Devices and methods for treating defects in connective tissue are provided along with methods for making such devices. The devices can include acellular arterial tissue matrices that facilitate regrowth of the damaged tissue.

Provided are methods for preparing non-gelling, solubilized extracellular matrix (ECM) materials useful as cell growth substrates. Also provided are compositions prepared according to the methods as well as uses for the compositions. In one embodiment a device, such as a prosthesis, is provided which comprises an inorganic matrix into which the non-gelling, solubilized ECM composition is dispersed to facilitate in-growth of cells into the ECM and thus adaptation and/or attachment of the device to a patient. In another embodiment, the composition is delivered intraarticularly, intrathecally, intraoccularly, intracranially, and into pleural space.

An implantable medical instrument is made of an iron-based alloy, comprising an iron-based alloy substrate and a drug-loaded coating. The drug-loaded coating comprises a polymer and an active drug; the weight average molecular weight of the polymer is greater than or equal to 50,000 and less than or equal to 1,000,000; micro-pores having a diameter of less than or equal to 10 micrometers are formed in the drug-loaded coating; the percentage of the active drug released on the implantable medical instrument made of an iron-based alloy is greater than or equal to 4t.sup.1/21 and less than or equal to 6.9t.sup.1/2+63, wherein t (0, 28], and t represents sampling time/days.

Implantable devices comprising a scaffold, cells, and/or therapeutic molecules are provided. Uses include inhibition of pathological immunity, elaboration of therapeutic growth factors, and immune augmentation. The implantable device may contain a porous substrate structure to which therapeutic cells are adherent, which can be implanted and explanted from a patient. In another embodiment, a medical device includes a porous substrate seeded with therapeutic cells, said device comprising of an additional layer allowing free exchange of molecules without cell escape. Said medical device is seeded with thymic medullary epithelial cells or progenitors of said thymic medullary epithelial cells. In conditions where tolerance to alloreactive donor cells is desired, the thymic medullary epithelial cells or progenitors thereof are derived from recipient cells. In conditions where tolerance to alloreactive recipient cells is desired, the thymic medullary epithelial cells or progenitors thereof are derived from donor cells.

This disclosure features elongated prosthetic devices that can be used to repair, e.g., resurface or occlude, a defect of a semicircular canal, e.g., a superior semicircular canal dehiscence, as well as methods of making and using these devices. For example, the devices can be made using three-dimensional (3D) printing.

A method of delivering a cell derived factors to a subject is described, which includes implanting a matrix material into an intracutaneous location in the subject that results in increased vascularisation and subsequently efficient delivery of the required cell derived factors to the subject. The implanted matrix material can be loaded in-situ or alternatively pre-loaded and inserted into the appropriate location depending on requirements.

The present invention provides compositions for treating soft tissue injuries comprising a collagen matrix and mesenchymal stem cells adhered to the collagen matrix. Methods of making and using compositions comprising a collagen matrix and mesenchymal stem cells adhered to the collagen matrix are also provided.

The present disclosure provides methods, substrates and compositions for modifying, repairing, and/or engineering blood vessel tissue, and in particular the use of such compositions for treating a diseased blood vessel.

Devices and methods for treating defects in connective tissue are provided along with methods for making such devices. The devices can include acellular arterial tissue matrices that facilitate regrowth of the damaged tissue.

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.