Provided relates to the field of cytometry, specifically to flow cytometric methods and kits for improved diagnosis, prognosis and monitoring of tumors and other lesions involving immune cell infiltration. Further provided are embodiments of the subject matter which relate to compositions and methods providing high resolution quantitative means for immunophenotyping and immune modeling, and for identification of disease prognostic and therapy predictive biomarkers.

Methods for extracting and analyzing a sample, and methods for predicting or diagnosing thyroid cancers and disorders, are described.

The invention provides biomarkers for predicting the response to checkpoint inhibitors. The inventors demonstrate that a PD-1/PD-L1 inhibitor exerts antitumor activity against tumor with low PD-L1 expression and immune-desert phenotype through blocking PD-L1 in the lymph nodes. The invention provides novel combinations of intratumoral markers for antigen cross-presenting cells and T cell chemokines which are expected to be superior efficacy-predicting biomarkers compared to existing methods.

The present disclosure provides a method of treating cancer by immune checkpoint blockade, or selecting patients for treatment with immune checkpoint blockers, by detecting tumors with high levels of T-lymphocytes with low levels of activation and proliferation. In various embodiments the tissue sample may be from a conventional biopsy. In various embodiments the cancer may be non-small cell lung cancer.

The present invention relates to an in vitro method for the prognosis of survival of a patient suffering from a solid cancer, comprising the quantification of the cell density of CD8+ cells and DC-LAMP+ dendritic cells present in a tumor tissue sample from said patient, wherein a high density of CD8+ cells and DC-LAMP+ dendritic cells indicates that the patient has a favorable prognosis, a high density of CD8+ cells and a low density of DC-LAMP+ dendritic cells indicates that the patient has a poor prognosis, and a low density of CD8+ cells and DC-LAMP+ dendritic cells indicates that the patient has the worst prognosis.

Methods of selecting test compounds on the basis of their cellular response profiles are disclosed. For a given test compound, a cellular response is determined by introducing into an array of individually addressable microwells a population of cells comprising a plurality of cell types and contacting the cells with the test compound. The cellular response profile for the test compound is then compared to a desired cellular response profile, and the test compound is selected based on the comparison.

Methods for identifying and isolating CD8 T cells that produce interleukin-13 upon activation are provided. The present methods leverage one or more newly-identified biomarkers to identify such CD8 T cells and, in certain cases, sort the same. Certain methods comprise obtaining a sample from a mammal, quantifying a level of expression of one or more biomarkers therein, and determining if the level of expression is elevated as compared, wherein an elevated expression level is indicative of an active disease state. Antisera and antibodies are also provided. In particular, an anti-C10orf128 antiserum formulated against a particular peptide is provided, such anti-C10orf128 antiserum characterized in that it identifies a subset of CD8 T cells that produce interleukin-13 upon activation.

The present disclosure relates in some aspects to methods, cells, and compositions for preparing cells and compositions for genetic engineering and cell therapy. Provided in some embodiments are streamlined cell preparation methods, e.g., for isolation, processing, incubation, and genetic engineering of cells and populations of cells. Also provided are cells and compositions produced by the methods and methods of their use. The cells can include immune cells, such as T cells, and generally include a plurality of isolated T cell populations or types. In some aspects, the methods are capable of preparing of a plurality of different cell populations for adoptive therapy using fewer steps and/or resources and/or reduced handling compared with other methods.

The invention relates to a method of determining an increased risk of cancer in an immunosuppressed patient, the method comprising: (a) determining the percentage of CD8+CD57+ T-cells in a population of CD8+ T-cells in a sample from the patient; wherein a percentage of 40% or greater of CD8+CD57+ T-cells is indicative of an increased risk of cancer; and/or (b) determining the percentage of CD4+CD57+ T-cells in a population of CD4+ T-cells in a sample from the patient; wherein a percentage of 10% or greater of CD4+CD57+ T-cells is indicative of an increased risk of cancer.

The present invention relates to the use of a nucleic acid molecule encoding a first reporter gene, bordered by at least one first pair and one second pair of sequences targeting a site-specific recombinase in order to detect cells of a mammal infected with a virus responsible for an immunodeficiency.