The problem of attaching a donor nerve stump to a recipient nerve for an end-to-side coaptation is solved by the use of a tissue connector. The tissue connector can have a body for receiving the donor nerve stump and one or more overflaps for attaching the tissue connector with the donor nerve stump therein to the epineurium on the side of the recipient nerve. Sutures can also be used to secure the tissue connector and nerves in place.

Described herein are methods of producing decellularized tissue hydrogels. In some aspects, the decellularized tissue hydrogels can contain one or more extracellular matrix proteins. Also described herein are methods of making the decellularized tissue hydrogels. Also described herein are methods of using the decellularized tissue hydrogels. In some aspects, the decellularized tissue hydrogels or a pre-gel solution can be administered to a subject.

Medical material production and preparation, and a preparation method of a 4D chitosan-based thermosensitive hydrogel. First, chitosan is dissolved in acetic acid solution; a chitosan-based thermosensitive hydrogel is printed by a 4D bioprinter and lyophilized after solvent extraction, to obtain lyophilized chitosan; subsequently, aqueous -sodium glycerophosphate solution is prepared with ultrapure water and -sodium glycerophosphate, and then aqueous carboxymethyl chitosan solution is prepared with ultrapure water and aqueous -sodium glycerophosphate solution are charged into and mixed well with aqueous carboxymethyl chitosan solution to prepare a mixture; finally, the lyophilized chitosan is crosslinked with the mixture to obtain the 4D chitosan-based thermosensitive hydrogel. With scientific and reliable principles thereof, the present invention solves a problem that conventional thermosensitive hydrogels have uneven pore sizes, and improves the entrapment efficiency and ability of limbal stem cells.

Disclosed a plant-derived exosome as well as a preparation method and an application thereof in preparation of drugs or scaffolds for animal tissue regeneration therapy. The preparation method includes: soaking and infiltrating any part of a natural plant with a 2-(N-morpholine) ethanesulfonic acid buffer solution; removing a supernatant; collecting a wet treated sample; refrigerating, centrifuging and extracting the sample to obtain apoplastic fluid, wherein the soaking and infiltrating method is as follows: vacuum supply is performed within 6-24 h after soaking for 2-5 times, vacuum supply time is independently 5-15 s each time, and interval time between two adjacent times of vacuum supply is independently 10 s-1 min; and centrifuging the apoplastic fluid at an ultra-high speed to obtain the plant-derived exosome, wherein ultra-high speed centrifugation conditions are as follows: centrifugal force is not lower than 100000 g, centrifugation time is 1-7 h, and a temperature is 0-4 C.

A composition includes Purified Exosome Product (PEP) and a pharmaceutically acceptable carrier that includes a surgical glue or tissue adhesive. In some embodiments, the PEP includes spherical or spheroid exosomes having a diameter no greater than 300 nm. In some embodiments, the PEP includes from 1% to 20% CD63.sup. exosomes and from 80% to 99% CD63.sup.+ exosomes. In some embodiments, the PEP includes at least 50% CD63.sup. exosomes. The composition may be applied to injured peripheral nervous tissue to promote growth of peripheral nervous tissue and/or treat the injured peripheral nervous tissue. The peripheral nervous tissue may be autologous or may be allogeneic.

The present invention relates to preparation and use of biocompatible and electrically conductive 3D hydrogels comprising nanocellulose fibrils, such as disintegrated bacterial nanocellulose, plant derived nanocellulose, tunicate derived nanocellulose, or algae derived nanocellulose, together with carbon nanotubes or graphene oxide, as a biocompatible and conductive 3D hydrogel for diagnostics and intervention to mimic or restore tissue and organ function. Biocompatible conductive 3D hydrogels described in this invention can be extruded, casted or injected. The 3D hydrogels described in this invention are cohesive 3D structures and provide electrical conductivity in wet form. 3D hydrogels described in this invention can be further crosslinked using divalent ions such as Calcium ions which improve mechanical stability. Such crosslinking can take place in an animal or human body in a physiological environment after injection into the tissue. 3D hydrogels are biocompatible and show preferable mechanical properties and electrical conductivity through printed lines (4.10.sup.1 S cm.sup.1). The 3D hydrogels prepared by this invention are suited as bioassays to screen drugs against neurodegenerative diseases such as Alzheimer's and Parkinson's, study brain function, and/or be used to link the human brain with electronic and/or communication devices. They can also be injected to replace neural tissue or stimulate guiding of neural cells. They can also be used to inject into the heart and stimulate the heart by using electrical signaling or to repair myocardial infarction.

A method of repairing nerve tissue is provided. A method of inducing neurite outgrowth in neurons also is provided.

The present invention relates to a fibrous nerve conduit for promoting nerve regeneration, comprising a channel, the channel having diameter controllable ends, the channel is adjustable to suturing to a proximal and distal end of a severed nerve, the conduit further comprises a PCL (MW: 70 KDa) with concentration of 10-15% and PLGA (MW: 50 KDa, 50:50) with concentration of 10-18%.

The present invention relates to a method for preparing of a nerve conduit using bio-printing technology and a nerve conduit prepared by the same, and it can easily prepare a nerve conduit by simulating a nerve bundle and nerve tissue, and the like, by three-dimensionally printing bio-ink comprising a neuronal regeneration material on one side of a porous polymer scaffold.

A nerve repair conduit configured to be secured on first and second portions of a selected nerve. The nerve repair conduit includes a polymeric body having a proximal end, a distal end, an exterior surface and an interior surface defining an interior lumen. In addition, the nerve conduit includes at least one drug reservoir to hold agent(s) that may facilitate nerve regeneration. The drugs diffuse from the drug reservoir(s) into the nerve repair conduit through an outlet (such as a hole or a semipermeable membrane) in proximity to the first and second portions of a selected nerve. The nerve repair conduit may be configured to deliver the agent(s) at a rate having substantially zero-order kinetics and/or at a constant rate over a selected period of time.