The present invention relates to the field of implants for the formation/regeneration of lymph nodes. In particular, the present invention relates to an implant comprising a biodegradable scaffold and lymph node fragments immobilized therein and/or thereon, to a method of manufacturing such an implant and to uses of such an implant.

Described are methods of enhancing development of renal organoids, methods of using the same, and kits.

The present invention concerns a method for obtaining an implantable cartilage gel for tissue repair of hyaline cartilage, comprising particles of chitosan hydrogel and cells that are capable of forming hyaline cartilage, said method comprising a step for amplification of primary cells in a three-dimensional structure comprising particles of physical hydrogel of chitosan or a chitosan derivative, then a step for re-differentiation and induction of the synthesis of extracellular matrix by said amplified cells, in the same three-dimensional structure, wherein said cells are primary articular chondrocytes and/or mesenchymal stem cells differentiated into chondrocytes. The present invention also concerns the cartilage gel obtained thereby, and its various uses for cartilage repair following a traumatic lesion or an osteoarticular disease such as osteoarthritis. The invention also concerns a three-dimensional matrix comprising particles of physical hydrogel of chitosan or of chitosan derivative, optionally supplemented with an anionic molecule such as hyaluronic acid or a derivative of hyaluronic acid or a complex of hyaluronic acid.

The present disclosure provides a method of producing uniformly sized organoids/multicellular spheroids using a microfluidic device having an array of microwells. The method involves several successive steps. First, a microfluidic device containing parallel rows of microwells that are connected with a supplying channel is filled with a wetting agent. The wetting agent is a liquid that is immiscible in water. For example, the wetting agent may be an organic liquid such as oil. In the next step, the agent in the supplying channel and the microwells is replaced with a suspension of cells in an aqueous solution that contains a precursor for a hydrogel. Next, the aqueous phase in the supplying channel is replaced with the agent, which leads to the formation of an array of droplets of cell suspension in the hydrogel precursor solution, which were compartmentalized in the wells. The droplets are then transformed into cell-laden hydrogels. Subsequently, the agent in the supplying channel is replaced with the cell culture medium continuously flowing through the microfluidic device and the cells within the hydrogels are transformed into multicellular spheroids.

Provided herein are novel methods and compositions utilizing adipose tissue-derived stromal stem cells for treating fistulae.

Disclosed is a three-dimensional tissue culture, comprising chondrocytes in a biocompatible artificial matrix, having at least the following layers: a first layer located at or close to a surface of the matrix, wherein chondrocytes have a non-spherical shape and are arranged essentially in parallel to the surface along their longest dimension; and a second layer at least partially covered by the first layer wherein the mean sphericity of the chondrocytes of the second layer is higher than the mean sphericity of the chondrocytes of the first layer; and preferably a third layer at least partially covered by the second layer, wherein chondrocytes are arranged into columns extending into the matrix, wherein each column has at least two chondrocytes. Such a tissue culture may for instance be used as artificial cartilage in surgery. Also disclosed is a method to produce such a three-dimensional culture.

Described are methods for producing multi-layered tubular tissue structures, tissue structures produced by the methods, and their use.

There is provided a tissue scaffold and a method for making a tissue scaffold. The tissue scaffold comprises elastin and optionally fibrin and/or collagen. The elastin in the scaffold may be cross-linked. The elastin that is cross-linked preferably comprises solubilised elastin and is unfractionated.

Immunotolerant engineered human tissue constructs are provided that are suitable for implantation into subjects. In some embodiments, the immunotolerance is controllable by an inducible system. Methods of making and using the immunotolerant engineered tissue constructs are provided.

This document provides RPE cells and RPE monolayers. For example, compositions containing RPE cells or RPE monolayers as well as methods and materials for making RPE cells or RPE monolayers from, for example, stem cells (e.g., iPSCs) are provided.