Hydrodynamic methods for conformally coating non-uniform size cells and cell clusters for implantation, thus preventing immune rejection or inflammation or autoimmune destruction while preserving cell functionality. A method for conformally coating cells and cell clusters with hydrogels that are biocompatible, mechanically and chemically stable and porous, with an appropriate pore cut-off size. The methods of the invention are advantageously reproducible and result in a relatively high yield of coated versus non-coated cell clusters, without compromising cell functionality. Conformal coating devices configured to perform the methods of the invention, methods of optimally utilizing said devices and purifying the coated islets, and coated biomaterials made by said methods.

Described herein are compositions composed of micronized placental components and pharmaceutical compositions thereof. The compositions have numerous medical applications. Methods for making and using the micronized compositions are also described herein.

The disclosure provides bone graft materials, methods for their use and manufacture. Exemplary bone graft materials comprise combining a radiopaque component with a cancellous bone component to produce a bone graft material, wherein the cancellous bone component comprises native osteoreparative cells. Methods for treating a subject with the bone graft material are also provided.

A problem to be solved by the present invention is to provide a fibrosis inhibitor that solves the problem of inhibiting fibrosis of an organ or tissue surface, and especially of inhibiting fibrosis of an epicardial surface. Furthermore, by inhibiting fibrosis, the present invention prevents or reduces subsequent development of adhesions to avoid organ or tissue damage during re-operation. Provided is a fibrosis inhibitor for inhibiting fibrosis of a tissue by fixing a biocompatible polymer to a tissue where it is desirable to inhibit fibrosis.

Osteoinductive compositions and implants having increased biological activities, and methods for their production, are provided. The biological activities that may be increased include, but are not limited to, bone forming; bone healing; osteoinductive activity, osteogenic activity, chondrogenic activity, wound healing activity, neurogenic activity, contraction-inducing activity, mitosis-inducing activity, differentiation-inducing activity, chemotactic activity, angiogenic or vasculogenic activity, and exocytosis or endocytosis-inducing activity. In one embodiment, a method for producing an osteoinductive composition comprises providing partially demineralized bone, treating the partially demineralized bone to disrupt the collagen structure of the bone. In another embodiment, an implantable osteoinductive and osteoconductive composition comprises partially demineralized bone, wherein the collagen structure of the bone has been disrupted, and, optionally, a tissue-derived extract.

Encasement structures and methods of customizing patient drug delivery profiles using an encasement structure are described herein. Encasement structures can be configured to receive an implantable medical device and physicians can implant the medical devices within the encasement structures. Encasement structures can include at least one sheet of a bioscaffold material and one or more depots. depots can be configured to release an active agent, such as an antibiotic, to the medical device within the encasement structure and/or the surrounding tissue. The depots can be insertable into or integrated with the at least one sheet of bioscaffold material.

Methods of using human airway stem cells in lung epithelial engineering, optionally wherein the cells are contacted with a gamma secretase inhibitor, bioartificial airway organs produced thereby, and the use thereof, e.g., for transplantation. Also methods of treating a bio-artificial matrix with Tenascin-C and/or fibrillin 2.

A method of preparing a tissue swatch comprising one or more desired thicknesses for use in the manufacture of a bioprosthetic device, said method comprising sectioning a sheet of frozen tissue to produce a tissue swatch of said one or more desired thicknesses.

A method of differentiating cells into CK19-positive cells capable of producing hair follicle-like and hair structure-like can include: providing a tissue scaffold; seeding cells into the scaffold, the cells being capable of differentiation; incubating the scaffold having the cells in a cell growth media; and incubating the scaffold having the cells in an osteogenic differentiation medium sufficient for CK19-positive cells to be generated in the scaffold. The tissue scaffold can be a decellularized Whartons' jelly matrix. The cell growth media excludes osteogenic differentiation components: dexamethasone, β-glycerophosphate, 1α,25-hydroxyvitamin D3, and ascorbic acid 2-phosphate. The osteogenic differentiation medium includes the osteogenic differentiation components. The cells can be mesenchymal cells, such as WJMSCs.

Biomimetic grafts or implants coated with an osteogenic extracellular matrix and methods for production and use are described.