The present disclosure features adhesive compositions and methods of use thereof related to the medical, veterinary, and dental fields.

The present disclosure provides tissue products produced from adipose tissues, as well as methods for producing such tissue products. The tissue products can include acellular tissue matrices for treatment of a breast.

This document provides methods and materials involved in reducing venous neointimal hyperplasia (VNH) of an arteriovenous fistula (AVF) or graft. For example, methods and materials for using stem cells (e.g., mesenchymal stem cells), extracellular matrix material, or a combination of stem cells and extracellular matrix material to reduce VNH of AVFs or grafts are provided.

Provided herein are methods of producing a distinct bilayer culture of retinal epithelial cells (RPE) with photoreceptor cells and/or photoreceptor precursor cells (PR/PRP). Further provided herein is a therapy comprising transplantation of the RPE and PR/PRP bilayer as well as methods for testing candidate drugs using the bilayer.

The present disclosure relates to tissue engineering, and more particularly to a method for treating or repairing rotator cuff or other tendon tears or damage using scaffold-free 3-dimensional engineered tendon constructs.

An inducer is directed to the induction of in situ regeneration in regenerative medicine. The inducer including an extracellular matrix and/or a bone morphogenetic protein, can induce the regeneration of bone and soft tissues surrounding the bone such as muscle, blood vessel and skin at the residual tissues where trauma occurs. The amount of regenerated tissue is associated with the dose of the implanted inducer.

An inducer is directed to the induction of in situ regeneration in regenerative medicine. The inducer including an extracellular matrix and/or a bone morphogenetic protein, can induce the regeneration of bone and soft tissues surrounding the bone such as muscle, blood vessel and skin at the residual tissues where trauma occurs. The amount of regenerated tissue is associated with the dose of the implanted inducer.

A cell transplanting kit includes a transplant including a cell group and a cell transplanting device. The cell transplanting device includes a needle-shaped portion that extends in a shape of a tube, and an aspiration portion configured to aspirate an interior of the needle-shaped portion. The needle-shaped portion is configured to attract the transplant by aspiration by the aspiration portion and take the transplant into the interior. The aspiration portion is configured to create an aspiration pressure in a range of −100 kPa to −0.1 kPa. The transplant includes a protection portion in a form of a gel covering at least a part of the cell group. The transplant has an outer diameter that is greater than or equal to a minimum value of the inner diameter of the needle-shaped portion. The protection portion has a jelly strength of greater than or equal to 100 g.

Provided is a cardiovascular implant based on in-situ regulation of immune response and a method for making the same, belonging to the technical field of biomedicine. The cardiovascular implant includes a cardiovascular implant body and H4000-CD25/dcas9 sustained-release nanoparticles modified on the cardiovascular implant body; the H4000-CD25/dcas9 sustained-release nanoparticles include an H4000 plasmid nanocarrier (Engreen), an anti-CD25 antibody, and a dcas9 plasmid sequence; a method for preparing the cardiovascular implant includes: constructing a cardiovascular implant body, preparing an H4000-CD25 nanotransfection vector, preparing H4000-CD25/dcas9 sustained-release nanoparticles, and conjugating the H4000-CD25/dcas9 sustained-release nanoparticles on the cardiovascular implant body. The present disclosure aims to construct a cardiovascular implant modified with the H4000-CD25/dcas9 sustained-release nanoparticles, which may induce nerve fiber ingrowth into engineered blood vessels; with the regulation ability of Treg cells on immune response, antithrombotic function of the cardiovascular implant is improved and in-situ regeneration of the cardiovascular implant is promoted.

The present disclosure includes systems, methods, kits, and individual tools (e.g., trial sizers and delivery devices) for medical procedures involving a soft-tissue allograft for the correction of skeletal impairments (e.g., misalignments, arthritis, etc.).