Abstract: The invention provides anti-human pro-epiregulin and anti-human amphiregulin antibodies and methods of using the same. Anti-EREG antibodies raised against amino acids 148-169 and 156-169 of the human EREG protein, and anti-AREG antibodies raised against amino acids 238-252 of the human AREG protein are disclosed. Methods of using these antibodies to detect EREG and AREG and kits and other products for performing such methods are also disclosed.

Abstract: Described herein are methods for co-expression analysis of multiple markers in a tissue sample comprising: computing a heat map of marker expression for each of a plurality of single marker channel images, wherein each of the plurality of single marker channel images comprise a single marker; identifying one or more candidate regions of interest in each heat map of marker expression; computing overlay masks comprising the identified one or more candidate regions of interest from each heat map of marker expression; determining one or more co-localized regions of interest from the overlay masks; mapping the one or more co-localized regions of interest to a same coordinate position in each of the plurality of single marker channel images; and estimating a number of cells in at least one of the determined one or more co-localized regions of interest in each of the plurality of single marker channel images.

Abstract: Disclosed herein are methods for identifying a subject as having NSCLC that is predicted or is likely to respond to treatment with an ALK inhibitor, for example crizotinib. The methods include identifying a sample including NSCLC tumor cells as ALK-positive or ALK-negative using immunohistochemistry (IHC) and scoring methods disclosed herein. A subject is identified as having NSCLC likely to respond to treatment with an ALK inhibitor if the sample is identified as ALK-positive and is identified as having NSCLC not likely to respond to treatment with an ALK inhibitor if the sample is identified as ALK-negative. According to certain embodiments of the methods, subjects predicted to respond to an ALK inhibitor may then be treated with an ALK inhibitor such as crizotinib.

Abstract: Disclosed herein are methods for identifying a subject as having NSCLC that is predicted or is likely to respond to treatment with an ALK inhibitor, for example crizotinib. The methods include identifying a sample including NSCLC tumor cells as ALK-positive or ALK-negative using immunohistochemistry (IBC) and scoring methods disclosed herein. A subject is identified as having NSCLC likely to respond to treatment with an ALK inhibitor if the sample is identified as ALK-positive and is identified as having NSCLC not likely to respond to treatment with an ALK inhibitor if the sample is identified as ALK-negative. According to certain embodiments of the methods, subjects predicted to respond to an ALK inhibitor may then be treated with an ALK inhibitor such as crizotinib.

Abstract: Provided herein are methods of analyzing stage II colorectal cancer (CRC) samples (such as those that are mis-match repair proficient, pMMR), by scoring G-alpha interacting vesicle associated protein (GIV, also known as girdin) full-length (GIV-fl) expression in combination with lymphovascular invasion (LVI) status or clinical variables. The disclosed methods can be used to identify GIV-fl expressing tumors that are likely to recur (high risk) and those that are not likely to recur (high risk). Subjects identified as having a high risk CRC can be selected to receive chemotherapy or biotherapy for the CRC. Thus, in some examples, the disclosed methods can be used to identify CRC tumors that are likely to respond to chemotherapy or biotherapy. Also provided are computer implemented methods, systems, and kits that can be used with these methods.

Abstract: The present invention provides compositions and methods for simultaneously detecting mutational status and gene copy number. In particular, the present invention provides simultaneous measurement of gene copy number and detection of the L858R and Exon 19 del mutations in a tissue sample.

Abstract: Disclosed herein are methods for identifying a subject as having NSCLC that is predicted or is likely to respond to treatment with an ALK inhibitor, for example crizotinib. The methods include identifying a sample including NSCLC tumor cells as ALK-positive or ALK-negative using immunohistochemistry (IBC) and scoring methods disclosed herein. A subject is identified as having NSCLC likely to respond to treatment with an ALK inhibitor if the sample is identified as ALK-positive and is identified as having NSCLC not likely to respond to treatment with an ALK inhibitor if the sample is identified as ALK-negative. According to certain embodiments of the methods, subjects predicted to respond to an ALK inhibitor may then be treated with an ALK inhibitor such as crizotinib.

Abstract: Heterogeneity for biomarkers in a tissue sample can be calculated. A heterogeneity score can be combined with an immunohistochemistry combination score to provide breast cancer recurrence prognosis. Heterogeneity can be based on percent positivity determinations for a plurality of biomarkers according to how many cells in the sample stain positive. An immunohistochemistry combination score can be calculated. An imaging tool can support a digital pathologist workflow that includes designating fields of view in an image of the tissue sample. Based on the fields of view, a heterogeneity metric can be calculated and combined with an immunohistochemistry combination score to generate a breast cancer recurrence prognosis score.

Abstract: The present invention provides compositions and methods for simultaneously detecting mutational status and gene copy number. In particular, the present invention provides simultaneous measurement of gene copy number and detection of the L858R and Exon 19 del mutations in a tissue sample.

Abstract: Disclosed herein are methods of predicting prognosis of a neoplastic disease (such as lung cancer, for example NSCLC), including determining the IGF1R gene copy number in a biological sample from a patient having a neoplastic disease; wherein an increase in IGF1R copy number predicts a good prognosis of the neoplastic disease in the patient. Also disclosed herein are methods of scoring copy number of a gene of interest in a biological sample. The method includes identifying individual cells in the sample having highest number of signals for the gene of interest detected by in situ hybridization, counting the number of signals for the gene of interest in the identified individual cells and determining an average number of signals per cell.