An autologous bone graft substitute composition for inducing new bone formation, promoting bone growth and treating bone defects. The composition includes autologous blood; one or more analogs of an osteogenic bone morphogenetic protein selected from BMP-6, BMP-2, BMP-7, BMP-4, BMP-5, BMP-8, BMP-9, BMP-12, and BMP-13, and combinations thereof in a range of from 2 to 1000 μg per ml of autologous blood; and hydroxyapatite, tri-calcium phosphate, or a mixture thereof as a compression resistant matrix, the compression resistant matrix being provided in the form of particles having a particle size in a range of from above 74 to 8000 μm. Preferably, a ratio between the compression resistant matrix and the autologous blood coagulum is from 50 to 500 mg of the compression resistant matrix per mL of the autologous blood coagulum.

An implant for promoting accelerated wound healing. The implant comprises a non-flocculating fiber material, admixed with a settable fluid. The fiber component typically will have short fiber lengths, so as to avoid forming entangled masses or clumps when mixed with a fluid. In an embodiment, the fiber material is native collagen fibers and the settable fluid is an isolated blood fraction, such as platelet rich plasma and platelet poor plasma. The native collagen fiber retaining the native crosslinks of the source tissue and providing an architectural and structural scaffolding for advancing cellular infiltration. The wound healing implant will accelerate the bodies healing process, to provide better healing and less scar tissue of the wound site.

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

The present invention concerns a tissue-engineered medical device, as well as a method for the production said medical device, comprising the following steps: providing a polymer scaffold comprising a mesh comprising polyglycolic acid, and a coating comprising poly-4-hydroxybutyrate; application of a cell suspension containing preferably human cells to the polymer scaffold; placement of the seeded polymer scaffold in a bioreactor and mechanical stimulation by exposure to a pulsatile flux of incremental intensity, thereby forming an extracellular matrix; mounting of the graft on a conduit stabilizer and incubation in cell culture medium; decellularisation of the graft in a washing solution; nuclease treatment of the graft; and rinsing of graft. The invention further comprises and various steps of quality control of the tissue-engineered medical device.

Provided herein are settable and non-settable compositions for use in surgical procedures comprising a variety of disclosed particles and optionally including previously unclotted, lyophilized, optionally crosslinked mammalian blood plasma. Also provided are related compositions, including surgical kits and packages, as well as methods of making and using the compositions.

The present description relates to a polymer composition for use in repairing tissue of a patient comprising at least one blood component, as polymer, such a chitosan, and at least one inorganic salt, such as NaCl, method of the composition and method of preparing the composition.

A method for coating a medical implant applies at least one coating to at least one surface of the implant by plasma polymerization. The implant has pores sized in the nanometer range. The method stabilizes the pores. The plasma polymerization is conducted in the presence of a coating gas and oxygen. A coating parameter can be selected so that a rough surface of the implant is coated. An implant includes a membrane having pores sized in the nanometer range. A surface of the implant is at least partially coated with a plasma polymer. The interior of the pores is uncoated.

A method for producing an implant material by: (A): setting a porous ceramic material having substantially unidirectionally arrayed pores at any depth position inside a container, (B): filling the container with a cell-containing liquid containing at least bone marrow blood and/or peripheral blood, and (C): applying, on the container, a centrifugal force in the direction along the axis of the container.

Disclosed are methods, devices, and techniques useful for enhancing function of an organ or cellular graft through photoceutical manipulation. In one embodiment a hematopoietic graft is treated with one or more wavelengths of low level laser irradiation at a sufficient energy to enhance homing and engraftment. In another embodiment the recipient long bones are treated with one or more wavelengths of low level laser irradiation at a sufficient energy to enhance chemoattraction and growth factor secretion on recipient stromal cells. Application of the invention includes areas of cellular transplants such as islet and hepatic cell grafts.

In vitro and in vivo application of sub-atmospheric, negative pressure on growth factor starting material, such as whole blood, extracts growth factors from the platelet granules of the growth factor starting material in a non-destructive medium without activating the clotting process. The extracted growth factors are released into a growth factor composition containing blood plasma, extracellular fluid or interstitial fluid depending upon the type and location of the growth factor starting material. The growth factors have a weight of about 70-76 kDaltons and are applied in either a filtered or unfiltered state topically to the area of a surface wound to effect healing. The extracted growth factors are also injected into soft tissue, such as a torn tendon, to promote tissue growth and healing. The growth factors are released in one method from a patient's own blood. In another method the growth factors are released from a whole blood source and freeze dried by lyophilization. Then at a later date, the freeze-dried product is reconstituted by normal saline for treatment of a patient's wound, for use in a surgical procedure, or for tissue regeneration.