Elongated, curled cartilage fibers and shaped implants comprising them are disclosed, as well as methods for making and using them. A cohesive mass of intertwined cartilage fibers may be shaped to provide a shaped implant which conforms to an implant site. The implant may also be reshaped to have a second shape which conforms to an implant site. The implant site may be the cavity of a cartilage defect, or a space or pocket at a treatment site, any of which may have resulted from treatment, injury, or disease. The implant may be shaped or reshaped to conform to, or replace, an anatomical feature or portion thereof, for repair or treatment of the anatomical feature. Shaped implants comprising the cartilage fibers have good shape retention and are capable of completely filling, and resisting migration from, an implant site after administration and hydration.

A process and system provides for atraumatic preparation of morselized Tissue Particles (TP)s, such as Full Thickness Skin Graft Particles (FTSGPs), cartilage particles and other organ tissue particles, in a liquid medium. The resultant tissue product may be a suspension of Tissue Particles in an aqueous solution and containing highly viable cells and may be rapidly prepared at bedside or in the operating room and conveniently delivered to a patient through a syringe or similar applicator. The morselized Tissues Particles may be used for surgical applications including wound healing, cosmetic surgery, and orthopedic cartilage repairs.

Medical devices having engineered mechanically functional cartilage from adult human mesenchymal stem cells and method for making same.

An implant having at least one biodegradable support structure and at least one dried covering material at least partially covering the at least one biodegradable support structure. The dried covering material is selected from an autologous, xenogeneic or allogeneic material or combinations thereof. The biodegradable support structure includes or consists of magnesium, zinc or iron; or the biodegradable support structure includes or consists of a biodegradable magnesium-based alloy, a biodegradable zinc-based alloy or a biodegradable an iron-based alloy.

The development and construction of implantable artificial organs, and a process for manufacturing three-dimensional polymer microscale and nanoscale structures for use as scaffolds in the growth of biological structures such as hollow organs, luminal structures, or other structures within the body are disclosed.

The present invention relates to a method for preparing a biocompatible porcine cartilage-derived extracellular matrix membrane capable of adjusting an in-vovo degradation rate and a mechanical property, and a composition containing the porcine cartilage-derived extracellular matrix as an active ingredient, for preventing adhesion between tissues and/or organs. Despite its high biocompatibility as a natural material, cartilage tissue extracellular matrix has a short decomposition period and its mechanical property is weak, thereby restricting the application. Accordingly, a method of enhancing the mechanical property through physical or chemical treatment and radiation treatment has been developed. In the present invention, biomaterials of various formulations were produced by treating the porcine cartilage-derived extracellular matrix with physiochemical methods. In addition, although was carried out, a characteristic that the above cartilage-specific function was maintained despite the treatment of the physico-chemical treatment was checked. Furthermore, it may also be used as an adhesion inhibitor with excellent in-vivo stability and anti-adhesion effect by using the porcine cartilage-derived extracellular matrix material.

The present invention provides a novel way to replenish the disc using retooled disc compositions to repair degenerative discs. There is no better source of proteoglycans than the actual disc material (6) itself. To this end, there has been developed a technique to remove the nucleus pulposus and retool the morphology of the nucleus pulposus to create a powder material (10) that is dry and can be stored at room temperature for long periods of time. This powder (10) can then be reconstituted with a variety of fluids, the most suitable being normal saline or lactated ringers to form a flowable mixture (20).

A method for producing a collagen meniscus implant by obtaining a freshly excised non-human meniscus, rinsing it in an aqueous solution, drying the rinsed meniscus, shaping it to approximate in dimension an average-sized human meniscus, extracting non-collagenous material from the shaped meniscus, and sterilizing it, yielding a collagen meniscus implant containing at least 90% by weight of type I collagen, less than 0.5% by weight of glycosaminoglycan, and less than 600 ppm DNA. Also disclosed is a collagen meniscus implant prepared by the above method. Further provided is a biocompatible and bioresorbable porous implant for meniscus repair. The implant includes a three-dimensional network of collagen fibers oriented in a direction approximating the collagen fiber orientation of a human meniscus. The implant has a size and a contour substantially equivalent to a human meniscus, and has a chemical composition similar to the above-described collagen meniscus implant.

The present application relates to bioactive implants, methods of making bioactive implants, and methods of using bioactive implants to treat or repair a bone defect or a cartilage defect. In an aspect, the present application relates to compositions comprising bone microparticles in a solution, wherein the compositions harden upon desiccation into bioactive implants. In an aspect, the present application relates to compositions comprising cartilage microparticles in a solution, wherein the compositions harden upon desiccation into bioactive implants. In an aspect, disclosed herein are methods of making and using the disclosed compositions comprising bone microparticles and the disclosed composition comprising cartilage microparticles. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present invention.

The present invention provides a method of preparing biomembrane, closed structure with biomembrane characteristics or cellular compartment, comprising the following steps: 1), acquire biological cells from natural tissues or natural biological species; 2), culture the cells obtained in step 1) massively in an appropriate environment; 3), acquire the lysates of cells in step 2), and extracting the biomembrane, closed structure with biomembrane characteristics and cellular compartment through differential centrifugation, density gradient centrifugation or dual-phase extraction individually or a combination of two methods or a combination of three methods thereof. The membrane is a natural biomembrane, closed structure with biomembrane characteristics and cellular compartment, which can be used for package of active ingredients in various fields.