In alternative embodiments, provided are compositions and methods for treating, enhancing the drug sensitivity of, and preventing the formation of cancer stems cells, including preventing or slowing the development or generation of a beta-3 (β3)-expressing, or integrin β3 (ITG-B3)-expressing cancer or tumor cells. In alternative embodiments, provided are methods using histone acetyl transferase inhibitors and/or histone methyl transferase inhibitors to determine therapeutic values in cancer cells that induce an integrin β3 (ITGB3) polypeptide expression. In alternative embodiments, provided are kits, blister packages, lidded blisters or a blister card or packet, clamshells, trays or shrink wraps, comprising at least one compound, composition or formulation used to practice a method as provided herein, and at least one Growth Factor Inhibitor.

The present invention relates to epitopes of glypican-1 (GPC-1) and uses thereof.

Methods for the detection, enumeration and analysis of circulating tumor cells expressing insulin-like growth factor-1 receptors (IGF-1R) are disclosed. These methods are useful for cancer screening and staging, development of treatment regimens, and for monitoring for treatment responses, cancer recurrence or the like. Test kits that facilitate the detection, enumeration and analysis of such circulating tumor cells are also provided.

Methods for the detection, enumeration and analysis of circulating tumor cells expressing insulin-like growth factor-1 receptors (IGF-1R) are disclosed. These methods are useful for cancer screening and staging, development of treatment regimens, and for monitoring for treatment responses, cancer recurrence or the like. Test kits that facilitate the detection, enumeration and analysis of such circulating tumor cells are also provided.

This invention relates methods and compositions for identifying Colorectal Cancer (CRC) prognostic transcripts and groups of CRC prognostic transcripts useful in determining the prognosis of cancer in a patient, particularly for gastrointestinal cancer, such as gastric or colorectal cancer. Specifically, this invention relates to CRC cell culture-based methods to identify cell proliferation signatures.

The present disclosure relates to antibodies or fragments thereof that target at least one conformational epitope of a Notch 3 or mutant Notch 3 receptor; and compositions and methods of use thereof.

The present invention provides methods for identifying biomarker proteins that exhibit differential expression in subjects with a first lung condition versus healthy subjects or subjects with a second lung condition. The present invention also provides compositions comprising these biomarker proteins and methods of using these biomarker proteins or panels thereof to diagnose, classify, and monitor various lung conditions. The methods and compositions provided herein may be used to diagnose or classify a subject as having lung cancer or a non-cancerous condition, and to distinguish between different types of cancer (e.g., malignant versus benign, SCLC versus NSCLC).

The present invention is directed to a method of detecting a DEK protein in a human urine sample using an ELISA assay. Methods and compositions for detection of DEK using mAb 260-6F9F6 (as detection antibody) and mAb 16-2C9C3 (as capture antibody) in human urine are provided herein. Specifically, the ELISA assay utilizes a capture mAb and a detection mAb to yield a high sensitivity of <50 ng/mL. The presence of DEK in urine is useful in predicting or diagnosing the occurrence of bladder cancer in humans.

The present invention is directed to a method of detecting a DEK protein in a human urine sample using an ELISA assay. Methods and compositions for detection of DEK using mAb 260-6F9F6 (as detection antibody) and mAb 16-2C9C3 (as capture antibody) in human urine are provided herein. Specifically, the ELISA assay utilizes a capture mAb and a detection mAb to yield a high sensitivity of <50 ng/mL. The presence of DEK in urine is useful in predicting or diagnosing the occurrence of bladder cancer in humans.

The invention relates to the use of the monoclonal antibody NILO1 for the diagnosis, treatment and/or prevention of brain tumors and lesions. Particularly, the invention relates to methods for the diagnosis of brain tumors and brain lesions in which cells marked with said antibody, or with immunologically active fragments thereof, are detected. The invention also relates to the use of said monoclonal antibody, or immunologically active fragments thereof, as a medicament for the treatment and/or prevention of brain tumors and brain lesions. In a preferred embodiment of the invention, the monoclonal antibody NILO1, or its immunologically active fragments, are humanized.