One aspect of the present disclosure relates to a method for forming a multipurpose membrane in vivo. One step of the method includes obtaining a blood component. Next, a vacuum assembly is operated to remove substantially all of the liquid from the blood component and thereby form a concentrated, substantially dehydrated blood component. The substantially dehydrated blood component is then formed into a non-coagulated injectable composition and administered to a wound of a subject.

A device for mixing a bone material with a liquid is provided. The device comprises a chamber having a proximal end and a distal end, and the bone material disposed within the chamber, the bone material comprising a DBM pellet of milled and lyophilized demineralized bone fibers; and a plunger having at least a portion slidably disposed within the proximal end of the chamber and configured to dispense the bone material mixed with liquid from the distal end of the chamber, when the plunger is in an extended position.

The disclosure provides a method of using blood or fractions thereof, e.g., serum, obtained from a mammal subjected to liver surgery, for example, obtained following a partial hepatectomy, to increase the engraftment, proliferation and/or functionality of cells on a biocompatible scaffold.

The present invention relates to methods for recellurization of blood vessels. This method is particularly useful for producing an allogeneic vein, wherein a donor vein is decellularized and then recellularized using whole blood or bone marrow stem cells. The allogeneic veins produced by the methods disclosed herein are particularly advantageous for implantation or transplantation into patients with vascular diseases.

The invention relates to a scaffold material comprising a plurality of particles of a highly porous polymeric material, characterized in that said scaffold material becomes a shapeable paste once hydrated. The specific features of the particle material impart a special behavior to the scaffold, which can be easily shaped and even highly reversibly compressed, so that in certain aspects it can, if needed, be injected, said capacity to be shaped being maintained over a high range of hydration conditions. A particular aspect of the invention relates, therefore, to the use of such scaffold material for the manufacturing of shapeable body implants, such as breast implants, to the shapeable body implants themselves as well as to non-invasive methods for using thereof in creating or reconstructing a three-dimensional volume in a subject's body part.

The invention relates to hardenable ceramic bone substitute compositions having improved setting, powders for such compositions and methods for their manufacture and use in medical treatment. More specifically the invention relates to hardenable bone substitute powder and hardenable bone substitute paste with improved setting properties, comprising calcium sulfate and heat-treated hydroxyapatite (passivated HA), which bone substitute is suitable for treatment of disorders of supportive tissue such as bone loss, bone fracture, bone trauma and osteomyelitis.

The invention relates to a scaffold material comprising a plurality of particles of a highly porous polymeric material, characterized in that said scaffold material becomes a shapeable paste once hydrated. The specific features of the particle material impart a special behavior to the scaffold, which can be easily shaped and even highly reversibly compressed, so that in certain aspects it can, if needed, be injected, said capacity to be shaped being maintained over a high range of hydration conditions. A particular aspect of the invention relates, therefore, to the use of such scaffold material for the manufacturing of shapeable body implants, such as breast implants, to the shapeable body implants themselves as well as to non-invasive methods for using thereof in creating or reconstructing a three-dimensional volume in a subject's body part.

The present invention concerns a cell-enriched fat graft and methods of making and using the same. The present invention also provides a kit for making and using the cell-enriched fat graft of invention.

A method of manufacturing a bone substitute structure for reconstruction of bone material in a patient. The method comprises the steps of providing data reflecting a cavity in a bone of a patient, defining and modelling a three dimensional structure corresponding to the cavity in the bone; and providing an individualized bone substitute structure, corresponding to the defined and modeled three dimensional structure, by combining calcium phosphate cement, growth factors and the patient's own un-coagulated blood.

Methods and devices for the repair of articular tissue using collagen material are provided. Compositions of collagen material and related kits are also provided.