Several embodiments relate to methods of repairing and/or regenerating damaged or diseased tissue comprising administering to the damaged or diseased tissues compositions comprising exosomes. In several embodiments, the exosomes comprise one or more microRNA that result in alterations in gene or protein expression, which in turn result in improved cell or tissue viability and/or function.

The present disclosure relates generally to an osteo-tissue graft capable of promoting bone tissue growth and regeneration, comprising at least one self-assemble peptide and mesenchymal stem cells (MSCs) in accordance with the present invention and a method of preparing such an osteo-tissue graft. The grafts are suitable for treatment of bone disorder or damages through tissue engineering, cellular replacement therapies as well as other applications.

A method of promoting spheroid formation, including: a preparation step of preparing a mixture obtained by mixing a cell sample with a promoter; and a culture step of culturing, inside a spheroid formation-culture vessel, the mixture obtained in the preparation step, in which the promoter is a polymer in which one or more selected from the group consisting of D-glucosamine, D-galactosamine, D-glucuronic acid, L-iduronic acid, and D-galactose are polymerized.

Microfluidic devices for modeling three-dimensional tissue structures and methods for making and using the same are described herein.

The present disclosure relates to: an artificial peritoneal tissue comprising a cellular tissue and a mesothelial cell layer that covers the surface of the cellular tissue, wherein the cellular tissue comprises a fibroblast, an extracellular matrix, and a vascular endothelial cell and/or a lymphatic endothelial cell each capable of forming a lumen; and a method for producing the artificial peritoneal tissue.

The invention is in the domain of delivery of molecules to brain cells across the blood-brain barrier. The invention relates to a novel polypeptide-based carrier that allows the efficient delivery of an effector peptide, to neuron cells across the blood-brain barrier, and to methods for the production and testing of such carrier, including a model for testing the capacity of such molecule to cross the blood-brain barrier and/or the toxicity of molecules on the blood brain barrier and/or the capacity of molecules that have crossed to target human brain cells (e/g. neurons, astrocytes and microglial cells).

The invention provides a bioreactor and methods for tissue cultivation. A bioreactor module comprises a container, a holder adapted to hold a scaffold containing an inherent vascular network, an inlet connectable to a vessel of the inherent vascular network, an inflatable device disposed within the container, and a pair of electrodes attached to opposing walls of the container, wherein the holder is removably receivable in the container and the inflatable device has a conduit extending through a wall of the container. An alternative embodiment provides an in-vitro method for tissue cultivation, comprising seeding an interior and an exterior of a vessel of an inherent vascular network of a scaffold with a first and a second cell type, respectively, and perfusing through the inherent vascular network with culture medium to facilitate compartmentalized co-cultivation of the first and the second cell type in different niches of the tissue. A further embodiment provides an in-vitro method for tissue cultivation, comprising seeding a surface of a scaffold with a predetermined cell type, and perfusing the scaffold with culture medium from an opposite surface of the scaffold through the scaffold and towards the seeded surface to create a nutrient/oxygen gradient and cause migratory diffusion induced penetration of cells towards the opposite surface.

The present invention provides methods for cellular seeding onto three-dimensional fibroblast constructs, three-dimensional fibroblast constructs seeded with muscle cells, and uses therefore.

A method of making a multi-layer patterned cell assembly is provided. A cell suspension liquid solution containing cells is loaded into a liquid-carrier chamber. The cells in the cell suspension liquid solution are let to settle down to the bottom of the chamber. Once the cells in the cell suspension liquid solution have gravitationally settled down to the bottom of the chamber, a hydrodynamic drag force is applied by using a vibration generator with a frequency and acceleration to the cells at the bottom of the chamber. The frequency and acceleration are designed to drag the settled cells into a three-dimensional pattern to form a multi-layer three-dimensional patterned cell assembly. The formed multi-layer three- dimensional patterned cell assembly can be transferred from the liquid-carrier chamber to an incubator to form a tissue culture. The bioengineered construct can be implanted for tissue engineering or other medical applications.

The invention provides a method to prepare a graft comprising a recellularized extracellular matrix of a mammalian liver, liver lobe or portion thereof, and a method of using the recellularized extracellular matrix of a mammalian liver, liver lobe or portion thereof.