Provided is a novel structure containing mesenchymal stem cells that can be used in various applications. A hydrogel fiber (10) comprises a hydrogel (14) that contains mesenchymal stem cells.

The present invention features a neural organoid that recapitulates in vitro most characteristics of the brain (e.g., human), and methods of using this neural organoid to study disease and to identify therapeutic agents for the treatment of neurological diseases and disorders.

The present invention disclosed a process to coat the surface of flexible polymeric implant with biocompatible polymer such that the coating does not crack when the implant is subjected to mechanical forces such as tension, torsion or bending while retaining the inherent properties of the coated polymer.

Compositions and methods of transplanting cells by grafting strategies into solid organs (especially internal organs) are provided. These methods and compositions can be used to repair diseased organs or to establish models of disease states in experimental hosts. The method involves attachment onto the surface of a tissue or organ, a patch graft, a “bandaid-like” covering, containing epithelial cells with supporting early lineage stage mesenchymal cells. The cells are incorporated into soft gel-forming biomaterials prepared under serum-free, defined conditions comprised of nutrients, lipids, vitamins, and regulatory signals that collectively support stemness of the donor cells. The graft is covered with a biodegradable, biocompatible, bioresorbable backing used to affix the graft to the target site. The cells in the graft migrate into and throughout the tissue such that within a couple of weeks they are uniformly dispersed within the recipient (host) tissue. The mechanisms by which engraftment and integration of donor cells into the organ or tissue involve multiple membrane-associated and secreted forms of MMPs.

The present disclosure relates to bio-printed kidney tissue and methods of manufacturing the same. The bio-printed tissue and methods may be used in a variety of applications such as regenerative medicine.

The invention relates to a stent for placement at an aortic annulus that is expandable from an undeployed state to a deployed state comprising a stent frame having rows of cells with a proximal section and a distal section at a longitudinal axis of the stent, the stent frame being formed by a plurality of arms, the arms being connected to one another at connection points, and wherein the plurality of arms forms a plurality of diamond-shaped stent cells, in particular the rows of cells, formed of vertices at said connection points between the arms, a dry valve made out bovine pericardium arranged at least at the distal section of the stent with the dry bovine pericardium being configured to be rehydrated with a solution, a skirt surrounding the dry valve and comprising at least one of bovine pericardium and polyester, and one or more eyelets arranged at a distal end of some of the arms, with the eyelets being configured to fix the valve to the stent frame.

Provided is a method for construction of bone substitutes efficient in the repair of large bone defects. The method for constructing such medical products includes three-dimensional printing of a bioresorbable scaffold and its activation by gene constructions. Produced medicinal products may serve as an efficient alternative to bone autografts.

Compositions and methods of transplanting cells by grafting strategies into solid organs (especially internal organs) are provided. These methods and compositions can be used to repair diseased organs or to establish models of disease states in experimental hosts. The method involves attachment onto the surface of a tissue or organ, a patch graft, a “bandaid-like” covering, containing epithelial cells with supporting early lineage stage mesenchymal cells. The cells are incorporated into soft gel-forming biomaterials prepared under serum-free, defined conditions comprised of nutrients, lipids, vitamins, and regulatory signals that collectively support stemness of the donor cells. The graft is covered with a biodegradable, biocompatible, bioresorbable backing used to affix the graft to the target site. The cells in the graft migrate into and throughout the tissue such that within a couple of weeks they are uniformly dispersed within the recipient (host) tissue. The mechanisms by which engraftment and integration of donor cells into the organ or tissue involve multiple membrane-associated and secreted forms of MMPs.

Materials and methods are provided to direct the formation of new lymphatics and to reconnect the disrupted lymphatic network. These materials and methods enable to improve survival of lymph nodes and lymph node fragments and their integration into a lymphatic network, following lymph node and lymph node fragments transplantation. The treatment or prevention of lymphedema is also addressed. In certain embodiments, a bundle of fibers or fibrils presented in the composition is effective to stimulate and direct the formation of new lymphatic and blood vessels. The bundle of fibers or fibrils presented in the composition is effective to promote survival of the lymph node or lymph node fragments and integration of the lymph node or lymph node fragments into a lymphatic network in the mammalian subject, at the site of transfer or transplantation.

The present invention provides, in some embodiments, multi-layer silk compositions including a first layer comprising silk fibroin and keratinocytes, a second layer comprising silk fibroin and fibroblasts, a third layer comprising silk fibroin and adipocytes, and a plurality of nervous system cells, wherein at least some of the plurality of nervous system cells span at least two layers, and methods of making and using the same. In some embodiments, provided methods and compositions further include immune cells and/or endothelial cells.