The disclosure pertains to epitopes identified in A-beta including conformational epitopes, antibodies thereto and methods of making and using immunogens and antibodies specific thereto.

The disclosure pertains to methods of treating or preventing a disease or condition associated with and/or induced by soluble A-beta oligomer such as Alzheimer's disease by administering to a subject in need thereof conformation specific and/or selective antibodies or binding fragments thereof and related products.

The present invention provides novel biomarkers associated with Down syndrome. In particular, biomarkers identified from a proteome analysis of blood samples collected from affected individuals are disclosed that can be used to evaluate the disease spectrum of each individual with Down syndrome. Methods of using such biomarkers to develop diagnostics and therapeutics for prognosis and treatment of the conditions and diseases accompanying Down syndrome, and to develop diagnostics and therapeutics for prognosis and treatment of conditions and diseases prevalent in typical individuals but rare in individuals with Down syndrome are also described.

The present disclosure relates to methods for screening and identifying a fetal trisomy. Certain embodiments of the present disclosure provide a method of screening for a fetal trisomy in a pregnant female subject. The method comprises detecting one or more lipid markers from the subject, wherein the one or more markers is indicative of the risk of a fetal trisomy in the subject, and determining the risk of a fetal trisomy in the pregnant female subject on the basis of the one or more lipid markers detected.

This disclosure provides systems and methods for mapping and/or measuring a mechanical property of a medium. The mechanical property can be measured by Brillouin spectroscopy. The systems and methods can include a three-dimensional imaging modality that is co-registered with a Brillouin probe beam of a Brillouin spectrometer. The three-dimensional imaging modality can be optical coherence tomography or Scheimpflug camera imaging.

The disclosure pertains to conformational epitopes in A-beta, antibodies thereto and methods of making and using immunogens and antibodies specific thereto.

A method of making a noninvasive molecular control and analysis is described. The method of making the noninvasive molecular control includes, predetermining a positive control for a condition of interest, selecting a cell line with a control marker for the condition of interest, amplifying release of cfDNA from the selected cell line, isolating the released cfDNA from the selected cell line, quantifying the control marker from the isolated cfDNA, determining a volume of the control marker for addition to an isolated control plasma, isolating the control plasma from a control sample, treating the isolated control plasma with a control stabilizer, determining a volume of the control plasma to add to the volume of control marker, combining the volume of the control marker with the isolated control plasma, and analyzing a sample against the noninvasive molecular control to determine the presence or absence of a condition of interest.

The disclosure pertains to epitopes identified in A-beta including conformational epitopes, antibodies thereto and methods of making and using immunogens and antibodies specific thereto.

Disclosed is a method to achieve digital quantification of DNA (i.e., counting differences between identical sequences) using direct shotgun sequencing followed by mapping to the chromosome of origin and enumeration of fragments per chromosome. The preferred method uses massively parallel sequencing, which can produce tens of millions of short sequence tags in a single run and enabling a sampling that can be statistically evaluated. By counting the number of sequence tags mapped to a predefined window in each chromosome, the over- or under-representation of any chromosome in maternal plasma DNA contributed by an aneuploid fetus can be detected. This method does not require the differentiation of fetal versus maternal DNA. The median count of autosomal values is used as a normalization constant to account for differences in total number of sequence tags is used for comparison between samples and between chromosomes.

Methods, systems, and apparatus are provided for determining whether a nucleic acid sequence imbalance exists within a biological sample. One or more cutoff values for determining an imbalance of, for example, the ratio of the two sequences (or sets of sequences) are chosen. The cutoff value may be determined based at least in part on the percentage of fetal DNA in a sample, such as maternal plasma, containing a background of maternal nucleic acid sequences. The percentage of fetal DNA can be calculated from the same or different data used to determine the cutoff value, and can use a locus where the mother is homozygous and the fetus is heterozygous. The cutoff value may be determined using many different types of methods, such as sequential probability ratio testing (SPRT).