RU163628U1 - TRANSPEDICULAR POLIAXIAL SCREW - Google Patents

Abstract

1. A transpedicular polyaxial screw comprising a screw shaft and a head, the screw shaft being made at one end with a thread on the working part, and at the other end with a spherical bulge that is installed in the head, the head is made with a through hole and can be installed in the upper part a through hole having an internal threaded thread, a locking screw, and a groove with the possibility of inserting a longitudinal rod into it, the thread profile of the working part of the screw rod is variable and is an isosceles apecia, and the trapezoid base decreases from a spherical thickening of the screw shaft to its tip, the outer diameter of the working part of the screw shaft is constant, and the inner diameter decreases from a spherical thickening to the tip with the formation of a cone-shaped core, the screw shaft can rotate relative to the head, and its spherical thickening contains an element that allows you to create a torque relative to the axis of the screw shaft, characterized in that the conical core of the screw shaft is made with the formation of two parts different tapers with the transition of one part to another and with a decrease in the angle of inclination of the generatrix of the cone of the end part of the conical core of the screw shaft, while at least the first thread turn is made from the tip of the screw shaft with a recess forming a chip groove with cutting edges, and spherical thickening of the screw shaft is notched. 2. The transpedicular polyaxial screw according to claim 1, characterized in that the element that allows you to create a torque relative to the axis of the screw shaft is at least four grooves, symmet

Description

The utility model relates to medicine and can be used in neurosurgery, orthopedics, traumatology, vertebrology, in particular, in the field of creating systems for correction and fixation of the spine.

Known transpedicular polyaxial screw, which is a screw shaft and a head. The screw rod is made at one end with a thread on the working part, and at the other end with a spherical thickening, which is installed in the head. The screw shaft is rotatable relative to the head. The head is made with a through hole having an internal stop thread in the upper part for installation in the upper part of the head of the locking screw, and with a groove for installing a longitudinal shaft in it (US patent 6488681, АВВ 17/70 dated 05/01/2001).

The disadvantage of this device is the possibility of weakening the longitudinal rod, and, therefore, unsatisfactory stability of fixation of the damaged segment of the spine.

Closest to the technical nature of the claimed (device) is a transpedicular polyaxial screw device containing a screw (screw shaft), head, insert, lock nut (locking screw). The screw (screw shaft) has a working part with a thread on one end and a spherical thickening on 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 in it. The screw (screw shaft) 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 bulge contains an element that allows you to create torque relative to the axis of the screw shaft. An insert is installed in the head to prevent the screw (screw shaft) from falling out of the head and having on one side a spherical surface corresponding to a spherical thickening of the screw (screw shaft), on the other hand, a groove with the possibility of installing a longitudinal shaft, and from the sides in contact with the inner part of the head is two opposed blind holes, with the other two blind holes located on the same axis as these holes in the head. The locking nut (locking screw) 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 locking nut (locking screw) into the head. At the end of the locking nut (locking screw), which can be in contact with the longitudinal shaft, an annular rib is made, the thread profile of the working part of the screw (screw shaft) is variable and is an isosceles trapezium, and the trapezium bases decrease from a spherical thickening to its tip, while the outer diameter of the working part of the screw (screw shaft) is constant, and the inner diameter decreases from a spherical thickening to the tip. An annular trapezoidal groove is made on the head (RF patent for utility model 154118, АВВ 17/70 dated 11/13/2014, published: 08/20/2015).

The disadvantage of this device is the large number of parts, the possibility of weakening the longitudinal rod, and, therefore, the poor stability of fixation of the damaged segment of the spine.

The objective of the utility model is to develop a transpedicular polyaxial screw of simple design for stable fixation of the damaged segment of the spine.

The technical result of the utility model is to ensure stable fixation of the damaged segment of the spine.

The claimed technical result is achieved by the fact that in the inventive device containing the screw shaft and the head, the screw shaft is made at one end with a thread on the working part, and at the other end with a spherical thickening that is installed in the head, the head is made with a through hole and with the possibility installation in the upper part of the hole having an internal threaded thread, a locking screw, and a groove with the possibility of inserting a longitudinal rod into it, the thread profile of the working part of the screw rod is variable and represents non-isosceles trapezoid, and the trapezoid base decreases from a spherical thickening of the screw shaft to its tip, the outer diameter of the working part of the screw shaft is constant, and the inner diameter decreases from a spherical thickening to the tip with the formation of a cone-shaped core, the screw shaft can rotate relative to the head, and its spherical thickening contains an element that allows you to create a torque relative to the axis of the screw shaft, according to a utility model, the conical core of the screw shaft is made with the formation of two parts of different tapers with the transition of one part to another and with a decrease in the angle of inclination of the generatrix of the cone of the end part of the cone-shaped core of the screw shaft, while at least the first thread turn is made from the tip of the screw shaft with a recess forming a chip groove with cutting edges and a notch is made on a spherical thickening of the screw shaft.

The element that allows you to create torque relative to the axis of the screw shaft is a four grooves symmetrically located on the spherical thickening of the screw shaft.

The notch on the spherical thickening of the screw shaft can be made in the form of a concentric cut or in the form of a spiral cut.

The angles of the isosceles trapezoid of the thread profile of the working part of the screw shaft are 5 ° and 40 °.

Performing a cone-shaped core of the screw shaft with the formation of two parts of different tapers with the transition of one part to another and with a decrease in the angle of inclination of the generatrix of the cone of the end part of the screw-shaped core of the screw, while at least the first thread turn is made from the tip of the screw shaft with a recess , forming a chip groove with cutting edges, makes it possible, thanks to the design features of the working part of the screw shaft, to reduce the risk of breakage of the screw shaft and allows you to install transpedicular ny polyaxial screw in different density bone vertebra, in particular in compact vertebral bone legs even with reduced bone mineral density, which ensures the stability of its position. In addition, the bone chips generated during screwing in the screw shaft compresses the bone tissue around the screw shaft and helps maintain its stability.

In addition, due to the fact that one of the angles of an isosceles trapezoid of the thread profile of the working part of the screw shaft is 5 °, conditions are created that prevent the spontaneous unscrewing of the transpedicular polyaxial screw, which increases its resistance to the force acting on pulling it out of the bone. As a result, the transpedicular polyaxial screw is firmly held in the bone tissue of the vertebra, thus ensuring the stability of its location in the bone tissue of the vertebra and ensures stability of fixation of the damaged segment of the spine.

Performing a notch on a spherical thickening of the screw rod in the place of its conjugation with the longitudinal rod in the form of a concentric or in the form of a spiral cut increases the adhesion force of the surfaces of the spherical thickening of the screw rod and the longitudinal rod, which allows reliable locking of the longitudinal rod in the head.

Thus, in general, the fixation stability of the damaged segment of the spine is ensured.

No technical solutions matching the totality of essential features of the utility model have been identified, which allows us to conclude that the utility model meets the patentability criterion of “novelty”.

The patentability condition "industrial applicability" confirms an example of a specific application of the inventive device.

The inventive utility model is illustrated by drawings.

The figure 1 presents the transpedicular polyaxial screw in a perspective view.

The figure 2 presents a schematic representation of the conical core of the screw shaft, which is made with the formation of two parts of different tapers.

The figure 3 presents the transpedicular polyaxial screw assembly with a locking screw and a longitudinal shaft.

The figure 4 presents the locking screw in cross section

The figure 5 presents the locking screw (top view) with an orienting notch.

The transpedicular polyaxial screw contains a screw shaft 1 and a head 2. A screw shaft 1 is made at one end with a thread 3 on the working part, and at the other end with a spherical thickening 4. The head 2 is made with a through hole 5, with the possibility of installation in the upper part of the through holes 5, having an internal threaded thread 6, a locking screw 7. In the lower part of the through hole 5, a spherical thickening 4 of the shaft of the screw 1 is placed and a groove 8 is made for installing a longitudinal shaft 9 in it.

The spherical thickening 4 of the screw rod 1 at the point of contact with the longitudinal rod 9 is made with a notch 10. The notch 10 can be made in the form of a concentric or spiral thread.

The thread profile 3 of the working part of the shaft of the screw 1 is variable and is an isosceles trapezoid 11, while the bases of the trapezoid 11 are reduced from the spherical thickening 4 of the shaft of the screw 1 to its tip 1 2. In particular, the profile of the thread 3 of the working part of the shaft of the screw 1 changes from trapezoidal spherical thickening 4 to triangular near the tip 12. The angles 13.1 and 13.2 of the isosceles trapezoid 11 of the thread profile 3 of the working part of the shaft of the screw 1, in particular, are 5 ° and 40 °. At least the first turn of the thread 3 from the tip of the screw shaft 12 is made with a recess 14 forming a chip groove with cutting edges.

The outer diameter of the working part of the shaft of the screw 1 is constant, and the inner diameter decreases from a spherical thickening 4 to the tip 12 with the formation of a cone-shaped core 15 of the shaft of the screw 1. In this case, the cone-shaped core 15 of the shaft of the screw 1 is made with the formation of two parts 15.1 and 15.2 of different taper with the transition of one part 15.1 to another 15.2 and with a decrease in the angle of inclination of the generatrix of the cone of the end part 15.2 of the cone-shaped core 15 of the shaft of the screw 1. The shaft of the screw 1 can rotate relative to the head 2, and its spherical thickening 4 contains an element 16 that allows you to create a torque relative to the axis of the shaft of the screw 1. In particular, the element 16 that allows you to create a torque relative to the axis of the shaft of the screw 1, consists of four grooves 16.1, 16.2, 16.3 and 16.4, symmetrically located on the spherical thickening 4 of the screw shaft one.

The locking screw 7 is made with an external thread 17, corresponding to the internal threaded thread 6 in the upper part of the through hole 5, and with an element 18 that allows you to apply a torque to screw the locking screw 7 into the head 2. The element 18 is an internal hexagon, and on the upper plane locking screw 7 made orienting notch 19.

The predominant embodiment of the transpedicular polyaxial screw involves its execution with a thread pitch 3 of the working part of the screw 1 of the screw 1 equal to 2.5 mm with an outer diameter of the working part of the screw 1 of the screw within 4.5-5.5 mm, and with a thread pitch 3 of the working part of the screw 1 1 equal to 3.0 mm with the outer diameter of the working part of the shaft of the screw 1 in the range of 6.5-7.5 mm.

The predominant embodiment of the shaft of the screw 1 involves the execution of it with a conical core with the formation of two parts 15.1 and 15.2 with a ratio of the lengths of the parts, respectively, as 1: 2.

The transpedicular polyaxial screw is made of a biocompatible titanium alloy and color-anodized to enhance bone compatibility. In addition, using color anodization, the transpedicular polyaxial screw is marked in diameter, namely, the transpedicular polyaxial screw with an outer diameter of 4.5 mm. has a golden color, transpedicular polyaxial screw with an outer diameter of 5.5 mm. has a blue color, transpedicular polyaxial screw with an outer diameter of 6.5 mm. has a pink color, and a transpedicular polyaxial screw with an outer diameter of 7.5 mm. has a green color.

The transpedicular polyaxial screw is an integral part of spinal fixation devices and is installed (mounted) as follows.

The vertebrae located in close proximity to the vertebrae requiring fixation are screwed with transpedicular polyaxial screws of the claimed design.

Installed transpedicular polyaxial screw, due to the thread profile 3 of the working part of the shaft of the screw 1 and the execution of the shaft of the screw 1 with a conical core with the formation of two parts 15.1 and 15.2 of different taper with the transition of one part to another and with a decrease in the angle of inclination of the forming cone of the end part 15.2 of the conical core of the rod screw 1, despite the fact that at least the first turn of thread 3 from the tip of the screw shaft 1 is made with a recess 14 forming a chip groove with cutting edges, this reduces the risk of breakage terzhnya screw 1 and provides equally strong fixation it both in the compact bone of the vertebral legs and in the cancellous bone of the vertebral body. This embodiment of the screw shaft 1 greatly facilitates the insertion of a transpedicular polyaxial screw into the bone tissue of the vertebra and allows maintaining the stability of its position in the vertebral body.

Next, in the grooves 8 made in the heads 2 of the transpedicular polyaxial screws, cylindrical longitudinal rods 9 are installed, which are then fixed with the help of locking screws 7. At the same time, the alignment screw 19 facilitates the installation of the locking screw on the upper plane of the locking screw 7 during installation (installation ) spinal fixation devices.

The mounted device for fixing the spine, a component of which is the device of the transpedicular polyaxial screw, due to the constructive implementation of its components, maintains a stable position during its use, thus ensuring reliable fixation of the vertebrae in case of injuries and diseases of the spine.

This design of the transpedicular polyaxial screw increases the availability of high-tech surgical care for injuries and diseases of the spine.

Claims (5)

1. A transpedicular polyaxial screw comprising a screw shaft and a head, the screw shaft being made at one end with a thread on the working part, and at the other end with a spherical bulge that is installed in the head, the head is made with a through hole and can be installed in the upper part a through hole having an internal threaded thread, a locking screw, and a groove with the possibility of inserting a longitudinal rod into it, the thread profile of the working part of the screw rod is variable and is an isosceles apecia, and the trapezoid base decreases from a spherical thickening of the screw shaft to its tip, the outer diameter of the working part of the screw shaft is constant, and the inner diameter decreases from a spherical thickening to the tip with the formation of a cone-shaped core, the screw shaft can rotate relative to the head, and its spherical thickening contains an element that allows you to create a torque relative to the axis of the screw shaft, characterized in that the conical core of the screw shaft is made with the formation of two parts different tapers with the transition of one part to another and with a decrease in the angle of inclination of the generatrix of the end part of the cone-shaped core of the screw shaft, while at least the first thread turn is made from the tip of the screw shaft with a recess forming a chip groove with cutting edges, and spherical thickening of the screw shaft is notched. 2. The transpedicular polyaxial screw according to claim 1, characterized in that the element that allows you to create a torque relative to the axis of the screw shaft is at least four grooves symmetrically located on the spherical thickening of the screw shaft. 3. The transpedicular polyaxial screw according to claim 1, characterized in that a concentric cutting is performed on the spherical thickening of the screw shaft. 4. The transpedicular polyaxial screw according to claim 1, characterized in that a spiral cutting is made on the spherical thickening of the screw shaft. 5. The transpedicular polyaxial screw according to claim 1, characterized in that the angles of the isosceles trapezoid of the thread profile on the working part of the screw shaft are 5 ° and 40 °.

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