A spinal implant revision device has a revision connector and a tulip member. The revision connector is configured for attachment to a pre-existing rod in a patient. The revision connector has a slotted opening configured to receive a first or a pre-existing rod. The tulip member is pivotally connected to the revision connector and movable in angularity within predetermined ranges in a first plane. This first plane is parallel to a rod to which the revision connector is attached. A second plane which is non-parallel to that first plane allows a second or new rod to be received in the tulip and allows the second rod to pivot relative to the first rod.
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1. A spinal implant revision device comprising:
a revision connector for attachment to a pre-existing rod in a patient, the revision connector having a slotted opening configured to receive a first or a pre-existing rod; and
a tulip member pivotally connected to the revision connector and movable in angularity within predetermined ranges in a first plane, the first plane being parallel to a rod to which the revision connector is attached, the tulip configured to receive a second or new rod wherein the tulip member can rotate within the first plane in a predetermined angular range α− to α+, wherein the angular range of α− to α+ is between −15 degrees to 15 degrees wherein 0 degrees is parallel to a longitudinal axis of the pre-existing rod, the range of angles α− to α+ allows the second or new rod to be tilted either upwardly or downwardly relative to the first or pre-existing rod to permit installation at different levels relative to the spine, and wherein the tulip member has a lower rod receiving portion and an elongated detachable tower portion connected integral to the lower rod receiving portion by a breakaway groove positioned therebetween, the lower rod receiving portion of the tulip is formed as a second or new rod receiving slot or channel extending to a closed end, a pair of legs extend from the closed end defining the second or new rod receiving slot or channel to the breakaway groove, the elongated detachable tower portion has a pair of detachable leg extensions, one leg extension extending from the breakaway groove and aligned with one of the legs further extending the receiving slot or channel toward a proximal end wherein the second or new rod receiving slot or channel extends open through and between legs and leg extension to receive the second or new rod therethrough external of a patient and configured to deliver said rod internal an incision to the closed end of the tulip, and wherein the tulip has a side with a projection interposed between the connector and the inner surface of the connector, the projection fits into a complimentary truncated “V” shaped recessed slot configured to limit the angularity of the connector relative to the tulip within the predetermined range α− to α+ when the tulip and revision connector are assembled the tulip can pivot limited by the projection abutting sides of the truncated “V” shaped recessed slot.
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This invention relates to a surgical instrument useful in bone fixation procedures and methods of use thereof; and more particularly to a system and devices for percutaneously revising existing pedicle screw assemblies for adding additional levels without removal of the pre-existing implants.
There are many different approaches taken to alleviate or minimize severe spinal disorders. One surgical procedure commonly used is a spinal fusion technique. Spinal fusion is a standard back surgical technique and its use continues to rise. In addition to the spinal implants or use of bone grafts, spinal fusion surgery often utilizes spinal instrumentation or surgical hardware, such as pedicle screws, plates, or spinal rods. Once the spinal spacers and/or bone grafts have been inserted, a surgeon places the pedicle screws into a portion of the spinal vertebrae and attaches either rods or plates to the screws as a means for stabilization while the bones fuse.
While spinal fixation procedures can have positive outcomes, adjacent segment degeneration (ASD) often follows fusion surgeries. In addition to requiring the fusion of additional spinal segments, patients suffering from ASD often require posterior pedicle screw rod fixation. Such cases can be difficult for the surgeon as the surgical procedure often requires “opening” of the patient's back to expose the entire system in order for the surgeon to get to the top tulip. Such procedure is not beneficial to the patient as it exposes them to increased pain, higher morbidity, worsening of paraspinal muscle fibrosis/atrophy. Should the surgeon need to completely remove the old system, trying to remove an existing rod in order to provide a new construct can be technically difficult. Moreover, given the number of different spinal fixation systems in the market, knowing what system the patient contains and having the right tools to work on that system is a challenge.
There exists, therefore, a need for an improved devices and systems for extending a patient's existing fixation hardware which does not require open dissection, reduces the disruption of post tension bands, and can be used with any existing pedicle screw system in place.
A spinal implant revision device has a revision connector and a tulip member. The revision connector is configured for attachment to a pre-existing rod in a patient. The revision connector has a slotted opening configured to receive a first or a pre-existing rod. The tulip member is pivotally connected to the revision connector and movable in angularity within predetermined ranges in a first plane. This first plane is parallel to a rod to which the revision connector is attached. A second plane which is non-parallel to that first plane allows a second or new rod to be received in the tulip and allows the second rod to pivot relative to the first rod.
The spinal implant revision has the second plane lying transverse to the first rod and allows the second rod inside the tulip to move within a predetermined angle range θ to θ+ on assembly relative to the first or pre-existing rod. The angular movement is achieved by a two piece saddle. The angular range within the second plane is θ− to θ+ between −15 degrees and 15 degrees wherein 0 degrees is perpendicular to the first or pre-existing rod, the range of angles θ− to θ+ allows the new rod to be angled relative to the first or pre-existing rod inward or outward relative to the first or pre-existing rod to permit installation directionally within the second plane toward or away from a centerline of a spine. The spinal implant revision device allows the tulip to rotate within the first plane a predetermined angular range α− to α+. This rotation and angular range is limited by a truncated “V” shaped slot or recess in the revision connector and a protrusion on the tulip. The angular range of α− to α+ is between −15 degrees to 15 degrees wherein 0 degrees is parallel to a longitudinal axis of the pre-existing rod, the range of angles α− to α+ allows the second or new rod to be tilted either upwardly or downwardly relative to the first or pre-existing rod to permit installation at different levels relative to the spine.
The spinal implant revision wherein the tulip member has a lower rod receiving portion and an elongated tower portion connected integral to the lower rod receiving portion by a breakaway groove positioned therebetween. The lower rod receiving portion has a receiving slot or channel extending to a closed end, a pair of legs extend from the closed end defining the channel past a pair of breakaway grooves. A pair of detachable leg extensions has one leg extension extending from each of the breakaway grooves and aligned with a leg further extending the channel toward a proximal end. The leg extensions and the legs have internal threads to receive a compression screw for securing the second or new rod. At or near the proximal end of the leg extensions further has a pair of bridge connections spanning the respective channel connecting each leg extension.
The slotted opening or channel extends through and between legs and leg extension to receive a second or new rod therethrough external of a patient and configured to deliver said rod internal an incision to the closed end of the tulip inside the patient. The tulip has a projection configured to limit the angle of angular movement α− to α+ within a truncated “V” slot or recess on the revision connector. The projection extending between the tulip and the first connector member, the first connector member further comprises a slot to receive the projection and sized larger to permit the range of angularity α− to α+. The revision connector has a shaft extending outwardly for coupling to the tulip. The tulip has a first receiving hole for passing a shaft and a second receiving hole for engaging an end of the shaft. The end of the shaft has a chamfered cavity to receive a swedging tool to enlarge and flatten the end of the shaft to secure the connector and tulip as an assembly.
The revision connector has the slotted opening for receiving a first or pre-existing rod extends inwardly toward the tulip to a closed end. The first connector member has a threaded opening above the slotted opening to receive a threaded set screw with a convex or conical or frustoconical shaped tip, and wherein tightening the set screw directs the tip of the set screw to engage the first or pre-existing rod external surface outward of the rod's longitudinal axis as tightening of the set screw draws the first connector member closed end to move tightly against the first or pre-existing rod securing the first or pre-existing rod between the closed end and the tip of the set screw.
The invention will be described by way of example and with reference to the accompanying drawings in which:
With reference to
With reference to
As further shown in
As mentioned, the leg extensions 26, 28 extend upwardly from the breakaway grooves 29. During fabrication, it must be noted the leg extensions 26, 28 are actually weldments that are welded to a portion of the lower portion of the tulip 22 prior to the breakaway groove 29 being formed. This weldment line is shown as 23 in
With reference to
As further shown, when the upper saddle portion 34 is positioned below the rod 102 in the tulip 22 a set screw 30 can be driven down over the rod 102 in such a fashion that it secures the top of the rod 102 against and inside a “U” slot in the upper saddle portion 34 along the rods bottom “U” shaped surface of the lower saddle portion 36 and tightens against the shaft 16. This subsequently locks the rod 102 securely into the tulip 22. When both rods 101, 102 are tightened and secured fastened, the tulip 22 cannot move relative to the connector 12. This is similarly shown in
With reference to
In
With reference to
When such a rod 102 is passed through the channel 24 in the leg extensions 26, 28 of the tower, it is noted that the bridge 27 extending between each leg extension 26, 28 can allow a tool to pivot about it. In the present invention these bridges 27 are shown at the proximal end of the tower 20, however, they can be reduced and slightly submerged to provide better control of the tool upon assembly. However, it is important to have the bridges 27 because they provide rigidity of the tower 20 and insures the leg extensions 26, 28 do not inadvertently break prematurely during a surgical procedure. Ideally, the leg extensions 26, 28 are maintained in their position until the rod 102 is fully positioned into the lower portion of the tulip 22 at which time the set screw 30 can tighten the rod 102 onto the lower saddle portion 36 and upper saddle portion 34.
With reference to
With reference to
With reference to
As shown in
It must be appreciated that the angularity between the rod 101 and rod 102 can be made to virtually any inclination desired by the amount of rod 102 movement in the two piece saddle 34, 36 and the shaft 16 angle selected. Similarly the distance between the rods 101, 102 can be increased or decreased by changing the shaft 16 distance or length relative to the closed end of the slotted opening 15.
Variations in the present invention are possible in light of the description of it provided herein. While certain representative embodiments and details have been shown for the purpose of illustrating the subject invention, it will be apparent to those skilled in this art that various changes and modifications can be made therein without departing from the scope of the subject invention. It is, therefore, to be understood that changes can be made in the particular embodiments described, which will be within the full intended scope of the invention as defined by the following appended claims.
Whipple, Dale, Tillett, Jason Hayes, Tally, William C., Khajavi, Kaveh, Toon, Geoffrey
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