The present invention relates to a medical implant, especially to an assemblable artificial bone plate and an artificial bone plate unit that can be used for cranioplasty, i.e., surgical repair of a bone defect in the skull.
After removal of a large area of a skull of a patient due to trauma or operation, cranioplasty needs to be carried out to repair the defect area in the skull using an artificial bone plate to cover the defect area of the skull. The artificial bone plate provides proper protection for the vulnerable brain tissue and prevents sequelae.
A conventional artificial bone plate used in cranioplasty is cut by machining from a chunk of material; to be precise, a chunk of metal or polymer is cut into the shape of the removed bone of the skull, and then the machined artificial bone plate is fixed to the skull by surgery.
However, the surface of the skull is curved, and therefore a great amount of material needs to be removed during the machining process, which causes a waste of material and time.
To overcome the shortcomings, the present invention provides an assemblable artificial bone plate and an artificial bone plate unit to mitigate or obviate the aforementioned problems.
The main objective of the present invention is to provide an assemblable artificial bone plate and artificial bone plate units that save material and take less time to manufacture.
An artificial bone plate unit of a first configuration comprises 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 are formed on the plate body and along the peripheral surface on the plate body. The connecting holes are formed in 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 comprises multiple aforementioned artificial bone plate units. The artificial bone plate units are connected using the connecting pins and the connecting holes.
An artificial bone plate unit of a second configuration comprises 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 are formed on the plate body and along the peripheral surface on the plate body.
An artificial bone plate unit of a third configuration comprises 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 holes are formed in the plate body and along the peripheral surface on the plate body.
By designing the artificial bone plate units each having the connecting pins and the connecting holes formed along the peripheral surface, the artificial bone plate units can be connected with each other using the connecting pins and the connecting holes located in the edge to form a larger piece of an assemblable artificial bone plate. An artificial bone plate for the patient is produced by connecting multiple said artificial bone plate units of the present invention to form a larger piece of the assemblable artificial bone plate, and then bend the assemblable artificial bone plate to make its shape correspond to a shape of a defect area of a skull. In this case, a waste of expensive medical grade material due to machining is prevented, and also the time it takes to produce the artificial bone plate is shorter.
Other objectives, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
With reference to
The connecting pins 30 and the connecting holes 40 are formed on the plate body and along the peripheral surface 20 on the plate body. The connecting holes 40 correspond in shape to the connecting pins 30, which means two artificial bone plate units in accordance with the present invention can be assembled together by engaging one of the connecting pins 30 of one plate unit with one of the connecting holes 40 of the other plate unit.
Connecting rods 30 and connecting holes 40 are formed on the peripheral surface 20 of the plate body, and therefore when multiple said artificial bone plate units are assembled together to form an assemblable artificial bone plate, a surface of the assemblable artificial bone plate is substantially smooth as edges of the plate bodies do not protrude therefrom. However, positions of the connecting pins 30 and the connecting holes 40 are not limited by the abovementioned, as long as the connecting pins 30 and the connecting holes 40 are formed along the peripheral surface 20 in the plate body, which means the connecting pins 30 and the connecting holes 40 only have to surround or be formed along the peripheral surface 20, and do not have to be located on the peripheral surface 20. To be precise, the connecting pins 30 and the connecting holes 40 can be formed on the peripheral surface 20 as shown in
The plate body in a preferred embodiment is a six-sided polygon, and to be precise, the plate body is a regular hexagon, such that the six connecting faces 21 are formed on the peripheral surface 20. A number of the connecting pins 30 are six, and the six connecting pins 30 are formed on the six connecting faces 21 respectively. A number of the connecting holes 40 are six, and the six connecting holes 40 are formed in the six connecting faces 21 respectively. In another preferred embodiment, the plate body can be an N-sided polygon other than hexagon, where N is an integer greater than 2. When the plate body is the N-sided polygon other than hexagon, a number of the connecting faces 21, the number of the connecting pins 30, and the number of the connecting holes 40 are N. The N connecting pins 30 are formed on the N connecting faces 21 respectively, and the N connecting holes 40 are formed in the N connecting faces 21 respectively. In other words, each side of the N-sided polygonal plate body has a connecting pin 30 and a connecting hole 40.
Moreover, a number of the connecting pin 30 on each connecting face 21 and a number of the connecting hole 40 on each connecting face 21 are not limited to one. For example, in a second embodiment in accordance with the present invention (as shown in
A shape of the connecting pin 30 is cylindrical, while the connecting hole 40 is a round recess, which corresponds to the shape of the connecting pin 30. However, the shapes of the connecting pin 30 and connecting hole 40 are not limited to the abovementioned, and can be of other shapes depending on the application. For example, the connecting pin 30B can be a quadrilateral prism as shown in
In another preferred embodiment, a round connecting ball 50E is connected to the tip of the connecting pin 30E (as shown in
With reference to
With reference to
The connecting pins 30F are formed on one of the two main surfaces 10F. The connecting holes 40F are formed through the two main surfaces 10F of the artificial bone plate unit. In a preferred embodiment, multiple screw holes 11F are formed through the two main surfaces 10F, and the screw holes 11F are located along the peripheral face 20F of the plate body. However, positions of the screw holes 11F are not limited by abovementioned positions, and the plate body may optionally have no screw holes 11F.
In a preferred embodiment, the plate body is polygonal, such that multiple corner portions 22F are formed on the peripheral surface 20F. Each of the connecting pins 30F is disposed adjacent to one of the corner portions 22F, and each of the connecting holes 40F is disposed adjacent to one of the corner portions 22F. To be precise, the plate body is a six-sided polygon, and the corner portions 22F are located adjacent to the corner positions of the polygonal plate body. However, positions of the connecting pins 30F and the connecting holes 40F are not limited by abovementioned positions. For example, the connecting pins 30F and the connecting holes 40F can be located in the middle of two of the adjacent corner portions 22F.
In a preferred embodiment, the plate body is an N-sided polygon, such that the N connecting faces 21F are formed on the peripheral surface 20F. A sum of a number of the connecting pins 30F and a number of the connecting holes 40F are N. To be precise, N is six, and the plate body is hexagonal, such that the six connecting faces 21F are formed on the peripheral surface 20F. Three connecting pins 30F and three connecting holes 40F are formed on the plate body, making the sum of the number of the connecting pins 30F and the number of the connecting holes 40F to be six, through which a polygonal plate body can be securely connected to an adjacent polygonal plate body. However, the sum of the number of the connecting pins 30F and the number of the connecting holes 40F are not limited by the abovementioned. For example, the sum of the number of the connecting pins 30F and the number of the connecting holes 40F in the polygonal plate body can be twelve.
With reference to
A distance between the two main surfaces 10F is defined as a thickness of the plate body. The thickness of the plate body in the aforementioned seventh and eighth embodiments of the artificial bone plate unit is less than 1 mm, but the thickness of the plate body in the embodiment wherein the connecting pins 30F and the connecting holes 40F are formed on the main surface 10F is not limited by abovementioned as long as the plate body can be deformed when bended to satisfy the need of a surgical repair.
In all the abovementioned embodiments of the artificial bone plate unit, the artificial bone plate unit can be made of a material with good biocompatibility and mechanical strength, such as titanium, Ti-6Al-4V, 316L stainless steel or polyether ether ketone (PEEK). The artificial bone plate unit can also be made of aluminum for reduced weight and cost.
With reference to
To use the present invention, first connect several artificial bone plate units together to form a larger piece of the assemblable artificial bone plate, and then bend the assemblable artificial bone plate to make the shape of the assemblable artificial bone plate correspond to the shape of a defect area of a skull.
When the assemblable artificial bone plate is of the second embodiment (as shown
When the assemblable artificial bone plate is of the first embodiment (as shown
Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and features of the invention, the disclosure is illustrative only. Changes may be made in the details, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.