The invention provides the use of mesenchymal stem cells for preparing drugs/medicines for the treatment of non-healing burn wounds. The inventor found that the mesenchymal stem cells of the present application are used to treat burn wounds and have significant curative effects. They can effectively promote the repair of hard-to-heal burn wounds, increase the healing rate of hard-to-heal burn wounds, and shorten wound healing time, with non-toxic side effects, easy absorption and other advantages. Therefore, the mesenchymal stem cells and the composition containing them can be used to prepare drugs/medicines for treating non-healing burn wounds.

The invention provides the use of mesenchymal stem cells for preparing drugs/medicines for the treatment of non-healing burn wounds. The inventor found that the mesenchymal stem cells of the present application are used to treat burn wounds and have significant curative effects. They can effectively promote the repair of hard-to-heal burn wounds, increase the healing rate of hard-to-heal burn wounds, and shorten wound healing time, with non-toxic side effects, easy absorption and other advantages. Therefore, the mesenchymal stem cells and the composition containing them can be used to prepare drugs/medicines for treating non-healing burn wounds.

A composition, for inducing chondrocyte differentiation or regenerating cartilage tissue or both, includes exosomes derived from stem cells differentiating into chondrocytes.

A composition, for inducing chondrocyte differentiation or regenerating cartilage tissue or both, includes exosomes derived from stem cells differentiating into chondrocytes.

Provided are cells containing exogenous antigen and uses thereof.

Provided are cells containing exogenous antigen and uses thereof.

In some aspects, fusosome compositions and methods are described herein that comprise membrane enclosed preparations, comprising a fusogen. In some embodiments, the fusosome can the target cell, thereby delivering complex biologic agents to the target cell cytoplasm.

Embodiments of the present disclosure encompass systems and methods for in-situ/in vivo, bottom-up tissue generation for wound repair, repair of tissue defects, and the like. Embodiments of the systems of the present disclosure include modular scaffolds seeded with cells (modular tissue forming units (MTFUs)) for packing a tissue defect, such that these MTFUs are able to fill the wound bed with cells of one or more needed tissue types supported by the modular scaffolding particles.

Embodiments of the present disclosure encompass systems and methods for in-situ/in vivo, bottom-up tissue generation for wound repair, repair of tissue defects, and the like. Embodiments of the systems of the present disclosure include modular scaffolds seeded with cells (modular tissue forming units (MTFUs)) for packing a tissue defect, such that these MTFUs are able to fill the wound bed with cells of one or more needed tissue types supported by the modular scaffolding particles.

Embodiments of the disclosure encompass methods and compositions for producing engineered mesenchymal stem/stromal cells (MSCs). The disclosure concerns large-scale processes for producing MSCs that are engineered to have disruption of expression of one or more genes using CRISPR and also express at least one heterologous antigen receptor. Specific embodiments include particular parameters for the process.