Abstract: The present disclosure relates to processes for determining the number of nucleic acid repeats in a DNA fragment comprising a nucleic acid repeat region. One example method may include receiving DNA size and abundance data generated by resolving DNA amplification products. A set of low-pass data may be generated by applying a low-pass filter to the DNA size and abundance data and a set of band-pass data may be generated by applying a band-pass filter to the DNA size and abundance data. A peak of the DNA size and abundance data representative of a number of nucleic acid repeats in the DNA may be identified based on peaks identified from the low-pass data and the band-pass data.

Abstract: The present disclosure relates to processes for determining the number of nucleic acid repeats in a DNA fragment comprising a nucleic acid repeat region. One example method may include receiving DNA size and abundance data generated by resolving DNA amplification products. A set of low-pass data may be generated by applying a low-pass filter to the DNA size and abundance data and a set of band-pass data may be generated by applying a band-pass filter to the DNA size and abundance data. A peak of the DNA size and abundance data representative of a number of nucleic acid repeats in the DNA may be identified based on peaks identified from the low-pass data and the band-pass data.

Abstract: Described herein are methods directed to determining the carrier status or genotype of a subject. Described herein is a method that combines experimental and computational approaches to resolve the structure of genomic loci (i.e., the genotype) whose sequences are highly homologous to other sequences in the genome. In particular, the determination of carrier status and/or copy number of a gene in a subject, wherein the gene has a corresponding highly homologous homolog, e.g., gene or pseudogene, utilizes Next Generation Sequencing. Also described herein is a computer-assisted method for such determinations.

Abstract: The present disclosure relates to processes for determining the number of nucleic acid repeats in a DNA fragment comprising a nucleic acid repeat region. One example method may include receiving DNA size and abundance data generated by resolving DNA amplification products. A set of low-pass data may be generated by applying a low-pass filter to the DNA size and abundance data and a set of band-pass data may be generated by applying a band-pass filter to the DNA size and abundance data. A peak of the DNA size and abundance data representative of a number of nucleic acid repeats in the DNA may be identified based on peaks identified from the low-pass data and the band-pass data.

Abstract: The present disclosure relates to processes for determining the number of nucleic acid repeats in a DNA fragment comprising a nucleic acid repeat region. One example method may include receiving DNA size and abundance data generated by resolving DNA amplification products. A set of low-pass data may be generated by applying a low-pass filter to the DNA size and abundance data and a set of band-pass data may be generated by applying a band-pass filter to the DNA size and abundance data. A peak of the DNA size and abundance data representative of a number of nucleic acid repeats in the DNA may be identified based on peaks identified from the low-pass data and the band-pass data.

Abstract: A method of identifying and quantifying copy number variations in a gene of interest for a genomic DNA sample includes (i) fragmenting a genomic DNA sample to produce a plurality of polynucleotide fragments, (ii) isolating a plurality of target polynucleotide fragments, (iii) sequencing the plurality of target polynucleotide fragments, (iv) aligning fragment sequences to a reference sequence, (v) calculating read depths for base positions of the plurality of target polynucleotide fragments, (vi) calculating copy number likelihoods for each base position of the reference sequence, (vii) performing a breakpoint analysis on a set of fragment sequences to identify at least one sequence variation located between selected breakpoint regions of the target gene and calculate modified copy number likelihoods for base positions of the reference sequence based on the at least one sequence variation, and (viii) determining whether the target gene includes at least one copy number variation.

Abstract: Described herein are methods directed to determining the carrier status or genotype of a subject. Described herein is a method that combines experimental and computational approaches to resolve the structure of genomic loci (i.e., the genotype) whose sequences are highly homologous to other sequences in the genome. In particular, the determination of carrier status and/or copy number of a gene in a subject, wherein the gene has a corresponding highly homologous homolog, e.g., gene or pseudogene, utilizes Next Generation Sequencing. Also described herein is a computer-assisted method for such determinations.

Abstract: The present disclosure relates to processes for determining the number of nucleic acid repeats in a DNA fragment comprising a nucleic acid repeat region. One example method may include receiving DNA size and abundance data generated by resolving DNA amplification products. A set of low-pass data may be generated by applying a low-pass filter to the DNA size and abundance data and a set of band-pass data may be generated by applying a band-pass filter to the DNA size and abundance data. A peak of the DNA size and abundance data representative of a number of nucleic acid repeats in the DNA may be identified based on peaks identified from the low-pass data and the band-pass data.

Abstract: In a multiple-board computer system, diagnostics are primarily performed by highly reliable microcontroller units (MCUs) on each processor (and memory) board. Operated separately from the board central processing units so that board failure will not prohibit diagnostic routines, the MCUs are serially connected to a bus separate from the main bus. Redundant diagnostic processor board MCUs constantly monitor the other MCUs and the serial bus, and oversee the operation of an MCUs on a malfunctioning board. In an alternate embodiment the diagnostic processor boards are replaced by a microcomputer serving as a monitor.