Described herein are compositions and techniques related to generation and therapeutic application of cardiosphere-derived cells (CDCs) and CDC-derived exosomes. These cells and their secreted vesicles contain a unique milieu of biological factors, including cytokines, growth factors, transcription factors, nucleic acids including non-coding nucleic acids such as microRNAs, that serve to initiate and promote many therapeutic effects. Exosomes and their “cargo” contents, such as microRNAs can favorably modulate apoptosis, inflammation and fibrosis in the injured heart. Thus, CDC-derived exosomes represent a novel “cell-free” therapeutic candidate for tissue repair.

Described herein are compositions and techniques related to generation and therapeutic application of cardiosphere-derived cells (CDCs) and CDC-derived exosomes. These cells and their secreted vesicles contain a unique milieu of biological factors, including cytokines, growth factors, transcription factors, nucleic acids including non-coding nucleic acids such as microRNAs, that serve to initiate and promote many therapeutic effects. Exosomes and their “cargo” contents, such as microRNAs can favorably modulate apoptosis, inflammation and fibrosis in the injured heart. Thus, CDC-derived exosomes represent a novel “cell-free” therapeutic candidate for tissue repair.

Methods for preparing capsules, such as micro- and/or nanocapsules from all-aqueous emulsions are described herein. The method includes mixing, combining, or contacting a first electrically charged phase containing a first solute with at least an optionally charged second phase containing a second solute. The solutes are incompatible with each other. The electrostatic forces between the two solutions induce the formation of droplets of a dispersed phase in a continuous phase. The droplets are then solidified to form the capsules.

Methods for preparing capsules, such as micro- and/or nanocapsules from all-aqueous emulsions are described herein. The method includes mixing, combining, or contacting a first electrically charged phase containing a first solute with at least an optionally charged second phase containing a second solute. The solutes are incompatible with each other. The electrostatic forces between the two solutions induce the formation of droplets of a dispersed phase in a continuous phase. The droplets are then solidified to form the capsules.

The invention relates to method for cultivating stem cells in vitro, comprising the following steps: providing a sample comprising stem cells and cultivating the stem cells by subjecting the sample to a treatment for a first period of time. The treatment is carried out under hypothermic conditions having a defined temperature and a defined atmosphere, wherein the temperature does not exceed 15° C. and the atmosphere has an oxygen content not exceeding 21% (v/v). Thereby, the first period of time is 4 days to 4 weeks.

The invention relates to method for cultivating stem cells in vitro, comprising the following steps: providing a sample comprising stem cells and cultivating the stem cells by subjecting the sample to a treatment for a first period of time. The treatment is carried out under hypothermic conditions having a defined temperature and a defined atmosphere, wherein the temperature does not exceed 15° C. and the atmosphere has an oxygen content not exceeding 21% (v/v). Thereby, the first period of time is 4 days to 4 weeks.

A sheet-shaped cell culture is disclosed that includes myocardial cells derived from pluripotent stem cells and has excellent functional properties. A sheet-shaped cell culture obtained by culturing a cell population that includes myocardial cells derived from pluripotent stem cells, wherein the proportion of the number of the myocardial cells derived from pluripotent stem cells to the total number of cells in the cell population is 50% to 70%; a method of producing the sheet-shaped cell culture; a composition including the sheet-shaped cell culture; and a method of treating a disease using the sheet-shaped cell culture or the composition.

A sheet-shaped cell culture is disclosed that includes myocardial cells derived from pluripotent stem cells and has excellent functional properties. A sheet-shaped cell culture obtained by culturing a cell population that includes myocardial cells derived from pluripotent stem cells, wherein the proportion of the number of the myocardial cells derived from pluripotent stem cells to the total number of cells in the cell population is 50% to 70%; a method of producing the sheet-shaped cell culture; a composition including the sheet-shaped cell culture; and a method of treating a disease using the sheet-shaped cell culture or the composition.

The present invention relates to new plasma or new platelet-rich plasma preparations, new cell dissociation methods, new cell associations or compositions, a method of preparation thereof, a use thereof, devices for the preparation thereof and preparations containing such a platelet-rich plasma preparation and cell associations or compositions. Specifically, the invention provides plasma or platelet-rich plasma alone or in cell composition preparations for use in tissue regeneration and bone regeneration and pain reduction.

The present invention relates to new plasma or new platelet-rich plasma preparations, new cell dissociation methods, new cell associations or compositions, a method of preparation thereof, a use thereof, devices for the preparation thereof and preparations containing such a platelet-rich plasma preparation and cell associations or compositions. Specifically, the invention provides plasma or platelet-rich plasma alone or in cell composition preparations for use in tissue regeneration and bone regeneration and pain reduction.