Described herein are dehydrated, laminated tissue grafts composed of two or more membrane layers of an amnion membrane, a chorion membrane, a Wharton's jelly, or an intermediate tissue layer, where a layer of micronized placental tissue is interposed between two of the layers. Also described herein are methods for making and using the laminated tissue grafts.

A solubilized notochordal cell matrix powder dissolved in a carrier solvent or formed as a gel is provided. The notochordal cell matrix powder originates from lyophilized and treated porcine nucleus pulposus tissue containing notochordal cells. The powder contains less than 20% of porcine nucleid acids, and the powder contains a substantially unchanged amount of porcine protein content compared to the originating porcine nucleus pulposus tissue. The solubilized notochordal cell matrix powder is capable of stimulating native or stem cells to proliferate and produce a significant increase inglycosaminoglycansand type-II collagen matrix. Embodiments of the invention can be used for the disc regenerative treatment of discogenic back and neck pain in an orthopaedic and/or pharmaceutical setting/approach.

The present invention provides a kidney production method including a step of tissue-specifically removing a metanephric mesenchyme of a metanephros of a non-human animal; a step of transplanting a human kidney precursor cell into the metanephros; and a step of advancing development of the metanephros, which is a step in which the transplanted human kidney precursor cell is differentiated and matured to form a part of the kidney.

The present invention provides a kidney production method including a step of tissue-specifically removing a metanephric mesenchyme of a metanephros of a non-human animal; a step of transplanting a human kidney precursor cell into the metanephros; and a step of advancing development of the metanephros, which is a step in which the transplanted human kidney precursor cell is differentiated and matured to form a part of the kidney.

A viable disc regenerative composition has a micronized material of nucleus pulposus and a biological composition made from a mixture of mechanically selected allogeneic biologic material derived from bone marrow having non-whole cellular components including vesicular components and active and inactive components of biological activity, cell fragments, cellular excretions, cellular derivatives, and extracellular components; and wherein the mixture is compatible with biologic function and further includes non-expanded whole cells. The biological composition is predisposed to demonstrate or support elaboration of active volume or spatial geometry consistent in morphology with that of disc tissue. The viable disc regenerative composition extends regenerative resonance that compliments or mimics disc tissue complexity.

A graft compression system for compressing soft tissue grafts used in connection with reconstructive surgery on the anterior cruciate ligament (ACL). The graft compression system includes a compression chamber having an elongate hollow shaft body having two ends that are threaded to mate with correspondingly threaded collet nuts. Collets are removably inserted into, and engage, the collet nuts fastened to opposing ends of the compression chamber A surgical graft may be inserted into a hollow compression tube having a lumen with a compressible diameter, said compression tube being sized for insertion into the collets and compression chamber. When such collet nuts are tightened by a user of the graft compression system, the inner diameters of the respective collet nuts nested within such collet nuts are decreased, causing the diameter of the lumen of the hollow compression tube to in turn be decreased and compress the surgical graft within.

A pre-sutured allograft construct and method of manufacture for repairing, replacing, reconstructing, or augmenting a hip or shoulder labrum may include a folded tissue portion extending from a first end to a second end and forming top, middle, and bottom folds. A stitched pattern secures the folded tissue portion into a graft roll having an overall length extending from a first adjustable region, through a central region, and through a second adjustable region. A continuous series of whip stitches extends from the first adjustable region, through the central region, and through the second adjustable region. A series of triple circumferential stitches overlays the whip stitches in the first and the second adjustable regions, while a series of circumferential stitches alternates with the whip stitches in the central region. The construct is pre-manufactured as an allograft product, but is adjustable during the surgical procedure within the body. Other embodiments are also disclosed.

The present disclosure provides biomaterials and methods for preventing and minimizing progression of cartilage and/or connective tissue damage. Also provided herein are biomaterials and methods for alleviating and/or reducing the risk for developing arthritis (e.g., osteoarthritis) associated with joint injury and/or joint surgery.

A method of treating a lesion in a gastrointestinal tract and an injectate system are provided. The method includes injecting a crosslinkable gel into a first tissue layer, the crosslinkable gel increasing a volume of the first tissue layer. The method also includes providing a crosslinker and resecting a portion of a first tissue layer having the increased volume away from a second tissue layer creating an exposed region in a remaining portion of the first layer and leaving a portion of the gel covering at least a portion of the exposed region. The injectate system includes a crosslinkable gel and a crosslinker where the crosslinkable gel and the crosslinker form a crosslinked gel having a compressive modulus of about 10-500 kPa.

A tissue collection and processing system for collecting bone fragments and tissue aspirated from a bone. The tissue collection and processing system includes a collection vessel, a collection vessel cap, a processing cover, a first tubing and a fluid withdrawal mechanism. The collection vessel has an opening formed therein to receive bone fragments and tissue aspirated from the bone. The collection vessel cap is capable of engaging the collection vessel to substantially seal the opening. The collection vessel cap or the collection vessel has a first port. The processing cover has an upper surface and a lower surface. The processing cover has a connection port and a bore. The connection port is proximate the upper surface. The bore is fluidly connected to the connection port and extends toward the lower surface. The processing cover has a density that is less than a density of fluid in the aspirated bone fragments and tissue. The fluid withdrawal mechanism is fluidly connected to the connection port with the first tubing to withdraw the fluid from the collection vessel. As fluid is withdrawn from the collection vessel, the processing cover is slidable in the collection vessel.