The present disclosure provides methods for determining the ploidy status of a chromosome in a gestating fetus from genotypic data measured from a mixed sample of DNA comprising DNA from both the mother of the fetus and from the fetus, and optionally from genotypic data from the mother and father. The ploidy state is determined by using a joint distribution model to create a plurality of expected allele distributions for different possible fetal ploidy states given the parental genotypic data, and comparing the expected allelic distributions to the pattern of measured allelic distributions measured in the mixed sample, and choosing the ploidy state whose expected allelic distribution pattern most closely matches the observed allelic distribution pattern. The mixed sample of DNA may be preferentially enriched at a plurality of polymorphic loci in a way that minimizes the allelic bias, for example using massively multiplexed targeted PCR.

The instant disclosure provides methods of multi-assay processing and multi-assay analysis. Such multi-assay processing and analysis pertain to automated detection of target nucleic acids, e.g., as performed in the clinical setting for diagnostic purposes. Also provided are common assay timing protocols derived from a variety of individual nucleic acid amplification and analysis protocols and modified to prevent resource contention. The instant disclosure also provides systems and devices for practicing the methods as described herein.

The instant disclosure provides methods of multi-assay processing and multi-assay analysis. Such multi-assay processing and analysis pertain to automated detection of target nucleic acids, e.g., as performed in the clinical setting for diagnostic purposes. Also provided are common assay timing protocols derived from a variety of individual nucleic acid amplification and analysis protocols and modified to prevent resource contention. The instant disclosure also provides systems and devices for practicing the methods as described herein.

Provided herein is technology relating to detecting and identifying nucleic acids and particularly, but not exclusively, to compositions, methods, kits, and systems for detecting, identifying, and quantifying target nucleic acids with high confidence at single-molecule resolution.

Provided herein is technology relating to detecting and identifying nucleic acids and particularly, but not exclusively, to compositions, methods, kits, and systems for detecting, identifying, and quantifying target nucleic acids with high confidence at single-molecule resolution.

Provided are methods and systems for detecting formation of nucleotide-specific ternary complexes comprising a DNA polymerase, a nucleic acid, and a nucleotide complementary to the templated base of the primed template nucleic acid. The methods and systems facilitate determination of the next correct nucleotide without requiring chemical incorporation of the nucleotide into the primer. This advantageously improves signal-to-noise ratios and increases the quality of results obtainable in a sequencing-by-binding protocol, and enables extended read lengths. These results can even be achieved in procedures employing unlabeled, native nucleotides.

Provided are methods and systems for detecting formation of nucleotide-specific ternary complexes comprising a DNA polymerase, a nucleic acid, and a nucleotide complementary to the templated base of the primed template nucleic acid. The methods and systems facilitate determination of the next correct nucleotide without requiring chemical incorporation of the nucleotide into the primer. This advantageously improves signal-to-noise ratios and increases the quality of results obtainable in a sequencing-by-binding protocol, and enables extended read lengths. These results can even be achieved in procedures employing unlabeled, native nucleotides.

The present invention is focused on a method, kit and system for determining the presence or absence of minimal residual disease in a subject who has been treated for a proliferative disease wherein said method, kit and system comprise: (A) amplifying and sequencing at least one nucleotide sequence comprised in genomic DNA from a biological sample obtained from said subject prior to treatment for said disease, to obtain a first list of characters reading from left to right; (B) amplifying and sequencing at least one nucleotide sequence comprised in genomic DNA from a biological sample obtained from said subject after treatment for said disease, to obtain a second list of characters reading from left to right, wherein when a nucleotide sequence is mutated it is a genetic marker for said proliferative disease; (C) determining, for each second list of characters obtained in step (B), the degree of similarity, DS, with each first list of characters obtained in step (A); (D) selecting, for each second list of characters obtained in step (B), the DS of highest value, DS.sub.HV; (E) adding up the number of second lists of characters which have a DS.sub.HV that is greater than a threshold value, T, to obtain L.sub.c, (F) adding up the total number of second lists of characters, L.sub.t; (G) calculating the level of minimal residual disease, MRD, according to any of the following formulae:
MRD=(L.sub.c×k)/(L.sub.t×D)
or
MRD=L.sub.c/L.sub.t
or
MRD=g×L.sub.c×(D/k)/L.sub.t.sup.2; (H) determining (i) the minimum variant read frequency, min VRF, of said genetic marker, (ii) the limit of detection, D-limit, of said genetic marker (iii) the average mutation noise, avMut and (iv) the average position noise, avPos; (I) determining the experimental sensitivity, ES, from the greater of the min VRF, D-limit, avMut and avPos or from the greater of min VRF and D-limit; (J) determining the presence or absence of minimal residual disease in said subject by comparing the value of the lev

The present invention is focused on a method, kit and system for determining the presence or absence of minimal residual disease in a subject who has been treated for a proliferative disease wherein said method, kit and system comprise: (A) amplifying and sequencing at least one nucleotide sequence comprised in genomic DNA from a biological sample obtained from said subject prior to treatment for said disease, to obtain a first list of characters reading from left to right; (B) amplifying and sequencing at least one nucleotide sequence comprised in genomic DNA from a biological sample obtained from said subject after treatment for said disease, to obtain a second list of characters reading from left to right, wherein when a nucleotide sequence is mutated it is a genetic marker for said proliferative disease; (C) determining, for each second list of characters obtained in step (B), the degree of similarity, DS, with each first list of characters obtained in step (A); (D) selecting, for each second list of characters obtained in step (B), the DS of highest value, DS.sub.HV; (E) adding up the number of second lists of characters which have a DS.sub.HV that is greater than a threshold value, T, to obtain L.sub.c, (F) adding up the total number of second lists of characters, L.sub.t; (G) calculating the level of minimal residual disease, MRD, according to any of the following formulae:
MRD=(L.sub.c×k)/(L.sub.t×D)
or
MRD=L.sub.c/L.sub.t
or
MRD=g×L.sub.c×(D/k)/L.sub.t.sup.2; (H) determining (i) the minimum variant read frequency, min VRF, of said genetic marker, (ii) the limit of detection, D-limit, of said genetic marker (iii) the average mutation noise, avMut and (iv) the average position noise, avPos; (I) determining the experimental sensitivity, ES, from the greater of the min VRF, D-limit, avMut and avPos or from the greater of min VRF and D-limit; (J) determining the presence or absence of minimal residual disease in said subject by comparing the value of the lev

A method of manufacturing and using a nanofluidic NAND transistor sensor array scheme including a plurality of nanopore channel pillars, a plurality of respective fluidic channels, a plurality of gate electrodes, a top chamber, and a bottom chamber includes placing a sensor substrate in an electrolyte solution comprising biomolecules and DNA. The method also includes placing first and second electrodes in the electrolyte solution (Vpp and Vss of the nanofluidic NAND transistor); forming the nanopore channel pillars; placing the gate electrodes and gate insulators in respective walls of the nanopore channel pillars; applying an electrophoretic bias in the first and second electrodes; applying a bias in the gate electrodes; detecting a change in an electrode current in the electrolyte solution caused by a change in a gate voltage; and detecting a change in a surface charge in nanopore channel electrodes in the respective fluidic channels.