An adjustable cranioplasty plate assembly is provided for use following a craniectomy. The assembly includes a ring which is attached to the skull around the skull opening and a plate adjustably mounted to the ring. The plate is moveable between a raised position spaced above the ring and a lower position substantially flush with the ring. The plurality of extendable and retractable struts extends between the ring and the plate to provide the plate adjustability. The plurality of stay cables extending between the ring and the plate provide lateral stability in the raised position. The assembly replaces the native bone and eliminates the need for subsequent cranioplasty surgery. In one embodiment, the plate includes a rigid central portion, three rigid mounting tabs, and a plurality of malleable tapered perimeter petals which provide a smooth interface between the plate and the skull of the patient.

A mosaic implant (2010) comprises a mesh support frame comprising a plurality of polygonal support rings (2040 A, B, C) connected by a plurality of struts (2014), and a plurality of mosaic plates (2012). The support rings are positioned within the mosaic plates; the struts extend between adjacent plates. An implant (1510) for filling a bore hole comprises a plate (1512) and a support frame (1520) having a central portion (1522) located at least partially within the plate, a polygonal outer rim (1524) having a plurality of fastening points for attaching the implant to bone surrounding a bore hole, and a plurality of arms (1530) extending between the central portion and the outer rim. The plurality of arms extend inwardly and downwardly away from the outer rim such that the central portion is located below the plane of the outer rim and the upper surface of the plate is flush with or slightly above the upper surface of the outer rim.

An artificial bone plate unit and an assemblable artificial bone plate are provided. The artificial bone plate unit includes a plate body, multiple connecting pins and multiple connecting holes. The plate body has two main surfaces and a peripheral surface. The peripheral surface is connected between the two main surfaces. The connecting pins and the connecting holes are formed on the plate body and along the peripheral surface on the plate body. The connecting holes correspond in shape to the connecting pins. The assemblable artificial bone plate is bendable and includes multiple artificial bone plate units. The artificial bone plate units are connected using the connecting pins and the connecting holes. The assemblable artificial bone plate is assembled from artificial bone plate units and then bent into the shape of the defect area of the skull, which saves material and time.

The invention relates to novel internal fixation devices, such as bone plates, generally and novel craniomaxillofacial bone plates more specifically and systems for bonding the same. More specifically, the invention relates to bone plates made of a polymer blend of (poly)lactic acid and Ecoflex as well as a novel hot-melt adhesive polymer blend of the same material.

A plate assembly for attaching a bone flap to a skull is provided and may include a first plate member attached to the bone flap and a second plate member supported by the first plate member and movable between a retracted position and an extended position relative to the first plate member. The second plate member may be removed from a cut line between the bone flap and the skull in the retracted position and may extend over the cut line in the extended position.

Disclosed is a compound bone plate for attaching a bone flap to a skull. The compound bone plate can include a first plate member, a second plate member, a burr hole cover, and a strut. The first plate member can be operable to be attached to the bone flap and the skull. The second plate member can be operable to be attached to the bone flap and the skull. The strut can connect the first plate member, the second plate member, and the burr hole cover.

A method for single-stage cranioplasty reconstruction includes prefabricating a clear craniofacial implant, creating a cranial, craniofacial, and/or facial defect, positioning the clear craniofacial implant over the cranial, craniofacial, and/or facial defect, tracing cut lines on the clear craniofacial implant as it lies over the cranial, craniofacial, and/or facial defect, cutting the prefabricated clear custom craniofacial implant along the hand-marked lines for optimal fit of the clear implant within the cranial, craniofacial, and/or facial defect, and attaching the final clear craniofacial implant to the cranial, craniofacial, and/or facial defect with standard fixation methods of today.

A plate assembly for attaching a bone flap to a skull is provided and may include a first plate member attached to the bone flap and a second plate member supported by the first plate member and movable between a retracted position and an extended position relative to the first plate member. The second plate member may be removed from a cut line between the bone flap and the skull in the retracted position and may extend over the cut line in the extended position.

An adjustable bone implant having a body configured to be secured to a first bone surface; an anchoring member configured to be secured to a second bone surface held at a raised position offset from the first bone surface, and a spacing member connecting the anchoring member to the body in an adjustable manner, to selectively space the anchoring member from the body, where the spacing member is located subcutaneously, where the spacing member is configured to receive an input via a transcutaneoustransmission from an external tool, and where the spacing member is configured to lower the first bone surface from a raised position upon receipt of the input and secure the first bone surface at the lowered position.

A fixation device includes a first anchor portion configured to join to a first bone portion, a second anchor portion configured to join to a second bone portion, and an intermediate component that extends between the first anchor portion and the second anchor portion. The intermediate component is configured to expand, contract, and angulate enabling constrained movement of the second bone portion with respect to the first bone portion. The second anchor portion has a larger configuration relative to the first anchor portion, thereby preventing the second bone portion from depressing below the first bone portion.