The present disclosure provides a method for cell preservation, for example, cryopreservation of cells exposed to ionizing radiation.

Described herein are methods and compositions relating to the treatment of cancer, e.g., breast cancer, using, e.g., aptamer-siRNA chimera molecules.

Provided are polypeptides and compositions comprising novel HSP-binding peptides. Such polypeptides and compositions are particularly useful as immunotherapeutics (e.g., cancer vaccines). Also provided are methods of inducing a cellular immune response using such polypeptides and compositions, methods of treating a disease using such polypeptides and compositions, kits comprising such polypeptides and compositions, and methods of making such compositions.

The present invention relates to microvesicles derived from natural tumor cells and tumor cells produced in vitro under a stress stimulus, such as radiation, which can be used in an effective manner as a therapeutic vaccine for cancer. The invention also relates to a therapeutic vaccine formulation containing the microvesicles, processes for the preparation and medical use thereof as a therapeutic vaccine to stimulate the antitumor immune system and treat cancer.

The present invention relates to vaccine(s) comprising cancer cells expressing antigen(s), excipients, optionally adjuvant wherein the said antigen(s) is expressed on contacting the said cancer cell with p38 inducer, for use in treatment of Cancer. The vaccine composition induces specific immune response against homologous and heterologus cancer cells of the tissue/organ. The invention also provides method of preparing the same.

The present disclosure provides methods of treatment with cells having a vaccine (e.g., gp96-Ig) and cells having a T-cell co-stimulatory molecule.

The invention disclosed herein relates generally to immunotherapy and, more specifically, to the use of immunotherapy for treating tumors and pathogen infected tissues by first priming patients with allogeneic cells designed to be rejected by a Th1 mediated mechanism, then inducing necrosis or apoptosis in a tumor or pathogen infected lesion by methods such as cryotherapy, irreversible electroporation, chemotherapy, radiation therapy, ultrasound therapy, ethanol chemoablation, microwave thermal ablation, radiofrequency energy or a combination thereof applied against at least a portion of the tumor or pathogen infected tissue, and then delivering one or more doses of allogeneic cells (e.g., Th1 cells) within or proximate to the tumor or pathogen-infected tissue in the primed patient. The present invention provides an immunotherapeutic strategy to develop de-novo systemic (adaptive) immunity to a tumor or pathogen.

The present invention relates to specific binding members which bind to lymphocyte-activation gene 3 (LAG-3). The specific binding members preferably comprise a LAG-3 antigen-binding site which may be located in two or more structural loops of a CH3 domain of the specific binding member. The specific binding members of the invention find application, for example, in cancer therapy.

The present invention relates to the treatment of cancer and to the prevention of cancer growth and/or metastasis. In particular, the invention relates to cellular and acellular vaccines containing C3d, a proteolytic product of complement (C3), and methods of enhancing a host immune response (e.g., a T cell mediated immune response) against cancers using same. Compositions and methods of the invention find use, alone or in conjunction with other cancer therapies, in treating lymphoma and/or cancers that develop and/or persist by evading host immune surveillance and/or responses (e.g., T-cell mediated immune responses). Compositions and methods of the invention find use in both clinical and research settings, for example, within the fields of biology, immunology, medicine, and oncology.

The present disclosure relates to protein molecules that specifically bind to 5T4 and/or 4-1BB. The molecules may have at least one humanized 5T4-binding or 4-1BB-binding domain. Such molecules are useful for the treatment of cancer. The protein molecule binding to 5T4 or 4-1BB may have a second binding domain that binds to another target. The molecules may bind both 5T4-expressing cells and a cell-surface molecule expressed by an effector cell to enhance effector cell activation, proliferation, survival and/or effector-cell mediated cytotoxicity. The disclosure also provides pharmaceutical compositions comprising the 5T4-binding or 4-1BB-binding polypeptide or protein molecules, nucleic acid molecules encoding these polypeptides and methods of making and using these molecules.