RU154118U1 - TRANSPEDICULAR POLYAXIAL SCREW DEVICE - Google Patents

Abstract

1. The device is a transpedicular polyaxial screw, comprising a screw, a head, an insert, a lock nut, the screw having a working part with thread on one end and a spherical thickening on the other end and installed in the head having a through hole with an internal rectangular stop thread and a groove with a width that allows you to install a longitudinal rod in it, and the screw has the ability to rotate relative to the head with a total deflection angle in the radial position of up to 55 degrees, and in its spherical thickening contains an element allowing you to create a torque relative to the axis of the screw, an insert is installed in the head that prevents the screw from falling out of the head and having on one side a spherical surface corresponding to a spherical thickening of the screw, on the other hand a groove with the possibility of installing a longitudinal shaft, and from sides in contact with the inner part of the head are two opposed blind holes, moreover, the other two blind holes are located on the same axis with these holes in the head, and the lock nut contains an external straight clay thrust thread corresponding to the internal thread on the head and an element that allows you to apply a torque to screw the lock nut into the head, characterized in that at the end of the lock nut, which can come in contact with the longitudinal shaft, an annular rib is made, the thread profile of the working part of the screw is variable and is an isosceles trapezoid, and the base of the trapezoid is reduced from a spherical thickening to its tip, while the outer diameter of the working part of the screw is constant, and the inner mind

Description

The utility model relates to medicine, namely to vertebrology, neurosurgery, orthopedics, traumatology, in particular to the field of creation of transpedicular polyaxial screws and lock nuts, which are part of spinal fixation devices and are used to stabilize deformities, traumatic injuries of the spine, as well as instability various etiologies in the thoracic, lumbar and sacral parts.

Known polyaxial transpedicular screw (patent US 6.660.004, A611317 / 70 dated 12/09/2003), containing the actual transpedicular screw having a threaded part on one side and a spherical thickening on the other hand, a head having a through hole with a thread and a groove with the possibility of installation into it a longitudinal rod, two inserts installed in the head and preventing the screw from falling out of the head and a lock nut that is screwed into the head and fixes the longitudinal rod.

The disadvantage of this device is the low degree of fixation of the longitudinal rod, the possibility of spontaneous unscrewing of the nut and hence the weakening of the fixation of the longitudinal rod.

The closest technical analogue, that is, the prototype, is a polyaxial transpedicular screw (patent US 6869433, A61B 17/70 of 03.22.2005), containing the transpedicular screw itself, having a threaded part on one side and a spherical thickening on the other hand, a head having a through hole with a thread and a groove with the possibility of installing a longitudinal rod into it, an insert having a spherical surface on one side and preventing the screw from falling out of the head, and two nuts that are screwed in and out into the th DCCH and fix longitudinal rod.

The disadvantage of this device is the low degree of fixation of the longitudinal rod, the possibility of spontaneous unscrewing of the nut and hence the weakening of the fixation of the longitudinal rod, the complexity of installation, due to the large number of parts and hence the increased risk of tissue injury.

The essence of the utility model lies in the fact that the device of the transpedicular polyaxial screw contains the actual screw, head, insert and lock nut. The screw has a working part with a thread at one end and a spherical thickening at the other end and is installed in the head, having a through hole with an internal rectangular thrust thread and a groove with a width that allows you to install a longitudinal shaft into it. In this case, the screw has the ability to rotate relative to the head with a total deflection angle in the radial position of up to 55 degrees, and in its spherical thickening contains an element that allows you to create torque relative to the axis of the screw. This element can be an internal hexagon or torx, which is a six-pointed star. An insert is installed in the head that prevents the screw from falling out of the head and having on one side a spherical surface corresponding to a spherical thickening of the screw, on the other hand a groove with the possibility of installing a longitudinal rod, and on the sides in contact with the inside of the head there are two opposite blind holes, moreover, on the same axis with these holes in the head are the other two blind holes. The insert is fixed relative to the head due to the fact that the influx of the metal of the head enters the two opposite holes of the insert when the load is applied with a special tool through two opposite holes in the head. The lock nut contains an external rectangular thrust thread corresponding to the internal thread on the head and an element that allows you to apply torque to screw the nut into the head. As such an element, a “camomile” type hole can be used, which is a central hole and six grooves around its perimeter with the same interval between them, or a torx representing a six-pointed star. The profile angle of the external stop thread of the lock nut and the internal thread in the head can be 90 ° and a pitch of 1.25 mm. An annular rib is made at the end of the lock nut, which may come in contact with the longitudinal rod. For a better fit of the annular rib to the longitudinal shaft and better blocking of the rod in the head, the surface roughness of the ring rib can be made two classes lower than the roughness of the remaining surfaces of the locking nut, and the ring rib can have an angle of 90 °. The thread profile of the working part of the screw is variable and is an isosceles trapezoid, and the base of the trapezoid is reduced from the spherical thickening of the screw to its tip. The angles of the isosceles trapezoid of the thread profile of the working part of the screw can be 10 ° and 40 °. The thread profile of the working part of the screw can vary from a trapezoidal screw at a spherical thickening to a triangular screw at its tip. The outer diameter of the working part of the screw is constant, and the inner decreases from head to tip. The possible thread pitch sizes of the screw working part can be 2.5 mm, with the outer diameter of the screw working part within 4.5-5.5 mm, and in the case of the outer diameter of the screw working part within 6.0-7.5 mm threads of the working part of the screw can be 3.0 mm. An annular trapezoidal groove and four ledges are made on the head.

All parts of the transpedicular polyaxial screw device are made of biocompatible titanium alloy. The design of the transpedicular polyaxial screw device allows to obtain a new technical result, which consists in increasing the reliability of fixing the longitudinal rods, which is provided by increasing the contact area of the elements of the locking nut with the surface of the longitudinal rods and creating the geometry of the external thread of the locking nut and the internal thread on the screw head, which guarantees the impossibility of spontaneously unscrewing the lock nut and loosening the fixation of the longitudinal rods. Ease of installation of the transpedicular polyaxial screw device and its increased strength are ensured by changing the spatial and geometric characteristics of the screw working part in comparison with analogues. The device provides the surgeon with intraoperative planning flexibility depending on the clinical situation.

The transpedicular polyaxial screw device is an integral part of spinal fixation devices and works as follows. Screws containing threads are screwed into the vertebrae requiring fixation. For screwing, a special tool is used, which is included in the internal hexagon or torx, located in the spherical thickening of the screw. In the screw heads located on different vertebrae, longitudinal cylindrical rods are installed, which are fixed using lock nuts with an external stop thread. Installing the locking nuts is carried out using a wrench, which is included in the nut element, allowing you to perform twisting and creating torque, providing rigidity. As such an element, a “camomile” type hole can be used, which is a central hole and six grooves around its perimeter with the same interval between them, or a torx representing a six-pointed star. When screwing the lock nut, the head is fixed with a special tool, which is included in four ledges on the head. An annular rib at the end of the nut provides reliable fixation of the longitudinal rods.

In FIG. 1 shows an assembly of a transpedicular polyaxial screw assembly (longitudinal section), FIG. 2 shows a polyaxial screw; FIG. 3 shows the element “A” - a fragment of the thread of the working part of the transpedicular polyaxial screw, in FIG. 4 shows a head in a perspective view; FIG. 5 shows a head in cross section, FIG. 6 shows a lock nut (in cross section), FIG. 7 is a top view of a lock nut; FIG. 8 shows an insert (half an insert in cross section), FIG. 9 - spherical thickening of the screw in a perspective view.

The transpedicular polyaxial screw device comprises a screw 1, a head 2, an insert 3, and a lock nut 4. The screw 1 has a working part with a thread 5 at one end and a spherical thickening 6 at the other end and is mounted in the head 2 having a through hole 7 with an inner rectangular threaded thread 8 and a groove 9 with a width that allows you to install a longitudinal rod 10. The roughness of the spherical thickening 6 can be two classes lower than the roughness of the remaining surfaces of the device. In this case, the screw 1 can be rotated relative to the head 2 with a total deflection angle in the radial position of up to 55 degrees, and in its spherical bulge 6 contains an element 11, which allows to create a torque relative to the axis of the screw. This element 11 may be an internal hexagon or torx, in the form of a six-pointed star. An insert 3 is installed in the head 2, preventing the screw 1 from falling out of the head 2 and having, on the one hand, a spherical surface 12 corresponding to a spherical thickening 6 of the screw 1, on the other hand, a groove 13 with the possibility of installing a longitudinal shaft 10, and from the sides in contact with the inner part of the head 2 is two opposed blind holes 14, and the other two blind holes 15 are located on the same axis with these holes in the head 15. The insert 3 is fixed relative to the head due to the fact that The heads of head 2 enter two opposing holes of insert 14 when a special tool is applied through two opposing holes 15 in head 2. The locking nut 4 contains an external rectangular stop thread 16 corresponding to internal thread 8 on head 2 and an element 17 that allows applying torque for screwing the locking nut 4 into the head 2. As such an element 17, a “camomile” type hole can be used, which is a central hole 18 and six grooves 19 along its perimeter with the same interval between them or torx in the form of a six-pointed star. The profile angle of the external threaded thread 16 of the locking nut 4 and the internal thread 8 in the head 2 can be 90 °, and the pitch is 1.25 mm. At the end of the locking nut 4, which may be in contact with the longitudinal rod 10, an annular rib 20 is made. For a better fit of the annular rib 20 to the longitudinal rod 10 and a better locking of the rod 10 in the head 2, the surface roughness of the annular rib 20 can be made two classes lower, than the roughness of the remaining surfaces of the lock nut 4, and the annular rib 20 may have an angle of 90 °. The thread profile of the working part 5 of the screw 1 is variable and is an isosceles trapezoid 21, and the bases of the trapezoid 21 are reduced from a spherical thickening 6 of the screw 1 to its tip 22. The angles of the isosceles trapezoid 21 of the thread profile of the working part 5 of the screw 1 can be 10 ° and 40 °. The thread profile of the working part 5 of the screw 1 can vary from a trapezoidal screw at a spherical thickening 6 of the screw 1 to a triangular one at its tip 22. The outer diameter of the working part 5 of the screw 1 is constant, and the inner diameter decreases from a spherical thickening of 6 to the tip 22. Possible thread pitch of the working part 5 screws 1 can be 2.5 mm, with the outer diameter of the working part 5 of screw 1 within 4.5-5.5 mm, and in the case of the outer diameter of the working part 5 of screw 1 within 6.0-7.5 mm, pitch threads of the working part of the screw can be 3.0 mm. An annular trapezoidal groove 23 and four ledges 24 are made on the head 2.

Experimental testing of the proposed technical solution showed the high strength of the transpedicular polyaxial screw device and the reliability of fixing the longitudinal shaft, which is achieved by increasing the contact area of the nut elements with the surface of the longitudinal shaft. The geometric parameters of the external thread of the nut and internal thread on the screw head guarantee the impossibility of spontaneous unscrewing of the nut and loosening the fixation of the longitudinal rods.

Good results were obtained when testing for pulling out a transpedicular polyaxial screw from the vertebral body. The ability of the screw to stay in the vertebral body when exposed to a force directed to pulling out exceeds the ability of analog screws.

Claims (12)

1. The device is a transpedicular polyaxial screw, comprising a screw, a head, an insert, a lock nut, the screw having a working part with thread on one end and a spherical thickening on the other end and installed in the head having a through hole with an internal rectangular stop thread and a groove with a width that allows you to install a longitudinal rod in it, and the screw has the ability to rotate relative to the head with a total deflection angle in the radial position of up to 55 degrees, and in its spherical thickening contains an element allowing you to create a torque relative to the axis of the screw, an insert is installed in the head that prevents the screw from falling out of the head and having on one side a spherical surface corresponding to a spherical thickening of the screw, on the other hand a groove with the possibility of installing a longitudinal shaft, and from sides in contact with the inner part of the head are two opposed blind holes, moreover, the other two blind holes are located on the same axis with these holes in the head, and the lock nut contains an external straight a thrust resistant thread corresponding to an internal thread on the head and an element allowing to apply a torque to screw the lock nut into the head, characterized in that an annular rib is made at the end of the lock nut, which may come into contact with the longitudinal shaft, the thread profile of the screw working part is variable and is an isosceles trapezoid, and the base of the trapezium is reduced from a spherical thickening to its tip, while the outer diameter of the working part of the screw is constant, and the inner mind shaetsya from a spherical thickening towards the tip, and the head an annular trapezoidal groove. 2. The transpedicular polyaxial screw device according to claim 1, characterized in that four ledges are made on the head. 3. The transpedicular polyaxial screw device according to claim 1, characterized in that the annular rib at the end of the lock nut has an angle of 90 °. 4. The transpedicular polyaxial screw device according to claim 1, characterized in that the surface roughness of the annular rib at the end of the locking nut, on the spherical thickening on the screw, the spherical surface of the insert is two classes lower than the roughness of the remaining surfaces of the transpedicular polyaxial screw device. 5. The device of the transpedicular polyaxial screw according to claim 1, characterized in that the angles of the isosceles trapezoid of the thread profile of the working part of the screw are 10 ° and 40 °. 6. The transpedicular polyaxial screw device according to claim 1, characterized in that the profile angle of the external threaded thread of the lock nut and the internal thread in the screw head is 90 °. 7. The transpedicular polyaxial screw device according to claim 1, characterized in that the thread pitch of the working part of the screw is 2.5 mm, with the outer diameter of the working part of the screw 4.5-5.5 mm. 8. The device of the transpedicular polyaxial screw according to claim 1, characterized in that the thread pitch of the working part of the screw is 3.0 mm, with the outer diameter of the working part of the screw 6.0-7.5 mm. 9. The transpedicular polyaxial screw device according to claim 1, characterized in that the element that allows you to apply torque to screw the lock nut into the head is a central hole and six grooves along its perimeter with the same interval between them. 10. The device of the transpedicular polyaxial screw according to claim 1, characterized in that the element contained in the spherical thickening of the screw and allowing you to create torque relative to the axis of the screw, is an internal hexagon. 11. The transpedicular polyaxial screw device according to claim 1, characterized in that the element that allows you to apply torque to screw the lock nut into the head is a torx in the form of a six-pointed star. 12. The device of the transpedicular polyaxial screw according to claim 1, characterized in that the element contained in the spherical thickening of the screw and allowing you to create torque relative to the axis of the screw, is a torx in the form of a six-pointed star.

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