A bone cleaning assembly with cleaning elements that remove soft tissue from bone stock. The module also includes a clearing element that is periodically urged against the cleaning elements to remove bone stock trapped by the cleaning elements from the cleaning elements.

A mill head for replaceable attachment to a base so as to collectively form a bone mill. The mill head includes shell with: a first opening in which bone stock is introduced into the head; and a second opening through which the bone chips are discharged. A cutting device is mounted in the shell to both rotate and move laterally. Attached to the cutting device are coupling features for engaging a drive spindle able to rotate the cutting device. Also attached to the housing is an alignment feature. The alignment feature engages a complementary alignment feature associated with the drive spindle so as a result of the engagement of the alignment features, the cutting device moves within the shell so that the cutting device coupling features are positioned to engage the drive spindle.

There is disclosed a system and method for dispersing sterile water from a circulating high-purity water system to a processing field containing allograft tissue. One embodiment includes a fluid inlet that is fluidly coupled with and configured to receive sterile water from the water system. The dispersion system also includes at least first and second fluid outlets that are selectively operable to deliver respective first and second fluid streams into different areas of the processing field. At least one of the first and second fluid outlets may be associated with a regulator valve configured to provide an adjustable flowrate to conserve water pulled from the circulating water system to meet the needs of the application taking place within the processing field. Other embodiments are also disclosed.

There is disclosed a system and method for dispersing sterile water from a circulating high-purity water system to a processing field containing allograft tissue. One embodiment includes a fluid inlet that is fluidly coupled with and configured to receive sterile water from the water system. The dispersion system also includes at least first and second fluid outlets that are selectively operable to deliver respective first and second fluid streams into different areas of the processing field. At least one of the first and second fluid outlets may be associated with a regulator valve configured to provide an adjustable flowrate to conserve water pulled from the circulating water system to meet the needs of the application taking place within the processing field. Other embodiments are also disclosed.

A processing arrangement for tissue material removed from a patient and to be applied after processing, such as in particular an autologous cartilage or bone tissue, includes a collection container which has a collection receptacle for receiving the tissue material removed from a tissue removal device, a processing container which has a mixing receptacle for receiving the tissue material and a liquid to pasty medium, and a processing device for mixing of the tissue material and the medium. A connection device is provided, on which a first fastener for attaching the collection container and second fastener for attaching the processing container and one passage opening, which can be positioned between the collection receptacle and the mixing receptacle, are provided.

A cleaning module for cleaning bone stock used in surgical procedures. The cleaning module includes a shell. The shell defines a void space to receive the bone stock. A cutter is rotating mounted in the void space. A shaving tube, also able to rotate, is coaxially disposed about the cutter. The cutter and shaving tube have complementary edges. A drive assembly rotates the cutter and shaving tube at different speeds, at different times or in different directions relative to the cutter. As a result of the rotation of the cutter and shaving tube soft tissue adhering to the bone stock is cut away from the bone stock by the relative rotating of the cutting edges of the cutter and shaving tube.

There is disclosed a system and method for dispersing sterile water from a circulating high-purity water system to a processing field containing allograft tissue. One embodiment includes a fluid inlet that is fluidly coupled with and configured to receive sterile water from the water system. The dispersion system also includes at least first and second fluid outlets that are selectively operable to deliver respective first and second fluid streams into different areas of the processing field. At least one of the first and second fluid outlets may be associated with a regulator valve configured to provide an adjustable flowrate to conserve water pulled from the circulating water system to meet the needs of the application taking place within the processing field. Other embodiments are also disclosed.

Disclosed are various bioactive grafts and methods of making the same. In one embodiment, bone material is harvested from a donor. The harvested bone material is exposed to a lysing agent, the lysing agent configured to release growth factors and bioactive materials from cellular material of the harvested bone material. The harvested bone material is then rinsed with a rinsing agent. The pH of the harvested bone material is substantially neutralized.

A device for hydrating particulate bone material is provided. The device comprises a tubular member having an interior surface and an exterior surface. The interior surface is configured to receive the particulate bone material and a hydration fluid. The exterior surface has a plurality of pores configured to allow the hydration fluid to flow into the interior surface of the tubular member and hydrate the particulate bone material. The plurality of pores are smaller in size than the particulate bone material. Methods of dispensing particulate the bone material are also provided.

Disclosed are various bioactive and/or biocompatible materials and methods of making the same.