The invention relates to a method of isolating a T cell that expresses a T cell receptor capable of binding specifically to an antigen presented by a cancer cell in association with an MR1 molecule. The method comprises the steps of (a) providing a preparation of T cells, (b) contacting the preparation with cancer cells expressing MR1 protein; (c) isolating a T cell that is specifically reactive to said cancer cells. The invention further relates to a method of preparing a T cell preparation expressing select MR1 recognizing T cell receptors from transgene expression vectors, the use of such T cell preparations in treatment of cancer, and to collections of MR1 reactive T cell receptor encoding nucleic acids and cells.

The present disclosure relates generally to methods and systems for detecting, characterizing biomarker expression and morphological analysis in cell samples. The methods allow for the use of automated platforms to stain cells for molecular biomarkers and Romanowsky-type staining for cell morphology analysis. Cells that are prepared according to the disclosed methods can also be used in the diagnosis of certain conditions.

Disclosed are subpopulations of mammalian stem cell- or mammalian progenitor cell-derived cardiomyocytes. The subpopulations of cardiomyocytes contain a portion of a population of mammalian stem cell- or mammalian progenitor cell-derived cardiomyocytes. The subpopulations of cardiomyocytes can be CD36.sup.+ subpopulations or CD36.sup.− subpopulations. Disclosed are methods of isolating and of using the subpopulations of cardiomyocytes, particularly in cardiac disease modeling, drug screening, cardiotoxicity testing, and cardiac regeneration/repair.

Disclosed herein are methods for isolating target cells from blood, involving mixing in an open container an undiluted blood sample having a volume of 10 ml or less, and binding agents, wherein each binding agent comprises (A) a primary binding agent comprising an agent capable of binding to at least one cellular epitope on target cells in the undiluted blood sample, (B) a first linker bound to the primary binding agent, to generate binding agent-attached target cells in the undiluted blood sample; contacting the binding agent-attached target cells in the undiluted blood sample with a plurality of buoyant reagents that include a second linker capable of binding to the first linker to generate an undiluted buoyant reagent-attached target cell mixture; diluting the undiluted buoyant reagent-attached target cell mixture by at least 20% to produce a diluted buoyant reagent-attached target cell mixture; applying a vectorial force, such as centrifugal force, to the diluted buoyant reagent-attached target cell mixture to generate a stratified diluted buoyant reagent-attached target cell mixture; removing the buoyant reagent-attached target cells from the stratified diluted buoyant reagent-attached target cell mixture; and isolating the target cells from the buoyant reagent-attached target cells.

Described herein are various systems, methods, and apparatus for systematic creation of isolated homogeneous colonies of cells from vector-based lineages. The vector-based lineages may originate from multiple types of viral vector families (e.g., Paramyx-oviridae, Retroviridae, Parvoviridae) or non-natural engineered vectors or a plurality of vector combinations, for example. In certain embodiments, the isolated homogeneous colonies of cells are vector-free sub-colonies; in other embodiments, the isolated homogeneous colonies of cells are homogeneous vector sub-colonies. In other embodiments, vector mixed sub-colonies are created. The disclosed systems, methods, and apparatus are useful for inducible pluripotent stem cell (iPSC) production and work by selectively binding to one or more corresponding protein markers expressed on the surface of a cell that indicate that cellular reprogramming has occurred. Software is used to automate the purification and isolation of the iPSCs produced.

A screening method is provided. Cells secreting target antibodies are screened by mixing candidate cells labeled with a first fluorescent molecule, a capture antigen and a labeled antibody against a target antibody and incubating, labeling using a high content cell imager and sorting using flow cytometry so as to screen cells secreting target antibodies. The screening method disclosed in the present application can automatically complete the labeling and sorting of target candidate cells in high throughput by labeling with a fluorescent molecule in combination with high-content cell imager and flow cytometer, so as to provide sufficient quantity of cells for subsequent amplification to obtain their antibody sequences and screen affinity antibodies. This method greatly improves the screening efficiency.

Methods, compositions and cells are provided that identify and isolate a population of adult non-embryonic progenitor cells having multilineage potential, physical diameters of about 2 μm to about 8 μm in size or about 4 μm to about 6 μm, and expressing at least one of the stem cell associated genes among Oct-4, KLF-4, Nanog, Sox-2, Rex-1, GDF-3 or Stella. Methods are also provided that identify and isolate populations, which are subsets or subpopulations of progenitor adult stem cells within the population of the adult stem cells which is a heterogeneous population, the methods including contacting the adult stem cells with a ligand specific for at least one of: CD99, tetraspan, ICAM4, full-length MUC1, and truncated MUC1 receptor, in which a presence of a surface protein on the cells that bind to the ligand identifies the population which is the subset of the differentiated progenitor adult stem cells.

The present disclosure provides a therapy for diabetes that targets abnormal stem cells in combination with stem cell migration. In one embodiment, the present disclosure provides a therapy for diabetes and/or diabetes-related diseases and disorders and/or symptoms that targets abnormal stem cells in combination with stem cell migration. In one embodiment, the present disclosure provides diagnosis of diabetes and/or diabetes-related diseases and disorders and/or symptoms, or the risk thereof, using abnormal stem cell migration and/or residence as an indicator.

A method for cellular separation, including: combining sperm with magnetic particles comprising a negative zeta potential charge to form an admixture, each magnetic particle being no greater than 1,000 nm; binding a subpopulation of said sperm to said magnetic particles through an electrical charge interaction to provide a bound subpopulation; and magnetically separating said bound subpopulation from unbound sperm.

The present invention discloses an application of a β3 adrenergic receptor (ADRB3) as a marker for detecting a plurality of diseases, and an application of anti-human ADRB3 monoclonal antibody in diagnosing a disease and preparing a drug for treating the disease. The present invention finds through research that the ADRB3 is a key receptor in nerve-endocrine-immunoregulatory network, and an ADRB3-mediated signaling pathway regulates proliferation and differentiation of neutrophils, lymphocytes and tumor cells. Under normal circumstances, the ADRB3 maintains the non-specific immunocompetence and specific immunocompetence of an organism, and eliminates pathogenic microorganisms and aged organism tissues to play a role in protecting the organism and anti-aging. Under pathological conditions, excessive activation of the signaling pathway will cause systemic chronic inflammation, and destroy immune homeostasis. Therefore, the ADRB3 can be used as a diagnostic marker and a therapeutic target for a plurality of diseases. Anti-human ADRB3 antibody can specifically bond with the ADRB3, regulate the activity of the ADRB3, has the functions of resisting cancer, inflammation, poisoning, shock, allergy, viral infection, autoimmune disease, disease caused by regenerative dysfunction, autoimmune disease, cachexia, cardiovascular and cerebrovascular disease, neurodegenerative disease and aging, regulating autophagy, treating aging disease, etc., and has important medical value and research and application prospects.