Abstract: The present technology relates to methods for determining whether a patient diagnosed with breast cancer, colorectal cancer, melanoma or lung cancer will benefit from or is predicted to be responsive to treatment with an individual therapeutic agent or a specific combination of therapeutic agents. These methods are based on screening a patient's solid tumors and detecting alterations in target nucleic acid sequences corresponding to a specific set of cancer-related genes. Kits for use in practicing the methods are also provided.

Abstract: The present technology relates to methods for determining whether a patient diagnosed with breast cancer, colorectal cancer, melanoma or lung cancer will benefit from or is predicted to be responsive to treatment with an individual therapeutic agent or a specific combination of therapeutic agents. These methods are based on screening a patient's solid tumors and detecting alterations in target nucleic acid sequences corresponding to a specific set of cancer-related genes. Kits for use in practicing the methods are also provided.

Abstract: Disclosed herein is a combination of genomic sequences whose methylation patterns have utility for the improved detection and differentiation between colorectal neoplasms. Further disclosed herein are methods, nucleic acids and kits for detecting or differentiating between colorectal neoplasms.

Abstract: Disclosed herein is a combination of genomic sequences whose methylation patterns have utility for the improved detection and differentiation between colorectal neoplasms. Further disclosed herein are methods, nucleic acids and kits for detecting or differentiating between colorectal neoplasms.

Abstract: Described herein are methods, compositions and kits directed to amplification of nucleic acids suitable for both next generation sequencing (NGS) and a second round of sequencing as validation, such as Sanger sequencing.

Abstract: Described herein are methods, compositions and kits directed to amplification of nucleic acids suitable for both next generation sequencing (NGS) and a second round of sequencing as validation, such as Sanger sequencing.

Abstract: The present technology relates to methods for determining whether a patient diagnosed with breast cancer, colorectal cancer, melanoma or lung cancer will benefit from or is predicted to be responsive to treatment with an individual therapeutic agent or a specific combination of therapeutic agents. These methods are based on screening a patient's solid tumors and detecting alterations in target nucleic acid sequences corresponding to a specific set of cancer-related genes. Kits for use in practicing the methods are also provided.

Abstract: The present technology relates to methods for determining whether a patient diagnosed with breast cancer, colorectal cancer, melanoma or lung cancer will benefit from or is predicted to be responsive to treatment with an individual therapeutic agent or a specific combination of therapeutic agents. These methods are based on screening a patient's solid tumors and detecting alterations in target nucleic acid sequences corresponding to a specific set of cancer-related genes. Kits for use in practicing the methods are also provided.

Abstract: Described herein are methods, compositions and kits directed to amplification of nucleic acids suitable for both next generation sequencing (NGS) and a second round of sequencing as validation, such as Sanger sequencing.

Abstract: Described herein are methods, compositions and kits directed to amplification of nucleic acids suitable for both next generation sequencing (NGS) and a second round of sequencing as validation, such as Sanger sequencing.

Abstract: The present technology relates to methods for determining whether a patient diagnosed with breast cancer, colorectal cancer, melanoma or lung cancer will benefit from or is predicted to be responsive to treatment with an individual therapeutic agent or a specific combination of therapeutic agents. These methods are based on screening a patient's solid tumors and detecting alterations in target nucleic acid sequences corresponding to a specific set of cancer-related genes. Kits for use in practicing the methods are also provided.

Abstract: Disclosed herein is a combination of genomic sequences whose methylation patterns have utility for the improved detection and differentiation between colorectal neoplasms. Further disclosed herein are methods, nucleic acids and kits for detecting or differentiating between colorectal neoplasms.

Abstract: Described herein are methods, compositions and kits directed to amplification of nucleic acids suitable for both next generation sequencing (NGS) and a second round of sequencing as validation, such as Sanger sequencing.

Abstract: Cancer markers are developed to detect diseases characterized by increased expression of apoptosis-suppressing genes, such as aggressive cancers. Genome wide analyses of genome copy number and gene expression in breast cancer revealed 66 genes in the human chromosomal regions, 8p11, 11q13, 17q12, and 20q13 that were amplified. Diagnosis and assessment of amplification levels of genes shown to be amplified are useful in prediction of patient outcome of a of patient's response and drug resistance in breast cancer. Certain genes were found to be high priority therapeutic targets by the identification of recurrent aberrations involving genome sequence, copy number and/or gene expression are associated with reduced survival duration in certain diseases and cancers, specifically breast cancer. Inhibitors of these genes will be useful therapies for treatment of these non-responsive cancers.

Abstract: Disclosed are new methods comprising the use of in situ hybridization to detect abnormal nucleic acid sequence copy numbers in one or more genomes wherein repetitive sequences that bind to multiple loci in a reference chromosome spread are either substantially removed and/or their hybridization signals suppressed. The invention termed Comparative Genomic Hybridization (CGH) provides for methods of determining the relative number of copies of nucleic acid sequences in one or more subject genomes or portions thereof (for example, a tumor cell) as a function of the location of those sequences in a reference genome (for example, a normal human genome). The intensity(ies) of the signals from each labeled subject nucleic acid and/or the differences in the ratios between different signals from the labeled subject nucleic acid sequences are compared to determine the relative copy numbers of the nucleic acid sequences in the one or more subject genomes as a function of position along the reference chromosome spread.

Abstract: The present invention relates to the identification of marker genes useful in the diagnosis and prognosis of clinically problematic subsets of primary breast cancers. More specifically, the invention relates to the identification of two sets of marker genes that are differentially expressed in and useful for the diagnosis and prognosis of subsets of hormone receptor-negative (HRneg; i.e., ER and PR negative) and triple-negative (Tneg; i.e., ER, PR and HER2 negative) primary breast cancers at highest risk for early metastatic relapse. The invention further provides methods for determining the best course of treatment for patients having one of these clinically problematic subsets of primary breast cancers. The invention also provides methods for identifying compounds that prevent or treat a subtype of breast cancer based on their ability to modulate the activity or expression level of one or more marker genes identified herein.

Abstract: The present invention provides a method of detecting nucleotide sequence differences between two nucleic acid samples. The method employs a comparative genomic hybridization (CGH) technique to analyze the sequence differences between the samples. This method permits the identification of small sequence differences (e.g., sequence divergence of 1% or less) in nucleic acid samples of high complexity (e.g., an entire genome).

Abstract: Cancer markers are developed to detect diseases characterized by increased expression of apoptosis-suppressing genes, such as aggressive cancers. Genome wide analyses of genome copy number and gene expression in breast cancer revealed 66 genes in the human chromosomal regions, 8p11, 11q13, 17q12, and 20q13 that were amplified. Diagnosis and assessment of amplification levels of genes shown to be amplified are useful in prediction of patient outcome of a of patient's response and drug resistance in breast cancer. Certain genes were found to be high priority therapeutic targets by the identification of recurrent aberrations involving genome sequence, copy number and/or gene expression are associated with reduced survival duration in certain diseases and cancers, specifically breast cancer. Inhibitors of these genes will be useful therapies for treatment of these non-responsive cancers.

Abstract: Disclosed are new methods comprising the use of in situ hybridization to detect abnormal nucleic acid sequence copy numbers in one or more genomes wherein repetitive sequences that bind to multiple loci in a reference chromosome spread are either substantially removed and/or their hybridization signals suppressed. The invention termed Comparative Genomic Hybridization (CGH) provides for methods of determining the relative number of copies of nucleic acid sequences in one or more subject genomes or portions thereof (for example, a tumor cell) as a function of the location of those sequences in a reference genome (for example, a normal human genome). The intensity(ies) of the signals from each labeled subject nucleic acid and/or the differences in the ratios between different signals from the labeled subject nucleic acid sequences are compared to determine the relative copy numbers of the nucleic acid sequences in the one or more subject genomes as a function of position along the reference chromosome spread.

Abstract: The present invention provides a method of detecting nucleotide sequence differences between two nucleic acid samples. The method employs a comparative genomic hybridization (CGH) technique to analyze the sequence differences between the samples. This method permits the identification of small sequence differences (e.g., sequence divergence of 1% or less) in nucleic acid samples of high complexity (e.g., an entire genome).