The present disclosure provides methods for forming stable three-dimensional vascular structures, such as blood vessels and uses thereof. More specifically, the present disclosure provides methods for culturing differentiated endothelial cells that include an exogenous nucleic acid encoding ETV2 transcription factor on a matrix under conditions that express exogenous ETV2 protein in the endothelial cell to form stable three-dimensional artificial blood vessels without the use of a scaffold, pericytes or perfusion. The present disclosure also provides stable three-dimensional blood vessels that are capable of autonomously forming a functional three-dimensional vascular network, and uses thereof. In addition, the present disclosure includes methods for vascularizing an organoid and a decellularized organ by culturing the organoid or decellularized organ with endothelial cells that include an exogenous nucleic acid encoding ETV2 transcription factor under conditions that express exogenous ETV2 protein in the endothelial cell to vascularize the organoid or decellularized organ.

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.

Described herein are new methods for making lung bud organoids (LBOs) that have the capacity of developing into branching airways and alveolar structures that a least partially recapitulate human lung development from mammalian, preferably human, pluripotent stem cells including embryonic stem cells (ESCs) and induced pluripotent stem cells (IPSC), either by culturing branched LBO in a 3D matrix or by transplanting the LBO under the kidney capsule of immune deficient mice. Branched LBOs contain pulmonary endoderm and mesoderm compatible with pulmonary mesenchyme, and undergo branching morphogenesis. Also described are LBOs harboring certain mutations that induce a fibrotic phenotype, and methods of making same. The mutated (B)LBOs can be used for screening agents that may treat pulmonary fibrosis.

A biologic stent or conduit made from an umbilical cord has a tissue body structure having a fluid passageway configured to be open to pass bodily fluids from a first end through a second end. The tissue body structure has an internal surface defining a boundary interior wall of the open fluid passageway and an external surface defining an exterior wall of the tissue body structure. The tissue body structure is made semi-rigid or rigid to maintain the stent or conduit open during the implantation and securing of the tissue body structure into the vessel, duct, or bowel. After a predetermined time sufficient to suture or otherwise fix the ends of the stent or conduit, the tissue body structure softens to a conformable stent inside the vessel duct, or bowel being repaired or reinforced.

Provided herein are inks including decellularized extracellular matrix (dECM) particles and scaffolds made from the inks. Also provided are methods of making the scaffolds and applications for the scaffolds. In an embodiment, a porous scaffold comprises dECM particles and an elastomer, wherein the scaffold is planar having a thickness of about 100 ?m or greater, the scaffold comprises irregularly shaped pores having a random orientation and distribution throughout the scaffold, and the scaffold is free of crosslinking between the molecular components of the scaffold.

Various embodiments disclosed relate to drug-coated balloon catheters for treating strictures in body lumens and methods of using the same. A drug-coated balloon catheter for delivering a therapeutic agent to a target site of a body lumen stricture includes an elongated balloon having a main diameter. The balloon catheter includes a coating layer overlying an exterior surface of the balloon. The coating layer includes one or more water-soluble additives and an initial drug load of a therapeutic agent.

Various embodiments disclosed relate to drug-coated balloon catheters for treating strictures in body lumens and methods of using the same. A drug-coated balloon catheter for delivering a therapeutic agent to a target site of a body lumen stricture includes an elongated balloon having a main diameter. The balloon catheter includes a coating layer overlying an exterior surface of the balloon. The coating layer includes one or more water-soluble additives and an initial drug load of a therapeutic agent.

Intravesical devices are provided that are wholly deployable within the bladder of a patient in need of treatment and are well tolerated by the patient. The device may include an elastic body having a retention shape having (i) dimensions that provide intravesical mobility and that prevent voiding of the medical device through the urethra, and (ii) dimensions, buoyancy, or both, that exclude the medical device from entering the orifices of the ureters. The elastic body may exert a maximum acting force less than 1N when compressed to a shape with a maximum dimension in any dimension of 3 cm. The device may include a drug for controlled release within the bladder, for treatment of the bladder or a regional tissue. Methods of treatment are also provided that include selecting a patient in need of treatment in the bladder where tolerability of the treatment is a primary concern.

One or more embodiments of the present invention are directed to a medical device having a textured surface with an arithmetical mean height value (Sa) below 3.0 m and a developed interfacial area ratio (Sdr) above 1.0 and a density of peaks (Spd) above 110.sup.6 peaks/mm.sup.2; a process of preparing such a medical device using a microstructured template; and a method of treating a mammal with such a medical device.

The present disclosure provides methods for forming stable three-dimensional vascular structures, such as blood vessels and uses thereof. More specifically, the present disclosure provides methods for culturing differentiated endothelial cells that include an exogenous nucleic acid encoding ETV2 transcription factor on a matrix under conditions that express exogenous ETV2 protein in the endothelial cell to form stable three-dimensional artificial blood vessels without the use of a scaffold, pericytes or perfusion. The present disclosure also provides stable three-dimensional blood vessels that are capable of autonomously forming a functional three-dimensional vascular network, and uses thereof. In addition, the present disclosure includes methods for vascularizing an organoid and a decellularized organ by culturing the organoid or decellularized organ with endothelial cells that include an exogenous nucleic acid encoding ETV2 transcription factor under conditions that express exogenous ETV2 protein in the endothelial cell to vascularize the organoid or decellularized organ.