Abstract: There is disclosed a constant force compression tool for measuring a compressible material. In an embodiment, the tool includes a handle having a passageway receiving a plunger. The tool includes a biasing member in communication with the plunger and the handle. The tool includes a retaining element in communication with the plunger and the handle. There is disclosed a system for measuring a compressible material with a measurement tube and a constant force compression tool. There is disclosed a method of measuring a compressible material. In an embodiment, the method includes selecting a measurement tube. The method includes placing a compressible material into the measurement tube. The method includes pressing a plunger against the compressible material. The method includes monitoring an indicator to determine a full volume of compressible material between the end of the plunger and the conical tube. Other embodiments are also disclosed.

Abstract: There is disclosed a method of combining mesenchymal stem cells (MSCs) with a bone substrate. In an embodiment, the method includes obtaining tissue having MSCs together with unwanted cells. The tissue is digested to form a cell suspension having MSCs and unwanted cells. The cell suspension is added to the substrate. The substrate is cultured to allow the MSCs to adhere. The substrate is rinsed to remove unwanted cells. In various embodiments, the tissue is adipose tissue, muscle tissue, or bone marrow tissue. In an embodiment, there is disclosed an allograft product including a combination of MSCs with a bone substrate in which the combination is manufactured by culturing MSCs disposed on the substrate for a period of time to allow the MSCs to adhere to the substrate, and then rinsing the substrate to remove unwanted cells from the substrate. Other embodiments are also disclosed.

Abstract: Compositions comprising a cartilage sheet comprising a plurality of interconnected cartilage tiles and a biocompatible carrier are provided. Methods of manufacturing cartilage compositions comprising a cartilage sheet comprising a plurality of interconnected cartilage tiles are also provided.

Abstract: There is disclosed a method of combining mesenchymal stem cells (MSCs) with a bone substrate. In an embodiment, the method includes obtaining tissue having MSCs together with unwanted cells. The tissue is digested to form a cell suspension having MSCs and unwanted cells. The cell suspension is added to the substrate. The substrate is cultured to allow the MSCs to adhere. The substrate is rinsed to remove unwanted cells. In various embodiments, the tissue is adipose tissue, muscle tissue, or bone marrow tissue. In an embodiment, there is disclosed an allograft product including a combination of MSCs with a bone substrate in which the combination is manufactured by culturing MSCs disposed on the substrate for a period of time to allow the MSCs to adhere to the substrate, and then rinsing the substrate to remove unwanted cells from the substrate. Other embodiments are also disclosed.

Abstract: Compositions comprising a plurality of cartilage particles from a human adult cadaveric donor, wherein the cartilage particles comprise viable chondrocytes, and a biocompatible carrier are provided. Methods of manufacturing cartilage compositions comprising a plurality of cartilage particles from a human adult cadaveric donor are also provided.

Abstract: Embodiments of the present invention may include a method for improving handling characteristics of an amnion tissue. The method may include providing the amnion tissue from a human donor. Furthermore, the method may include exposing the amnion tissue to supercritical carbon dioxide to form an exposed amnion tissue. The exposed amnion tissue may have a higher ultimate tensile strength and elastic modulus than the amnion tissue before the exposure.

Abstract: There is disclosed a method of combining mesenchymal stem cells (MSCs) with a bone substrate. In an embodiment, the method includes obtaining tissue having MSCs together with unwanted cells. The tissue is digested to form a cell suspension having MSCs and unwanted cells. The cell suspension is added to the substrate and the MSCs are allowed to adhere. The substrate is rinsed to remove unwanted cells. In an embodiment, there is disclosed an allograft product including a combination of MSCs with a bone substrate made according to the described method. Other embodiments are also disclosed.

Abstract: A method for determining microbial contamination of allograft products comprises providing an extraction vessel having an outer container and a removable inner basket, place the allograft product into the inner basket, providing an abstraction fluid in the outer container of the extraction vessel, positioning the inner basket in the outer container, so that the allograft product and the inner basket is submerged in the extraction fluid and agitating the extraction fluid for a predetermined amount of time and analyzing the extraction fluid from microbial contamination.

Abstract: Compositions comprising a plurality of cartilage particles from a human adult cadaveric donor, wherein the cartilage particles comprise viable chondrocytes, and a biocompatible carrier are provided. Methods of manufacturing cartilage compositions comprising a plurality of cartilage particles from a human adult cadaveric donor are also provided.

Abstract: Compositions comprising a cartilage sheet comprising a plurality of interconnected cartilage tiles and a biocompatible carrier are provided. Methods of manufacturing cartilage compositions comprising a cartilage sheet comprising a plurality of interconnected cartilage tiles are also provided.

Abstract: Osteochondral graft composition comprising a cartilage component and a bone component, and further comprising one or more perforations in the bone component and/or the cartilage component, are provided. Methods of manufacturing and using osteochondral graft compositions comprising one or more perforations in the bone component and/or the cartilage component are also provided.

Abstract: Flowable matrix compositions and methods of their use and manufacture are provided. Exemplary compositions may include a flowable, syringeable, putty-like form of acellular human dermal matrix. In some cases, compositions may include a moldable acellular collagen extracellular matrix. In use, the matrix compositions can be used to fill or treat skin voids, channel wounds, and other soft tissue deficiencies.

Abstract: There is disclosed a system for cleaning and disinfecting allograft material. In an embodiment, the system includes a sterile bag and a motorized paddle blender. The sterile bag having an outer wall configured to withstand blending forces, at least one paddle contact section, and an allograft retaining section separate from the at least one paddle contact section. The motorized paddle blender having at least one paddle configured to apply blending forces on the sterile bag on the at least one paddle contact area, a motorized portion to actuate the at least one paddle, and a door component configured to hold the sterile bag adjacent the at least one paddle. The at least one paddle and the allograft retaining section are configured to prevent the paddle from contacting the allograft material when the blending forces are applied on the sterile bag on the at least one paddle contact area.

Abstract: Embodiments of the present invention encompass graft assemblies, and methods for their use and manufacture. An exemplary bone graft assembly includes first and second bone pieces having respective mating features which, when combined, define non-uniform press fit. Related embodiments encompass graft assemblies having enclosed or hidden mating features.

Abstract: The present invention provides compositions for treating soft tissue injuries comprising a collagen matrix and mesenchymal stem cells adhered to the collagen matrix. Methods of making and using compositions comprising a collagen matrix and mesenchymal stem cells adhered to the collagen matrix are also provided.

Abstract: Osteochondral graft composition comprising a cartilage component and a bone component, and further comprising one or more perforations in the bone component and/or the cartilage component, are provided. Methods of manufacturing and using osteochondral graft compositions comprising one or more perforations in the bone component and/or the cartilage component are also provided.

Abstract: Embodiments of the present invention encompass fascia, fat, and dermis fibrous compositions, and methods for their manufacture and use. In a first aspect, embodiments of the present invention encompass methods for obtaining a fascia fiber for use in producing a biotextile. Exemplary methods may include treating a cadaveric fascia tissue with acetone, and obtaining the fascia fibers from the treated fascia tissue. In some cases, methods may include processing the fascia fibers to produce the fibrous fascia biotextile.

Abstract: Embodiments of the present invention provides bone graft compositions, and methods for their use and manufacture. A bone graft composition may include a first amount of non-demineralized cancellous bone. The composition may further include a second amount of demineralized cancellous bone. The composition may also include a third amount of demineralized cortical bone. The non-demineralized cancellous bone, the demineralized cancellous bone, and the demineralized cortical bone may be obtained from the same cadaveric donor.

Abstract: Compositions comprising a cartilage sheet comprising a plurality of interconnected cartilage tiles and a biocompatible carrier are provided. Methods of manufacturing cartilage compositions comprising a cartilage sheet comprising a plurality of interconnected cartilage tiles are also provided.