The present disclosure relates to compositions of ULSCs and/or conditioned media thereof. In particular, the disclosure relates to conditioned media containing therapeutic factors including growth factors, cytokines, chemokines and extra cellular matrix components.

Disclosed herein is a different and novel approach to cancer vaccines using a subject's own dendritic cells (DCs) and macrophages (Mphs) in combination to present cancer antigens to the immune system. Further disclosed are methods of producing monocyte-derived autologous DCs and Mphs loaded ex vivo with particular whole irradiated cancer cells which generates optimally activated immunostimulatory antigen-presenting cells (APCs) as a superior method for stimulating robust and long-lasting immunity to a particular cancer in vivo as compared with more traditional vaccination methods. Compositions, methods of use and methods for preparation of these DCs and Mphs with cancer cells are also disclosed herein.

The described invention provides a tumor cell vaccine comprising genetically modified tumor cell line of a particular tumor type that stably expresses high levels of two or more immunomodulators. According to some embodiments, an immunogenic amount of the tumor cell line variants may be selected for concomitant expression of two or more of recombinant membrane expressed IgG1, CD40L, TNF-alpha, as well as membrane and soluble forms of GM-CSF, and Flt-3L peptides that are effective to elicit an anti-tumor immune response compared to the parent unmodified tumor cell line as measured in vitro by a one-way mixed lymphocyte tumor reaction assay using human peripheral blood mononuclear cells and the genetically modified allogeneic cell vaccine candidate. According to some embodiments, the tumor cell vaccine candidate will induce an immune response in the recipient cancer patient that cross reacts with the patient's own (autologous) tumor cells, the effects of which will be sufficient to result in enhanced anti-tumor immunity contributing to the increased survival of a vaccinated patient cohort compared to a matched unvaccinated patient cohort.

Provided are methods and compositions for obtaining genome-engineered iPSCs, and derivative cells with stable and functional genome editing at selected sites. Also provided are cell populations or clonal cell lines derived from genome-engineered iPSCs, which comprise targeted integration of one or more exogenous polynucleotides, and/or in/dels in one or more selected endogenous genes.

The present invention relates to a non-agonist ligand, particularly an antibody, that specifically binds to LIGHT or its receptor LTβR thereby interrupting the interaction of LIGHT with LTβR for use in treatment of a haematologic malignancy.

The present invention provides methods or kits with inflammatory cytokines to pretreat 1-ISCs to augment their immune modulatory effect, in prevention and treatment of various diseases such as multiple sclerosis, arthritis, lupus, sepsis, hepatitis, cirrhosis, Parkinson's disease, chronic infections, and GvHD. The present invention relates to novel methods for enhancing the immunosuppressive or the immune stimulatory activities of mesenchymal stem cells (JvfSCs).

Compounds that either produced a higher proportion or greater absolute number of phenotypically identified nave, stem cell memory, central memory T cells, adaptive NK cells, and type I NKT cells are identified. Compositions and methods for modulating immune cells including T, NK, and NKT cells for adoptive cell therapies with improved efficacy are provided.

The disclosure relates to dental pulp stem cells, method of preparing dental pulp stem cells, and methods of treating a patient with nervous tissue injuries by using dental pulp stem cells.

It was found that culturing of fibroblasts in the presence of effective amounts of Tumor Necrosis Factor-alpha (TNF-α) known as a factor that induces hemorrhagic necrosis of tumor and Interleukin-4 (IL-4) known for its role in onset of allergic reactions leads to increase in the number of CD106-positive and G-CSF-positive fibroblasts.

Provided is a method for producing an economical bovine serum composition containing many factors useful for cell proliferation. The method includes a step of performing an anticoagulation treatment of bovine whole blood with an anticoagulant, a step of obtaining a buffy coat and a fraction with a heavier specific gravity than that of the buffy coat from the anticoagulated whole blood, and a step of promoting and activating an interaction between the obtained leukocytes and platelets at a given temperature for not less than a given time to cause secretion or release of a humoral factor from the leukocytes and/or platelets and performing a recoagulation treatment of blood components including the humoral factor with a re-coagulating agent.