The present invention provides a process for generation of genetically modified T cells, T cell subsets and/or T cell progenitors comprising the steps: a) providing a cell sample comprising T cells, T cell subsets and/or T cell progenitors b) preparation of the cell sample by centrifugation c) magnetic separation of the T cells, T cell subsets and/or T cell progenitors d) activation of the enriched T cells, T cell subsets and/or T cell progenitors using modulatory agents e) genetic modification of the T cells, T cell subsets and/or T cell progenitors f) expansion of the genetically modified T cells, T cell subsets and/or T cell progenitors in a cultivation chamber g) washing of the cultured T cells, T cell subsets and/or T cell progenitors characterized in that all steps are performed in a closed and sterile cell culture system.

A filter for filtering nucleated cells that includes a body containing at least either a metal or a metal oxide as its main component; and plural through holes, each of which have a shape other than a square shape, formed therein. A longitudinal diameter of an inscribed ellipse within each of the through holes is smaller than a size of a nucleus of each of the nucleated cells to be filtered. The inscribed ellipse of the through hole is an ellipse that abuts all sides that define an opening of the through hole.

Provided herein are kit for providing a gamma sterilized aqueous dextran solution that increase the efficiency of blood separation by allowing the dextran solution to be sterilized by exposure to gamma radiation while maintaining sufficient molecular weight to act as a red blood cell aggregate. Also provided are methods of use.

The disclosure relates to methods of preparation of fetal nucleated red blood cells (NRBCs) from biological samples for diagnostic testing.

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. Depletion of CD8+ T cells from the donor lymphocyte infusion reduces the risk of sustained engraftment and graft-versus-host disease. Removal of regulatory T cells from the infused population may augment the ability of non-regulatory T cells to provide help for endogenous effectors of anti-tumor immunity. Allogeneic T cell therapy is typically given in the context of allogeneic stem cell transplantation, in which the patient receives highly immunosuppressive conditioning followed by an infusion of a stem cell graft containing unselected populations of mature T cells. In the treatment described here, the graft is engineered to minimize the possibility of sustained donor cell engraftment, and the anti-tumor effector T cells derive from the host.

Methods for separating cells from a sample (e.g., separating fetal red blood cells from maternal blood) are described. The method begins with the introduction of a sample including cells into one or more microfluidic channels. In one embodiment, the device includes at least two processing steps. For example, a mixture of cells is introduced into a microfluidic channel that selectively allows the passage of a desired type of cell, and the population of cells enriched in the desired type is then introduced into a second microfluidic channel that allows the passage of the desired cell to produce a population of cells further enriched in the desired type. The selection of cells is based on a property of the cells in the mixture, for example, size, shape, deformability, surface characteristics (e.g., cell surface receptors or antigens and membrane permeability), or intracellular properties (e.g., expression of a particular enzyme).

The present disclosure provides distinct therapeutic populations of cells that form a pharmaceutical composition useful in hematopoietic stem/progenitor cell transplant. For example, the present disclosure provides a therapeutic population of cells, comprising an enriched population of hematopoietic stem/progenitor cells, memory T cells, regulatory T cells, and wherein the population of cells is depleted of na?ve conventional ??-T cells. The present disclosure further provides methods of treatment using the therapeutic population of cells. In other embodiments, the present disclosure provides methods of producing a therapeutic population of cells.

The present invention provides a sufficiently effective medicine for treatment and/or prevention of ischemic diseases, without performing isolation of therapeutic cells or removal of deleterious cells from blood cells/hemocytes. The blood cells and/or the hemocytes are subjected to the action of a saccharide. The saccharide is a monosaccharide, a disaccharide, a trisaccharide, a polysaccharides, or a copolymer containing a monosaccharide, a disaccharide, or a trisaccharide as a component. The saccharide is a copolymer of sucrose and epichlorohydrin.

The technology relates in part to methods for inducing partial apoptosis of cells that express an inducible caspase polypeptide. The technology further relates in part to methods for inducing partial apoptosis of cells that express an inducible modified caspase polypeptide, having a modified dose response curve to the multimeric ligand inducer. The technology also relates in part to methods for cell therapy using cells that express the inducible caspase polypeptide or the inducible modified caspase polypeptide, where the proportion of caspase polypeptide-expressing cells eliminated by apoptosis is related to the administered amount of the multimeric ligand inducer.

Aspects of the present disclosure include methods for separating components having different densities from a biological sample droplet. Methods according to certain embodiments include contacting a surface of a support with a biological sample droplet that includes components of different densities; subjecting the biological sample droplet to a gravitational force to produce two or more regions in the biological sample droplet on the support surface, where each region in the biological sample droplet includes a component from the biological sample droplet having a different density; separating the biological sample droplet into two or more product droplets, wherein each product droplet includes a different region of the biological sample droplet; and collecting the one or more product droplets. Systems for practicing the subject methods are also described. Computer systems and kits are also provided.