide in a sample in real time. These methods are compatible with target oligonucleotides amplified using a Nicking and Extension Amplification Reaction (NEAR) reaction.