Surgeons are performing more and more spinal surgeries to correct different spinal defects in the hopes of reducing pain and restoring normal or close to normal movement. One area of particular interest lies in the restoration of normal spacing between adjacent vertebral bodies. Whether due to the degeneration of the intervertebral disc over time or because of an injury, a decrease in spacing between vertebral bodies can cause a myriad of problems for a patient, the least of which is pain resulting from the pinching of nerves between the bodies. Correcting this problem is often very important to returning a patient to his or her normal level of activity and/or managing the pain associated with a degenerative spinal problem.
Over the years, there have been many different techniques employed in restoring the normal disc space. For instance, solid fusion devices have been implanted in many patients in the hopes of both restoring normal disc spacing and preventing further degeneration of the space by fusing the vertebral bodies to one another. Recently, there has been a trend to both restore the disc spacing and allow natural movement of the adjacent vertebral bodies with respect to one another. Nonetheless, there exist certain extreme cases of degradation of the disc space which require extreme measures in order to restore the natural spacing.
Often, the decrease in spacing will be so drastic that some amount of distraction of the adjacent vertebral bodies will be required. Although this distraction is sometimes achieved through the use of various tools, the desire for faster and more efficient surgical techniques favors the elimination of superfluous surgical steps. Thus, there exists a need for an intervertebral implant which is implantable in an unexpanded state and easily expandable to restore the disc space, thereby negating the need for additional tools and the additional surgical steps of using them.
An expandable implant for implantation between two vertebral bodies is disclosed. The implant can include a first member, the first member including a first vertebral contact surface and a first interior surface, a second member, the second member including a second vertebral contact surface and a second interior surface, the first and second interior surfaces facing towards one another, a strut attached to both the first and second members, and a wedge disposed between the first and second interior surfaces and attached to at least one of the first or second members. Movement of the wedge in a first direction can cause movement of at least one of the first or second members in a second direction.
The wedge can be attached to at least one of the first or second members by a deformable tether. The implant can include first and second wedges, where movement of the first and second wedges towards one another causes an increase in a distance between the first and second interior surfaces. The first and second wedges can each be attached to both of the first and second members by a deformable tether. One of the first or second wedges can include a bulleted or rounded surface for aiding in insertion of the expandable implant between the two vertebral bodies. The first wedge can include first and second angled wedge surfaces for cooperating with first and second angled interior surfaces of the first and second members, respectively. The second wedge can include third and fourth angled wedge surfaces for cooperating with third and fourth angled interior surfaces of the first and second members, respectively. Movement of the first and second wedges towards one another can be permitted, while movement of the first and second wedges away from one another can be prevented. This can be the case because the first, second, third, and fourth wedge surfaces and the first, second, third, and fourth interior surfaces can each include teeth. The first and second members and the first and second wedges can also cooperate to define at least one aperture through the implant adapted for bone growth therethrough.
Another expandable implant for implantation between two vertebral bodies is disclosed. The implant can include a first member, the first member including a first vertebral contact surface and a first interior surface, a second member, the second member including a second vertebral contact surface and a second interior surface, the first and second interior surfaces facing towards one another, a strut attached to both the first and second members, and first and second wedges disposed between the first and second interior surfaces, one of the first or second wedges including a bulleted or rounded surface for aiding in insertion of the expandable implant between the two vertebral bodies. Movement of the first wedge towards the second wedge can causes an increase in a distance between the first and second interior surfaces.
Each of the first and second wedges can be attached to each of the first and second members by deformable tethers. The first wedge can include first and second angled wedge surfaces for cooperating with first and second angled interior surfaces of the first and second members, respectively. The second wedge can include third and fourth angled wedge surfaces for cooperating with third and fourth angled interior surfaces of the first and second members, respectively. Movement of the first and second wedges towards one another can be permitted, while movement of the first and second wedges away from one another can be prevented. This can be the case because the first, second, third, and fourth wedge surfaces and the first, second, third, and fourth interior surfaces each include teeth. The first and second members and the first and second wedges can cooperate to define at least one aperture through the implant adapted for bone growth therethrough.
An expandable implant for implantation between two vertebral bodies is disclosed. The implant can include a first member. The first member can include a first vertebral contact surface and a first interior surface, a second member, the second member including a second vertebral contact surface and a second interior surface, the first and second interior surfaces facing towards one another, a strut attached to both the first and second members, and first and second wedges disposed between the first and second interior surfaces. Movement of the first wedge towards the second wedge can cause an increase in a distance between the first and second interior surfaces, and at least one of the first and second wedges can be prevented from torsionally moving with respect to the first and second members.
Each of the first and second wedges can be attached to each of the first and second members by deformable tethers. The first wedge can include first and second angled wedge surfaces for cooperating with first and second angled interior surfaces of the first and second members, respectively. The second wedge can include third and fourth angled wedge surfaces for cooperating with third and fourth angled interior surfaces of the first and second members, respectively. Movement of the first and second wedges towards one another can be permitted, while movement of the first and second wedges away from one another can be prevented. This can be the case because the first, second, third, and fourth wedge surfaces and the first, second, third, and fourth interior surfaces can each include teeth. The first and second members and the first and second wedges can cooperate to define at least one aperture through the implant adapted for bone growth therethrough. The first and second members can include either a depression or a protuberance, and the first and second wedges can include the other of a depression or a protuberance. The first and second members can include a tongue, a pin, or an elongate projection, and the first and second wedges can include either a groove or a channel.
Yet another expandable implant for implantation between two vertebral bodies is disclosed. The implant can include a first member, the first member including a first vertebral contact surface and a first interior surface having a first and third angled interior surfaces, a second member, the second member including a second vertebral contact surface and a second interior surface having second and fourth angled interior surfaces, the first and second interior surfaces facing towards one another, a strut attached to both the first and second members, a first wedge disposed between the first and second interior surfaces, the first wedge including first and second angled wedge surfaces for cooperating with the first and second angled interior surfaces of the first and second members respectively, and a second wedge disposed between the first and second interior surfaces, the second wedge including third and fourth angled wedge surfaces for cooperating with the third and fourth angled interior surface of the first and second members respectively. Movement of the first wedge towards the second wedge causes an increase in a distance between the first and second interior surfaces, and movement of the first and second wedges towards one another can be permitted, while movement of the first and second wedges away from one another can be prevented.
The first, second, third, and fourth wedge surfaces and the first, second, third, and fourth interior surfaces can each include teeth. The first and second members and the first and second wedges can cooperate to define at least one aperture through the implant adapted for bone growth therethrough.
Yet another expandable implant for implantation between two vertebral bodies is disclosed. The implant can include a first member, the first member including a first vertebral contact surface and a first interior surface having a first and third angled interior surfaces, a second member, the second member including a second vertebral contact surface and a second interior surface having second and fourth angled interior surfaces, the first and second interior surfaces facing towards one another, a plurality of struts attached to both the first and second members, a first wedge disposed between the first and second interior surfaces, the first wedge including first and second angled wedge surfaces for cooperating with the first and second angled interior surfaces of the first and second members respectively, a first tether connecting the first wedge to one of the first or second members, a second wedge disposed between the first and second interior surfaces, the second wedge including third and fourth angled wedge surfaces for cooperating with the third and fourth angled interior surface of the first and second members respectively, and a first tether connecting the first wedge to one of the first or second members. Movement of the first wedge towards the second wedge causes an increase in a distance between the first and second interior surfaces, and the first, second, third, and fourth wedge surfaces and the first, second, third, and fourth interior surfaces each include teeth. One of the first or second wedges can include a bulleted or rounded surface for aiding in insertion of the expandable implant between the two vertebral bodies.
A method of implanting an expandable implant between two vertebral bodies is disclosed. The method can include the steps of inserting the expandable implant between two vertebral bodies. The implant can have a first member, a second member, and a wedge disposed between the first and second members and attached to at least one of the first or second members. The method also includes the step of moving the wedge in a first direction so as to cause movement of the first and second members which in turn causes movement of the vertebral bodies away from one another.
The implant can further include at least one deformable strut and more than one wedge. Each wedge can be attached to at least one of the first or second members by a deformable tether. In some cases, the wedges can be attached to both members by deformable tethers. The implant can further include structure which allows for the movement of the at least one wedge in a first direction, but prevents movement of the wedge in an opposition direction. The wedge can be prevented from torsionally rotating with respect to the first and second members.
A more complete appreciation of the subject matter of the disclosure and the various advantages thereof can be realized by reference to the following detailed description in which reference is made to the accompanying drawings in which:
Referring to the drawings, wherein like reference numerals refer to like elements,
As is shown in
As is also shown in
First wedge 16 can further include an angled, bulleted, or rounded exterior surface for aiding in insertion of implant 10 between adjacent vertebrae. In the variation shown in
Struts 20a-d can be deformable so as to allow for the expansion of implant 10 upon the movement of first and second members 12 and 14 away from one another. There are many different designs for such deformable struts that can be employed. For example, as is shown in
First and second wedges 16 and 18 are each respectively attached to both first and second members 12 and 14. As is shown in
In order to be suitable for implantation into the human body, all of the elements of implant 10 can be biocompatible. For example, in a variation, each of the components of implant 10 is constructed of a metal, such as titanium (commercially pure grade 2). However, other biocompatible materials can be utilized, like other titaniums, PEEK, titanium/PEEK composites, nitinol, bioresorbables, and the like. Depending upon the material utilized, certain of the components can be formed integral with or separately from one another. For example, struts 20a-d, in certain variations, can be formed integral with first and second members 12 and 14. In other variations, struts 20a-d and first and second members 12 and 14 can be formed separately and constructed together in accordance with normal practices. For instance, these portions could be welded or otherwise fused together.
Implant 10 also can include certain elements which cooperate to substantially prevent torsional movement of the first and second wedges 16 and 18 with respect to first and second members 12 and 14. Of course, such elements are not required for proper operation of the device. As is shown in
The cooperation between the above-discussed protuberances and channels is such that movement of wedges 16 and 18 with respect to each other and first and second members 12 and 14 is not inhibited (i.e., the wedges can move in similar directions as depicted by arrows A and B of
In operation, movement of first wedge 16 in the direction of arrow A (
The deformable nature of tethers 46a-d and 48a-d allows them to follow along with first and second wedges 16 and 18 during their movement towards one another. So, at all times the wedges are connected to first and second members 12 and 14, thereby preventing them from becoming dislodged from implant 10. This is an important safety feature of the implant. Furthermore, the above-discussed teeth located on the first and second angled interior surfaces and the angled wedge surfaces allows for the movement of first and second wedges 16 and 18 in the direction of arrows A and B, respectively, but prevents opposite movement of the components. In other words, the different cooperating teeth (i.e., 27a and 37a, 27b and 39a, 33a and 37b, and 33b and 39b) are designed so as to allow the first movement, but prevent the second, opposite movement. Many different teeth designs can be employed in order to achieve this functionality.
Upon movement of first and second wedges 16 and 18 towards one another, first and second members 12 and 14 expand, which can act to both distract the vertebral space and also dig projections 23 and 29 of the vertebral contact surfaces 22 and 28 into the vertebral end plates of the vertebra they are in contact with. As is mentioned above, the different cooperating teeth (i.e., 27a and 37a, 27b and 39a, 33a and 37b, and 33b and 39b) allow for the expansion of implant 10, but prevent its contraction. Thus, once expanded, implant 10 remains in such a state without the addition of any further components. Nonetheless, one or more locking components could be utilized to ensure that implant 10 remains in the expanded state.
It is to be understood that the above brief discussion of the surgical procedure is merely exemplary, and more, less, or different steps can be performed. Moreover, one or more implant 10 can be inserted and deployed between adjacent vertebrae. Depending upon the overall size of the implant (which can widely vary), more than one implant can be required in order to properly support the disc space. With the implant(s) in place and deployed, the disc space can be restored to at or near its original height. Bone growth can occur through apertures 34 and 36 of the first and second members 12 and 14, respectively. First and second wedges 12 and 14 can include similar apertures or voids which ensure an open passage through implant 10 upon full expansion. In the expanded state, the interior of implant 10 can be packed with bone morphonogenic proteins or other bone growth inducing substances in order to encourage this bone growth from one adjacent vertebra to the other.
The cooperation between the protuberances and channels is like that that similar elements of implant 10 such that movement of wedges 116 and 118 with respect to each other and first and second members 112 and 114 is not inhibited. However, any torsional or rotational movement of the wedges with respect to the first and second members is prevented. In other words, first and second wedges 116 and 118 are prevented from going off track.
Although the disclosure has been described with reference to particular variations, it is to be understood that these variations are merely illustrative of the principles and applications of the disclosure. It is therefore to be understood that numerous modifications can be made to the illustrative variations and that other arrangements can be devised without departing from the spirit and scope of the present invention as defined by any claims presented.
Number | Date | Country | |
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61099156 | Sep 2008 | US |