Described herein are methods for selecting lymphocytes for adoptive cell therapy based on P-glycoprotein expression and compositions comprising same.

The present invention provides improved and/or shortened methods for expanding TILs and producing therapeutic populations of TILs, including novel methods for expanding TIL populations in a closed system that lead to improved efficacy, improved phenotype, and increased metabolic health of the TILs in a shorter time period, while allowing for reduced microbial contamination as well as decreased costs. The methods may comprise gene-editing at least a portion of the TILs to enhance their therapeutic efficacy. Such TILs find use in therapeutic treatment regimens.

The invention provides a microfluidic device comprising at least one cell culture chamber, the at least one cell culture chamber being connected to at least two openings, the device being configured to supply at least one physiologically active substance from at least one of the openings to the at least one cell culture chamber in such a manner as to form a concentration gradient or concentration gradients in the at least one chamber when cells and a hydrogel are introduced into the at least one cell culture chamber to culture the cells in a 3D-gel medium.

The disclosure provides a human umbilical cord mesenchymal stem cell sheet comprising one or more layers of confluent human umbilical cord mesenchymal stem cells (hUC-MSCs). The disclosure also provides method for producing hUC-MSC sheets comprising culturing hUC-MSCs in culture solution on a temperature-responsive polymer which has been coated onto a substrate surface of a cell culture support, wherein the temperature-responsive polymer has a lower critical solution temperature in water of 0-80° C.; adjusting the temperature of the culture solution to below the lower critical solution temperature, whereby the substrate surface is made hydrophilic and adhesion of the cell sheet to the surface is weakened; and detaching the cell sheet from the culture support.

Provided are a method for obtaining active mitochondria by freezing platelets and a use of isolated mitochondria, and more specifically, to a method for obtaining mitochondria by thawing platelets after freezing the same and a pharmaceutical composition containing the mitochondria obtained by the method as an active ingredient. The present disclosure, by providing a method for obtaining mitochondria by thawing platelets in a frozen state in a preservation solution, not only enables to obtain mitochondria in which the activity is stably maintained, but also enables to provide a commercial value for donor platelets that are discarded after refrigeration for a short period of time. Additionally, the pharmaceutical composition containing platelet-derived mitochondria obtained by the above method may be effectively used to treat various diseases caused by mitochondrial dysfunction.

The invention provides a method for culturing mammalian cells. The method provides greater control over cell o growth to achieve high product titer cell cultures.

The present invention provides improved and/or shortened methods for expanding TILs and producing therapeutic populations of TILs, including novel methods for expanding TIL populations in a closed system that lead to improved efficacy, improved phenotype, and increased metabolic health of the TILs in a shorter time period, while allowing for reduced microbial contamination as well as decreased costs. The methods may comprise gene-editing at least a portion of the TILs to enhance their therapeutic efficacy. Such TILs find use in therapeutic treatment regimens.

The present invention provides improved and/or shortened methods for expanding TILs and producing therapeutic populations of TILs, including novel methods for expanding TIL populations in a closed system that lead to improved efficacy, improved phenotype, and increased metabolic health of the TILs in a shorter time period, while allowing for reduced microbial contamination as well as decreased costs. The methods may comprise gene-editing at least a portion of the TILs to enhance their therapeutic efficacy. Such TILs find use in therapeutic treatment regimens.

A bioactive suspension derived from freshly disaggregated tissue is provided, as well as related methods of formulation and use. The bioactive suspension may comprise a cell-free supernate derived from epidermal and dermal tissue that has been enzymatically and mechanically disaggregated, then separated, and which may contain tissue regeneration factors known to speed healing. The bioactive suspension may further comprise genetically-modified treatment cells, wild type cells, or both, and may be combined with one or more scaffolding elements to form a bioactive suspension combination product suitable for treatment of a cutaneous defect. Synthetic bioactive suspensions and bioactive suspension combination products are also provided.

A bioactive suspension derived from freshly disaggregated tissue is provided, as well as related methods of formulation and use. The bioactive suspension may comprise a cell-free supernate derived from epidermal and dermal tissue that has been enzymatically and mechanically disaggregated, then separated, and which may contain tissue regeneration factors known to speed healing. The bioactive suspension may further comprise genetically-modified treatment cells, wild type cells, or both, and may be combined with one or more scaffolding elements to form a bioactive suspension combination product suitable for treatment of a cutaneous defect. Synthetic bioactive suspensions and bioactive suspension combination products are also provided.