A tumor vaccine, a preparation method therefor, and use of the tumor vaccine thereof. A pharmaceutical combination with a first membrane component having a membrane derived from the inner membrane of bacteria, the pharmaceutical combination further includes components derived from other organisms than the bacteria. A method for enhancing an uptake of a target antigen by an immune cell, activating an immune cell, enhancing an innate immunity and/or a specific immune response and/or preventing and/or treating a tumor. A tumor vaccine for preventing postoperative recurrence of cancer.

The invention encompasses components from microbial cells which are useful for antibody production, including peptides, polypeptides comprising these peptides, polynucleotides which encode these peptides or polypeptides, and antibodies directed to these peptides, polypeptides, or polynucleotides. The invention also encompasses to expression vectors and host cells for producing these peptides, polypeptides, polynucleotides, and antibodies. The invention further encompasses methods and compositions, especially vaccine compositions, for detecting, targeting, and inhibiting microbial cells, especially methanogen cells, using one or more of the disclosed peptides, polypeptides, polynucleotides, antibodies, expression vectors, and host cells.

Disclosed herein are novel compositions and methods for stimulation of and the production or expansion of natural killer (NK) cells. Numbers of NK cells can be increased following contact with exosomes modified with one or more stimulatory peptides. Methods and compositions for the production of exosomes, wherein the exosomes comprises stimulatory peptides are also described. Also described are methods of treating cancer using the disclosed NK-stimulating exosomes or NK cells stimulated by the disclosed methods.

Disclosed herein are novel compositions and methods for stimulation of and the production or expansion of natural killer (NK) cells. Numbers of NK cells can be increased following contact with exosomes modified with one or more stimulatory peptides. Methods and compositions for the production of exosomes, wherein the exosomes comprises stimulatory peptides are also described. Also described are methods of treating cancer using the disclosed NK-stimulating exosomes or NK cells stimulated by the disclosed methods.

Disclosed herein are novel compositions and methods for stimulation of and the production or expansion of natural killer (NK) cells. Numbers of NK cells can be increased following contact with exosomes modified with one or more stimulatory peptides. Methods and compositions for the production of exosomes, wherein the exosomes comprises stimulatory peptides are also described. Also described are methods of treating cancer using the disclosed NK-stimulating exosomes or NK cells stimulated by the disclosed methods.

Disclosed herein are novel compositions and methods for stimulation of and the production or expansion of natural killer (NK) cells. Numbers of NK cells can be increased following contact with exosomes modified with one or more stimulatory peptides. Methods and compositions for the production of exosomes, wherein the exosomes comprises stimulatory peptides are also described. Also described are methods of treating cancer using the disclosed NK-stimulating exosomes or NK cells stimulated by the disclosed methods.

Recombinant strains of avian paramyxovirus (APMV), such as Newcastle disease virus (NDV), are provided. Also provided are compositions comprising them, and methods of using them to lyse tumor cells and to treat cancer. In certain aspects, genetically-engineered viral strains that incorporate therapeutic transgenes are also provided. The recombinant viruses may be used in accordance with methods of providing enhanced oncolytic efficacy and delivering an oncolytic virus to tumors present in a patient. Also provided are methods for identifying a recombinant virus as an oncolytically-effective agent.

A method for coordinating the manufacturing of an expanded cell therapy product for a patient may include receiving a cell order request to expand the cell therapy product for the patient; generating a patient-specific identifier or cell order identifier associated with the cell order request; and initiating a process to expand the cell therapy product from at least some of a solid tumor obtained from the patient. If acceptance parameters for the expansion cell therapy product do not meet certain acceptance criteria at a second time point subsequent to a first time point in the expansion process, it is determined whether re-performing the expansion of the cell therapy product using the cell expansion technique is possible from the first time point based on the acceptance parameters at the second time point. If such re-performing the expansion is possible, patient treatment events that use the expanded cell therapy product are rescheduled.

A method for coordinating the manufacturing of an expanded cell therapy product for a patient may include receiving a cell order request to expand the cell therapy product for the patient; generating a patient-specific identifier or cell order identifier associated with the cell order request; and initiating a process to expand the cell therapy product from at least some of a solid tumor obtained from the patient. If acceptance parameters for the expansion cell therapy product do not meet certain acceptance criteria at a second time point subsequent to a first time point in the expansion process, it is determined whether re-performing the expansion of the cell therapy product using the cell expansion technique is possible from the first time point based on the acceptance parameters at the second time point. If such re-performing the expansion is possible, patient treatment events that use the expanded cell therapy product are rescheduled.

This disclosure is directed to compositions and methods for treating cancer using combination therapies of NK-92 cells with cancer drugs (e.g. thalidomide, cisplatin, and paclitaxel).