Abstract: This invention relates, e.g., to a method for predicting a subject's response to a chemotherapeutic agent and/or the subject's prognosis, comprising measuring the phosphorylation state of at least one member of the mTOR pathway, and/or of at least one member of an interconnected polypeptide pathway (e.g. a member of the Akt pathway or a member of the IRS pathway), compared to a baseline value, in a cancer tissue or cancer cell sample from the subject, wherein an elevated level of the phosphorylation state compared to the baseline value indicates that the subject is a non-responder to the chemotherapeutic agent and/or has a poor prognosis. Also described is a method for treating a cancer in a subject in need thereof, wherein the subject exhibits an elevated level of the phosphorylation state, comprising administering one or more inhibitors of the mTOR and/or an interconnected pathway.

Abstract: This invention relates, e.g., to a method for predicting the response of a subject having estrogen-receptor-positive breast cancer to an inhibitor of the estrogen signaling pathway (e.g. tamoxifen), comprising measuring in a cancer sample from the subject the level of phosphorylation, compared to a baseline value, of one or more of the following members of an interconnected intracellular signaling pathway: (a) 4EBP1, and/or (b) p70S6, and/or (c) STAT3, and/or (d) FAK, wherein a significantly elevated level of phosphorylation of 4EBP1, and/or p70S6 and/or STAT3, and/or a significantly decreased level of phosphorylation of FAK, compared to the baseline value, indicates that the subject is likely to be a non-responder to the inhibitor and/or has a poor prognosis. Additional members of the intracellular signaling pathway whose phosphorylation can be measured are also described.

Abstract: A theranostics technique for describing signaling pathway activity within a cellular or tissue sample may include analyzing a cellular sample to obtain sample quantitative values for a series of target protein modification levels reflected in a set of a plurality of protein biomarkers in the sample. The sample quantitative values may be compared to reference quantitative values for the same series of protein modification levels. The reference quantitative values may be statistically processed from a plurality of comparable samples. The sample quantitative values may be displayed in relation to the reference quantitative values in a way that may suggest a specific course of treatment.

Abstract: The present invention relates to a method of quality assurance/quality control for high-throughput bioassay processes. The method includes generating a bioassay process model, and then comparing spectral data based on a combination of a biochip and a test serum to the bioassay process model to determine if the test sample and the bioassay process are producing acceptable data. Alternatively, the method may include comparing spectral data based on a combination of serum and diluents used in an electrospray process to the bioassay process model. If the bioassay process and test sample fall within the model, then the spectrum produced may be further analyzed.

Abstract: The invention describes a process for determining a biological state through the discovery and analysis of hidden or non-obvious, discriminatory biological data patterns. The biological data can be from health data, clinical data, or from a biological sample, (e.g., a biological sample from a human, e.g., serum, blood, saliva, plasma, nipple aspirants, synovial fluids, cerebrospinal fluids, sweat, urine, fecal matter, tears, bronchial lavage, swabbings, needle aspirantas, semen, vaginal fluids, pre-ejaculate.), etc. which is analyzed to determine the biological state of the donor. The biological state can be a pathologic diagnosis, toxicity state, efficacy of a drug, prognosis of a disease, etc. Specifically, the invention concerns processes that discover hidden discriminatory biological data patterns (e.g., patterns of protein expression in a serum sample that classify the biological state of an organ) that describe biological states.

Abstract: The invention describes a process for determining a biological state through the discovery and analysis of hidden or non-obvious, discriminatory biological data patterns. The biological data can be from health data, clinical data, or from a biological sample, (e.g., a biological sample from a human, e.g., serum, blood, saliva, plasma, nipple aspirants, synovial fluids, cerebrospinal fluids, sweat, urine, fecal matter, tears, bronchial lavage, swabbings, needle aspirantas, semen, vaginal fluids, pre-ejaculate.), etc. which is analyzed to determine the biological state of the donor. The biological state can be a pathologic diagnosis, toxicity state, efficacy of a drug, prognosis of a disease, etc. Specifically, the invention concerns processes that discover hidden discriminatory biological data patterns (e.g., patterns of protein expression in a serum sample that classify the biological state of an organ) that describe biological states.