The present invention relates to a method for the preparation of autologous human primary hair follicles in 3D cultures, comprising the isolation of primary fetal follicles; isolation of the patient's hair follicle cells; isolation of skin cells of the patient's scalp; extraction of growth factors from fetal follicle cells; the fibrin gel creation that contains growth factors of fetal follicles; sandwich cultivation of patient's hair follicle cells and skin of the patients scalp on or into fibrin gel that contains growth factors of fetal follicles; separation from fibrin gel the patients primary hair follicles, which can be used to treat baldness as an autologous graft.

Structures and methods for tissue engineering include a multicellular body including a plurality of living cells. A plurality of multicellular bodies can be arranged in a pattern and allowed to fuse to form an engineered tissue. The arrangement can include filler bodies including a biocompatible material that resists migration and ingrowth of cells from the multicellular bodies and that is resistant to adherence of cells to it. Three-dimensional constructs can be assembled by printing or otherwise stacking the multicellular bodies and filler bodies such that there is direct contact between adjoining multicellular bodies, suitably along a contact area that has a substantial length. The direct contact between the multicellular bodies promotes efficient and reliable fusion. The increased contact area between adjoining multicellular bodies also promotes efficient and reliable fusion. Methods of producing multicellular bodies having characteristics that facilitate assembly of the three-dimensional constructs are also provided.

A 3D-printed in vitro model biological microenvironment in examples discussed below may have one or more of the following features: (a) a gel matrix 3D-printed scaffold, wherein the gel matrix comprises a chemical composition configured to culture a first type of live cells, (b) a target chemical disposed at one or more locations within the gel matrix, the target chemical forming a chemical depot from which a chemical gradient is created within the gel matrix, (c) a conduit disposed within the gel matrix and defining a lumen comprising a second type of live cells, wherein the conduit is configured to enable at least some of the first type of live cells to migrate through the conduit and facilitate flow of at least: some of the live cells to an outlet of the conduit, or enable introduction of at least one of other cells, Achemical mediators, or drugs into the 3D-printed microenvironment.

Provided herein are microfluidic vascularized platforms and methods of using the platforms. Further provided herein are skin model systems comprising hydrogel layers of cells.

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 relates to a microfluidic devices and methods for culturing bone marrow cells. Aspects include methods of preparing microfluidic devices and culturing bone marrow cells with the microfluidic devices. In some aspects, a method includes providing a microfluidic device having an upper chamber, a lower chamber, and a porous membrane separating the upper chamber from the lower chamber. The method further includes seeding walls of the lower chamber and a bottom surface of the membrane with endothelial cells. The method further includes providing a matrix within the upper chamber. The matrix includes fibrin gel and bone marrow cells. The method further includes filling or perfusing the upper chamber with a media.

Certain populations of small cells present in adult human tissue can undergo activation/development to form human pluripotent stem cell populations. These small cells are generally less than six micrometers in diameter and are CD49f-positive, and are referred to herein as human early stage precursors or CD49f.sup.+ cells. Accordingly, provided are cell populations and compositions with enriched CD49f.sup.+ cells from adult human tissue samples and methods and compositions for promoting activation/development of these CD49f.sup.+ cells. Upon differentiation, the activated stem cells can be used for various therapeutic purposes.

This document provides methods and materials for performing retinal pigment epithelium transplantation. For example, methods and materials for using fibrin supports for retinal pigment epithelium transplantation are provided.

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

The invention relates to a matrix in ball form comprising cross-linked fibrinogen, the matrix being free from fibrin, as well as to a method for preparing such a matrix, comprising the following steps: (a) providing an initial composition comprising fibrinogen and a platelet factor; (b) injecting said initial composition into an oil heated to a temperature of 50 C. to 80 C. so as to form an emulsion; (c) mixing the emulsion thus obtained at a temperature of 50 C. to 80 C. until a matrix in ball form is obtained; and (d) isolating the matrix thus obtained. The matrix is used as a cell carrier.