Abstract: This invention relates to compositions and methods for immunotherapy of cancer. Specifically, a method of cancer immunotherapy is described which results in the systemic liquidation of both solid and metastatic tumors whereever they reside in the body. The compositions include activated allogeneic Th1 cells that when administered appropriately lead to liquidation of tumors. The method includes administering priming doses of the therapeutic composition, ablation of a selected tumor lesion along with intratumoral injection of the composition and then infusion of the therapeutic composition. These steps enable the systemic liquidation of tumors secondary to immune cell infiltration and leads to immune-mediated tumor eradication.

Abstract: T-cells are generated with enhanced immunostimulatory capabilities for use in self therapy treatment protocols, by utilizing a biodegradable device with a biodegradable support that has one or more agents that are reactive to T-cell surface moieties. The biodegradable devices are mixed with the T-cells sufficiently so that the one or more agents cross-link with the T-cells' surface moieties and deliver a signal to the T-cells to enhance immunostimulatory capabilities.

Abstract: A method of manipulating allogeneic cells for use in allogeneic cell therapy providing a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism, or “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect The anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect. The highly activated allogeneic cells of the invention can be used to stimulate host immunity in a complete HLA mis-matched setting in a patient.

Abstract: A method of manipulating allogeneic cells for use in allogeneic cell therapy protocols is described. The method provides a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism called the “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect. The effectiveness and widespread application of the anti-tumor GVT effect is limited by the severe toxicity of the GVH effect. In the present invention, the anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect.

Abstract: A method of manipulating allogeneic cells for use in allogeneic cell therapy providing a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism, or “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect. The anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect. The highly activated allogeneic cells of the invention can be used to stimulate host immunity in a complete HLA mis-matched setting in a patient.

Abstract: A novel cell type has been generated that has both Th1 characteristics and cytolytic activity. These Th1/killer cells are CD4+ cells purified from peripheral blood and manipulated to have Th1 characteristics such as production of IFN-gamma combined with cytolytic activity similar to cytotoxic T-cells (CTL). The CTL activity is targeted toward diseased cells, not normal cells. The cytolytic activity of the Th1/killer cells is mediated by Granzyme B-Perforin mechanism and results in apoptotic death of diseased cells. Methods of producing and using these Th1/killer cells include isolating CD4+ cells from peripheral blood, activating the CD4+ T-cells to form Th1/killer cells and administering these Th1/killer cells with the cytolytic activity to a patient wherein the Th1/killer cells are allogeneic to the patient.

Abstract: A novel cell type has been generated that has both Th1 characteristics and cytolytic activity. These Th1/killer cells are CD4+ cells purified from peripheral blood and manipulated to have Th1 characteristics such as production of IFN-gamma combined with cytolytic activity similar to cytotoxic T-cells (CTL). The CTL activity is targeted toward diseased cells, not normal cells. The cytolytic activity of the Th1/killer cells is mediated by Granzyme B-Perforin mechanism and results in apoptotic death of diseased cells. Methods of producing and using these Th1/killer cells include isolating CD4+ cells from peripheral blood, activating the CD4+ T-cells to form Th1/killer cells and administering these Th1/killer cells with the cytolytic activity to a patient wherein the Th1/killer cells are allogeneic to the patient.

Abstract: The disclosure herein relates generally to immunotherapy and, more specifically, to the use of immunotherapy for treating tumors and pathogen infected tissues. The immunotherapy relates to first priming patients with allogeneic cells designed to be rejected by a Th1 mediated mechanism, then inducing in situ necrosis or apoptosis in a tumor or pathogen infected lesion. Necrosis or apoptosis can be induced 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. One or more doses of allogeneic cells (e.g., Th1 cells) are then delivered 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.

Abstract: The present invention includes methods for handling live cell compositions in non-nutritive buffer. The cells in the compositions maintain their identity and functional characteristics after being stored in non-nutrititive media up to about 72 hours. The storage method enables the cells to be manufactured at a processing facility and shipped to a point of care site. The invention also includes compositions that have been stored in non-nutritive buffer at storage temperatures while maintaining the functional characteristics.

Abstract: The present invention relates to compositions and methods that promote the induction of IL-12 in a patient. The composition includes activated allogeneic cells that are administered to a patient with a disease such as cancer. Administration of the composition skews the patient's immune response to a Th1 environment and produces detectable levels of IL-12 in the patient's plasma, without any IL-12 related toxicity.

Abstract: The present disclosure relates to an apparatus for dispensing biologic drug compositions. The apparatus includes an automated device that can store a biologic drug under the desired conditions. When authorized, the automated device can process the stored biologic drug by performing the desired processing steps to prepare the biologic drug for administration to a patient. The automated device may include a computing system to transmit patient information to a remote location and receive authorization from a remote location.

Abstract: A method of manipulating allogeneic cells for use in allogeneic cell therapy providing a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism, or “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect. The anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect. The highly activated allogeneic cells of the invention can be used to stimulate host immunity in a complete HLA mis-matched setting in a patient.

Abstract: A method of manipulating allogeneic cells for use in allogeneic cell therapy protocols is described. The method provides a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism called the “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect. The effectiveness and widespread application of the anti-tumor GVT effect is limited by the severe toxicity of the GVH effect. In the present invention, the anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect.

Abstract: A method resulting in differentiation of T-cells for use in cell therapy includes labeling the T-cells with a first array of antibodies specific for T-cell surface antigens; applying a universal cross-linking agent to the labeled T-cells with the first array of antibodies; labeling the T-cells with a second array of antibodies specific for T-cell surface antigens; and applying a universal cross-linking agent to the labeled T-cells with the second array of antibodies.

Abstract: A method of manipulating allogeneic cells for use in allogeneic cell therapy protocols is described. The method provides a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism called the “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect. The effectiveness and widespread application of the anti-tumor GVT effect is limited by the severe toxicity of the GVH effect. In the present invention, the anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect.

Abstract: A method of manipulating allogeneic cells for use in allogeneic cell therapy protocols is described. The method provides a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism called the “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect. The effectiveness and widespread application of the anti-tumor GVT effect is limited by the severe toxicity of the GVH effect. In the present invention, the anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect.

Abstract: The present invention relates to pharmaceutical vaccine compositions comprising at least one vaccine antigen together with living immune cells. These immune cells include at least a portion of activated T-cells and act as an adjuvant. Methods for using these pharmaceutical compositions to prevent or treat diseases, such as cancer, infectious diseases and autoimmune disease are also included.

Abstract: A novel cell type has been generated that has both Th1 characteristics and cytolytic activity. These Th1/killer cells are CD4+ cells purified from peripheral blood and manipulated to have Th1 characteristics such as production of IFN-gamma combined with cytolytic activity similar to cytotoxic T-cells (CTL). The CTL activity is targeted toward diseased cells, not normal cells. The cytolytic activity of the Th1/killer cells is mediated by Granzyme B-Perforin mechanism and results in apoptotic death of diseased cells. Methods of producing and using these Th1/killer cells include isolating CD4+ cells from peripheral blood, activating the CD4+ T-cells to form Th1/killer cells and administering these Th1/killer cells with the cytolytic activity to a patient wherein the Th1/killer cells are allogeneic to the patient.

Abstract: Ex-vivo prepared T-cells are harvested from cell culture conditions and formulated in medium suitable for infusion. The formulation is made by labeling the cells with one or more agents which have reactivity for T-cell surface moieties capable of delivery activation signals upon cross-linking and mixing the labeled cells with biodegradable nanospheres or microspheres coated with a material capable of cross-linking the agents attached to the T-cell surface moieties. Alternatively, the formulation may be made by mixing a population of T-cells with biodegradable nanospheres or microspheres coated with a first material and one or more second materials. The first material binds the second material and the second material has reactivity for surface moieties on the T-cells and the interaction of the second materials with the T-cells causes the activation of the T-cells.

Abstract: T-cells are generated with enhanced immunostimulatory capabilities for use in self therapy treatment protocols, by utilizing a biodegradable device with a biodegradable support that has one or more agents that are reactive to T-cell surface moieties. The biodegradable devices are mixed with the T-cells sufficiently so that the one or more agents cross-link with the T-cells' surface moieties and deliver a signal to the T-cells to enhance immunostimulatory capabilities.