Provided herein are methods for selecting/identifying and/or isolating cancer stem cells from a biological sample or a cell culture sample using a fluorescent glucose analog. Also provided herein are methods for selecting/identifying and/or isolating leukemia stem cells and subpopulations thereof. The present invention is based, in part, on the discovery that cancer stem cells can be selected/identified based upon a lower level of fluorescence of the fluorescent glucose analog compared to non-cancer stem cells and that specific genes are differentially expressed in leukemia stem cells compared to non-leukemia stem cells.

The present invention relates to the field of cancer and inflammation, and in particular methods of monitoring, diagnosis, prognosis, detecting, treating and preventing cancer and inflammation conditions. The use of composition comprises method of monitoring, diagnosis, prognosis, and detecting cancer and inflammation with EN2 and/or SATB2 expression and/or activity. The pharmaceutical composition will further comprise agents that inhibit EN2 and/or SATB2 expression or activity.

[Object] To provide a novel examination method for a cancer treatment effect, screening method for a peptide for a cancer vaccine, and peptide and composition for inducing an immune response against cancer. [Solving Means] Provided are an examination method for a cancer treatment effect and a screening method for a peptide for a cancer vaccine each including detecting an antibody against a cancer/testis antigen or an anti-p53 antibody in a sample. It is suitable that an anti-XAGE1 antibody (IgG and/or IgA) be detected, or an anti-NY-ESO-1 antibody (IgG) be detected. Also provided are a novel peptide and novel composition for inducing immune responses against cancer.

This invention relates generally to compositions and methods for identifying genes and gene networks that respond to, modulate, control or otherwise influence tumors and tissues, including cells and cell types of the tumors and tissues, and malignant, microenvironmental, or immunologic states of the tumor cells and tissues. The invention also relates to methods of diagnosing, prognosing and/or staging of tumors, tissues and cells, and provides compositions and methods of modulating expression of genes and gene networks of tumors, tissues and cells, as well as methods of identifying, designing and selecting appropriate treatment regimens.

The present application discloses methods of making anti-hepsin antibodies, anti-hepsin antibodies, methods of screening the activity of anti-hepsin antibodies, pharmaceutical compositions of anti-hepsin antibodies, kits containing anti-hepsin antibodies, and methods of using anti-hepsin antibodies to diagnose a cancer.

Embodiments of the disclosure include methods and compositions directed to targeting of cells that express the long form of Bone marrow stromal cell antigen 2 (BST2) protein, including cancer cells that express the long isoform of BST2. In particular embodiments, monoclonal antibodies or functionally active fragments thereof are utilized to target cells that express the long isoform of BST2. The monoclonal antibodies or functionally active fragments thereof may be utilized by themselves or as part of other entities, such as cells or engineered antigen receptors. The disclosure includes methods of treatment, prevention, and/or diagnosis using the encompassed antibodies or functional fragments thereof.

The disclosure relates to biomarkers for predicting a therapeutic response of a patient to an immune therapy. Since gene signatures and markers according to an aspect have an excellent predictive capacity for predicting a patient's therapeutic response to an immune therapy, a patient group predicted to exhibit therapeutic effects may be selected to perform an appropriate treatment, and a patient's suffering and costs may be reduced.

The invention concerns gene signatures obtained from microvesicles and a method of applying these gene signatures in helping to determine a biological condition. The determination of a biological condition may aid, for example, the diagnosis, prognosis, and therapy treatment selection for disease in a subject.

Provided herein are methods and articles of manufacture for use with cell therapy for the treatment of diseases or conditions, e.g., cancer, including for predicting and treating a toxicity. In some embodiments, the toxicity is related to cytokine release syndrome (CRS). The methods generally involve assessing a change in a factor indicative of tumor burden prior to administration of a cell therapy in a subject that is associated with and/or correlate to a risk of developing toxicity. In some aspects, the methods can be used to determine if the subject is at risk or likely at risk for developing a toxicity following administration of the cell therapy. Also provided are methods for treating a subject having a disease or condition, in some cases involving administration of the cell therapy, based on assessment of risk of developing a toxicity following administration of the therapy. Also provided herein are reagents and kits for performing the methods.

Provided are an anti-VEGFA-anti-PD-1 bispecific antibody and a use thereof. Specifically, the anti-VEGFA-anti-PD-1 bispecific antibody comprises: a PD-1-targeted first protein functional region and a VEGFA-targeted second protein functional region. According to an EU numbering system, mutation occurs at two positions of positions 234 and 235 of a heavy chain constant region of the immunoglobulin contained in the bispecific antibody, and after the mutation, an affinity constant of the bispecific antibody with FcγRI, FcγRIIa, FcγRIIIa, and/or C1q is decreased compared to that before the mutation. The bispecific antibody can specifically bind to VEGFA and PD-1, specifically relieve immunosuppression of VEGFA and PD-1 on an organism, and inhibit tumor-induced angiogenesis, and thus has good application prospects.