POSTERIOR FUSION SYSTEM OF PEDICLE SCREW-ROD-CONNECTOR
TERMS TO BE USED
Human Spine (H.S.), implant-pedicle screw, joint, divisible rod, helical spring
TECHNICAL FIELD
The posterior fusion systems are generally used in the stabilization of the Human Spine, in f actures, degenerative spine diseases, and deformities that cause various functional, neurological problems, etc. The materials are screws that pass through the vertebrae's pedicles, two per vertebra and are connected to one another onto a rod with the use of a joint. These three elements, that is the screw, the rod or plate, and the joint which connects them combined with the specific properties that they have due to their design, which differs from system to system, also characterize the ability of each system that is in use nowadays to be easily positioned, while correcting, reducing, and at the same time retaining such mechanical and bio-mechanical properties after its application, increasing the material's endurance to breaking and fatigue, or reducing as much as possible failure danger due to screws' loosening and migration (pull out).
PREVIOUS TECHNIQUE'S LEVEL
Today there exist various screws and joints that connect them to rods or plates hence creating a short or longer construction, depending on the situation and the stabilization need that is demanded. In almost all systems that exist, the rods used are of the same diameter, usually of 6 mm and onto them slip the joints that are designed in such a way so that they easily sit on the screw's threaded upper section, and then are secured with a nut, allowing the creation of a construction of whatever length, that may start f om the first thoracic vertebrae and end up low to the sacral bone. Hence, it stabilizes the H.S. to all its length. There is no positioning or application difficulty in
short constructions. However, the longer the construction the more difficulties may occur especially in their assembly, either due to the fact that the screws are not in the same straight line that is they are in different distances from the rod but they also form different angles on the sagital and transverse axis, the joint's hole doesn't always sit on the screw's threaded upper part and exercise of force is necessary. In order to solve this difficulty and succeed to the construction's assembly without tension, screws whose head can move by 10 or 15 degrees towards any direction of 360 degrees have been designed, or joints that also have double movement both towards the rod and the screw too. Although this technique solves most of the problems, in lots of cases and mostly in heavy deformity, kyfosis, scoliosis, and angle formation due to trauma etc., the abilities of these techniques are not enough and further bending of the rod is demanded at the points where the rod's joint does not come close enough to the screw in the correct way. Such points are the peaks of the convex or the ends of the construction. The rod is pre-bent so that it follows the proportional convexities of H.S., before its application, but it is also bent afterwards, after assembly on the H.S. in order to achieve the corrections that we want, such as derotation of scoliosis, reduction (elevation) etc. These operations result in assembling the whole construction under tension, although care is taken in order to avoid the appearance of these forces because they are the main cause of the material's failure, either due to breakage due to fatigue, or due to the implanted screws' loosening inside the bone. In order to avoid the phenomenon of loosening, screws with bio-mechanical properties have been designed so that they promote osteogenesis since they are covered with porous titanium and are of conical shape etc, and instead of a metallic rod of 6 mm that connects them, 2 thinner ones that offer elasticity are used or a rod made of polyurethane.
ADVANTAGES OF THE NEW TECHNIQUE
The new technique is based on improvements of the biomechanical behavior of the points that used to be the main cause of total or partial failure of the fusion's materials. The screw has been designed so that on the one hand it is not as rigid as in all other systems and on the other hand it functions with implant's characteristics. Hence, it is fully embodied in the bone where it is implanted. Its body's elasticity
allows the absorption of the vibration loads that are responsible either for the fatigue and breakage or for the screw's loosening in the implantation site, since micro- movements can smoothen and destroy the walls (threads) of the bone's hole where it is screwed. The screw's design with a hollow front section and S shaped helical spring, which rotates itself at 180 degrees anti-clock wise, to all its length, pushing in its interior, the pieces of bone that it cuts into when it is being screwed clockwise, fills the internal section of the threads with the same bone where it is being implanted. This significantly reduces the demanded time for osteogenesis and its attachment on its touch points.
On the contrary, all solid screws during screwing, push and put aside the bone perimetrically, without embodying it in their interior, which does not allow the communication among its diametrically opposite sections, that's why screws of this type, contrary to ours, are not characterized as implants. This combined with the exercise of loading forces or even due to permanent tension of the construction's application in some cases, results in partial or total failure with loosening or breakage.
The connection of the screw to the rod is performed in whichever position without any tension because the rod is not solid, but divisible, thanks to the joint's mechanism which before tightening the nut allows movement towards all directions. Depending on the number of vertebrae we wish to fuse, we add the demanded rods, one after the other, easily by opening the joint which accepts the spherical end of the rod in its two reception points, thus increasing the construction's length while tying the screws without demanding application of force or tension and contrary to the existing technique which in most cases demands the rod's bending so that the joint will be attached to the screw.
Our system has an advantage after implantation and positioning of the whole construction compared to the existing technique, when after the assembly we perform corrective maneuvers in order to bring the H.S. back to its normal height, correct kyfosis-angle formation, or derotate the scoliosis. The divisible rod is a very important advantage especially in cases where we have to tie many vertebrae, making long constructions, since step by step and trough exercise of minimal force we succeed in gradual correction, contrary to the previous technique that is based on the
pre-bent rod, which demands great force to be exercised hence causing the screw to be pulled out of position or breaking of the bone (pedicle).
DESCRIPTION
In a few words the figures represent the stages as follows:
Fig. 1 shows the screw with the thread of different design. Fig. 2 shows the internal helical spring of the screw in a vertical cut, together with part of the thread. Fig. 3 shows the lower hollow end of the screw. Fig. 4 shows the rod with the two elliptic spheres on its edges. Fig. 5 shows the joint open and fig. 6, shows it closed having engulfed the two ball-shaped ends inside the special upper and lower cavities of the rod. Fig. 7 shows the screw tied to the rods and the nut secured. Fig. 8 shows the whole construction in position. Fig. 13 shows the helical internal spring 10 along the screw.
It is about a posterior Lumbar fusion system which consists of screw-implant, rod, and joint with the following characteristics:
The screw fig. 1 is hollow on its end while it is of oblique and sharp end fig. 3, so that it cuts easily through the bone. While it is clockwise advanced with the screwdriver, the cut bone is gathered by the anti-clockwise 180 degrees helical spring 10 fig. 2, which starts after point 11, fig.l, continues up to the screw's head 12 fig. 1 and forms its internal structure, which is complemented by the perimetrical threads 13, that create two cavities, rotated around themselves at 180 degrees anti-clock wise, to all the length of the helical spring, 20 and 21 fig. 2. The threads 13 fig. 1 lean and are attached on the helical spring. The screw's body can be seen on fig. 2, where the spring's 10 structure consisting from nucleus 22 is also visible on fig. 2, together with the two wings of opposite direction 24 that have anti-clockwise orientation, so that
they help in forwarding the bone towards the upper section of the screw. Compartments (cavities) 21 and 22 fig. 2 that are created from the 180 degrees rotation of the spring 10, which is also the body of the screw, in the space and from the two tangent threads. Thus the screw's body is not solid but helical and with the threads, on its perimeter, creates the two compartments 21 and 22 fig. 2 that are filled with cut bone that was cut from the front part of the screw after the final screwing, and communicate directly towards all directions perimetrically to the screw with the neighboring bone tissue of the pedicle and the vertebra towards 360 degrees. This creates the best possible conditions for the incorporation of the screw and ossification and makes it differ from the solid ones that exist nowadays, so that it can be characterized as screw-implant. For the connection of the screw to the rods, a joint fig.5 is used, open fig.9 and closed fig. 6 which accepts the spherical ends of the rods, which (joint) that carries mechanism 26 fig. 9 on one of its sides so that it can open and close. The threaded stem of screw 14 fig. 7, passes through the joint's hole 15 fig.5 and then we close the joint having previously placed in cavities 17, the spherical heads of the construction's two rods, in such a way so that notch 16, sits on the stem 14, on whose end we screw nut 19 in order to secure the connection as can be seen on fig. 7. On fig. 10 the rod's head 40 can be seen, it is placed on the two ends of the construction on the external side of the reception 17 fig. 5, unless a transverse bridge 44 fig. 11 is needed to be placed for better support and stability in rotational forces. The joint's hole 15 fig. 5, is not round but oblong, so that we can tighten the screw on either side, in order to correct if needed and regain the gap's lost height, through increasing or decreasing the distance between the two screws and through the selecting a rod of an appropriate length.
EXAMPLE
On a patient with compression fracture of the body of the 3rd Lumbar vertebra, which results in loss of height, we insert the screws of fig. 1 in the pedicles of L2, L4, L5, on both sides of the injured vertebral body, having previously catheterized them with a thin drill, keeping in mind the differences of the angles that exist proportionally to the vertebra's height, on sagittal and transverse axis, in order to avoid injuring the root or the spinal channel. We then place the rods having chosen the appropriate length so
that their spherical ends sit on the receptions of the joints, so that when we close the joint the hole 15 fig. 5 accepts first the stem of the screw 14, fig. 7 onto which the nut 19 will be secured without being tightened. On the two ends of our construction, that is on L2 on its upper and the lower section of L5 we place a spherical head 40, fig. 10, so that there is symmetry of exercise of force during the nut's tightening.
Having placed the construction assembled but keeping nuts 19 loose and before the final tightening, we can attempt easy reduction of the kyfosis and restoration of the height of the inter- ertebral space back to normal by exercising force on all three axes of space. The oblong shape of the joint's 15 hole, allows correction, increase or reduction of the neighboring screws' in-between distance up to 2.5 cm, which allows the easy elevation of the space's height.
After the final tightening of nuts, we move on stitching and closing the trauma.