A method of treating a subject in need of a non-syngeneic cell or tissue graft is disclosed. The method comprising: (a) transplanting into a subject a dose of T cell depleted immature hematopoietic cells, wherein the T cell depleted immature hematopoietic cells comprise less than 5×10.sup.5 CD3.sup.+ T cells per kilogram body weight of the subject, and wherein the dose comprises at least about 5×10.sup.6 CD34+ cells per kilogram body weight of the subject; and subsequently (b) administering to the subject a therapeutically effective amount of cyclophosphamide, wherein the therapeutically effective amount comprises 25-200 mg per kilogram body weight, thereby treating the subject.

The invention provides methods and compositions for administration of allogeneic lymphocytes as an exogenous source of CD4+ T cell help for endogenous, tumor-reactive CD8+ T cells.

A method for producing an engineered T cell population includes obtaining a cell population containing a monocyte and a T cell, resting the obtained cell population on a surface, adhering the monocyte to the surface, retaining a non-adherent cell population, activating the non-adherent cell population, introducing a nucleic acid into the activated non-adherent cell population to obtain a transformed T cell, and expanding the transformed T cell to obtain the engineered T cell population.

The present disclosure relates to genetically modified B cells, including memory cells, differentiated to plasmablasts or plasma cells useful for long term in vivo expression of a transgene, such as a specific antibody or other protein therapeutic. Also disclosed are methods of producing the cells and methods of treatment.

A method is disclosed for separating cells from a lung. Mechanical pressure can be used in one stage of the process to increase the yield of separated cells, including alveolar type II cells.

Systems and methods for sorting T cells are disclosed. Autofluorescence data is acquired from individual cells. An activation value is computed using one or more autofluorescence endpoints as an input. The one or more autofluorescence endpoints includes NAD(P)H shortest fluorescence lifetime amplitude component (α.sub.1).

The invention relates to a system for platelet release from a fluid comprising in particular megakaryocytic cells comprising cytoplasmic extensions.

The system allows to reproduce the pipetting process performed manually by means of a pipette, thereby permitting a continuous and automatic release of platelets.

This is performed on a large scale since the geometry of the system according to the invention allows to treat large volumes of fluid with a high flow rate (of the order of a plurality of liters per hour), thereby making it particularly suitable for use on an industrial scale.

The invention also relates to a method for platelet release from a fluid comprising in particular megakaryocytic cells comprising cytoplasmic extensions, said method being implemented by means of the abovementioned system.

There is provided an effector immune cell which expresses a cell surface receptor or receptor complex which specifically binds an antigen recognition receptor of a target immune cell; which effector immune cell is engineered such that when a synapse is formed between the effector immune cell and the target immune cell, the capacity of the effector immune cell to kill the target immune cell is greater than the capacity of the target immune cell to kill the effector immune cell. There is also provided the use of such a cell in methods for treating cancer, preventing allograft rejection and GVHD.

Provided herein are methods for the isolation of platelets, for example, isolation of platelets from umbilical cord blood. In certain embodiments, presented herein are methods for preparation of platelet rich plasma. In one aspect, provided herein are methods for isolation of platelets from blood. In certain embodiments, presented herein are methods for isolation of platelets from cord blood, e.g., human cord blood. The isolated platelets can be used for a variety of applications, including, for example, methods of wound healing, organ repair and/or regeneration, and/or tissue repair and/or regeneration, in either autologous or allogenic settings.

Provided herein are methods for selecting a population of cells expressing a target polypeptide. In some aspects, the disclosure provides methods for sorting and selecting populations of transfected host cells based on their early expression of a selectable polypeptide. In certain embodiments, the sorting is performed using fluorescence-activated cell sorting or magnetic-activated cell sorting based on the selectable polypeptide. Such selection methods can be further utilized to generate clonal populations of producer cells, e.g. for large-scale manufacturing of a target polypeptide of interest.