The present disclosure provides patterned biomaterials having organized cords and extracellular matrix embedded in a 3D scaffold. According, the present disclosure provides compositions and applications for patterned biomaterials. Pre-patterning of these biomaterials can lead to enhanced integration of these materials into host organisms, providing a strategy for enhancing the viability of engineered tissues by promoting vascularization.

Described are compositions and methods for cartilage replacement. Also described are collagen scaffolds comprising the composition described herein.

The present disclosure provides patterned biomaterials having organized cords and extracellular matrix embedded in a 3D scaffold. According, the present disclosure provides compositions and applications for patterned biomaterials. Pre-patterning of these biomaterials can lead to enhanced integration of these materials into host organisms, providing a strategy for enhancing the viability of engineered tissues by promoting vascularization.

A system and method for printing cells in a medium. A multi-dimensional printer, stably constructed of low-mass parts, can include a computer numerically controlled system that can enable motors driving delivery systems. The motors can include encoders that can enable achieving arbitrary resolution. The motors can drive ballscrews to enable linear motion of delivery systems, and the delivery systems can enable printing of a biological material in a pre-selected pattern in a petri dish. The petri dish can accommodate a medium such as a gel, and can further accommodate a vision system that can detect actual position and deflection of the delivery system needle. The printer can accommodate multiple delivery systems and therefore multiple needles of various sizes.

The present invention relates to the preparation of a membrane for use in the repair of the middle ear including perforations and damage to the tympanic membrane. More particularly, the invention provides for compositions and methods for preparing silk fibroin biocompatible polyurethane membranes using a solvent, which have improved biodegradation, mechanical and vibroacoustic properties.

The present invention involves implants suitable for surgical implantation into subjects. In some embodiments the implants comprise a biocompatible scaffold material and blood vessels containing engineered endothelial cells—such as E4ORF1+ engineered endothelial cells or engineered endothelial cells that express certain marker molecules. The present invention provides implants, methods for preparing such implants, and methods of treatment utilizing such implants.

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.

Method of the osteoreparative processes' correction and/or bone defect restoration by means of human cell-based products (cell and/or tissue transplants) and the method of its manufacturing. The invention a creates and establishes conditions for osteoreparative processes restoration in destroyed bone tissue by osteoreparation cell sources restoration as the result of use cell technologies and bone tissue engineering methods, e.g. scaffold-guided regeneration, particularly by means of cell transplantation by injection and/or transplantation of original three-dimensional osteoreparative prevascularized graft (3D-OPG). Manufacturing of medical products and preparations of the product based on human cells (cell and/or tissue transplants) is dedicated for impaired osteoreparative processes correction and/or bone defect restoration.

The present invention refers to a process for preparing a biomaterial scaffold said method comprising, (a) providing a hydrogel comprising a fibrin network and a polysaccharide network; (b) subjecting the hydrogel of step a) to a freeze-thawing process to physically crosslink the hydrogel; and (c) subjecting the physically cross-linked hydrogel obtained after conducting the step b), to a lyophilization. The invention also relates to the biomaterial scaffold obtainable by the process as defined above, as well said biomaterial scaffold for its use to partially or completely increase, restore or replace the functional activity of a diseased or damaged oral mucosa.

In one aspect, a method includes providing support material within which the structure is fabricated, depositing, into the support material, structure material to form the fabricated structure, and removing the support material to release the fabricated structure from the support material. The provided support material is stationary at an applied stress level below a threshold stress level and flows at an applied stress level at or above the threshold stress level during fabrication of the structure. The provided support material is configured to mechanically support at least a portion of the structure and to prevent deformation of the structure during the fabrication of the structure. The deposited structure material is suspended in the support material at a location where the structure material is deposited. The structure material comprises a fluid that transitions to a solid or semi-solid state after deposition of the structure material.