FR2993170A1 - Friction device for connecting poly-axial screw to connector of spinal fixation device, has ring and bushing positioned against spherical head of screw, to axially pre-position connector relative to axial anchoring position of screw - Google Patents

Abstract

The friction device has a ring (8) and a bushing (12) intended to be positioned against a spherical head (9) of a poly-axial screw (4), so as to axially pre-position, before immobilizing, a connector (3) relative to an axial anchoring position of the poly-axial screw. The ring is arranged in a groove (10) arranged in a bore of the connector. The ring includes an opening for allowing axial deformation of the ring at the time of the installation of the spherical head of the poly-axial screw.

Description

The present invention relates to a device for friction of a spherical-head poly-axial screw in a connection connector of a spinal fixation device making it possible to instrument a spinal segment. of a spine of a patient. Known spinal fixation devices comprising connecting connectors each receiving a poly axial screw whose spherical head cooperates with locking means in vertical translation leaving a freedom of movement in rotation of said poly-axial screw inside said connector. .

This freedom of movement of the connection connector with respect to the polyaxial screw has certain disadvantages when said screw is anchored in the vertebral body of a vertebra. Indeed the connection connector is free from any pivoting around the spherical head 0 during the establishment of the connecting rod by the surgeon inside said connector. This freedom of movement does not make it possible to position and hold the connector in a determined axial plane for mounting the connecting rod by the surgeon. The latter is obliged to maintain said connector in position during the establishment of the connecting rod causing a mounting complication. The friction device according to the present invention aims to remedy its disadvantages by proposing friction means for maintaining in an axial position determined by the surgeon the connection connector with respect to the poly axial screw and during mounting of the rod. linking and before immobilization in translation and in rotation of said rod inside said connector. The friction device according to the present invention consists of friction means which are positioned against the spherical head of the polyaxial screw 40 in order to be able to pre-position axially before its immobilization said connection connector with respect to the anchoring position. axial of said polyaxial screw. The friction device according to the present invention comprises friction means which consist of at least one ring housed in a groove formed in the inner part of the connecting connector.

The friction device according to the present invention comprises a ring which is made of a material with a high coefficient of friction. The friction device according to the present invention comprises a ring which is made of a material made of titanium or cobalt alloy. The friction device according to the present invention comprises a ring comprising an opening allowing axial deformation of said ring during the introduction of the spherical head of the polyaxial screw. The friction device according to the present invention comprises a ring which is positioned at the widest outer diameter of the spherical head of the polyaxial screw. The friction device according to the present invention comprises a ring which bears against two half-shells housed in the groove formed in the internal part of the connection connector when the internal diameter of said connector is smaller than the external diameter of the anchoring part. of the polyaxial screw. The friction device according to the present invention comprises two half-shells whose internal profile is of complementary shape to that external of the spherical head of the poly-axial screw so as to allow it to lock in translation inside the connection connector. The friction device according to the present invention comprises friction means which consist of a ring coming after deformation of the internal partitions of the connection connector bearing against the spherical head of the polyaxial screw. The friction device according to the present invention comprises a ring comprising a housing whose inner face is of complementary profile to that spherical of the head of the polyaxial screw. The friction device according to the present invention comprises a ring comprising, on the opposite side of the housing, notches receiving the deformed part of the internal partitions of the connection connector (3). The friction device according to the present invention comprises friction means which consist of a ring housed in a groove formed in the internal bore of the connection connector so as to cooperate with the part of the widest outer diameter of the spherical head of the polyaxial screw and a ring coming after deformation of the internal partitions of said connecting connector bearing against the upper face of spherical head of said polyaxial screw. The following description with reference to the accompanying drawings, given by way of non-limiting examples, will make it possible to better understand the invention, the characteristics that it presents, and the advantages that it is likely to provide: FIG. perspective view illustrating a connection element of a spine device for the spine whose connection between the connecting connector and the poly-axial screw is completed by a friction device according to the present invention. Figures 2 and 3 are views showing an arrangement of the friction device and the poly-axial screw within the connector of the present invention. Figures 4 and 5 are views showing a variation of the arrangement of the friction device when the inner diameter of the connecting connector is smaller than the outer diameter of the anchoring portion of the polyaxial screw. Figures 6 to 9 are views illustrating different embodiments of the friction device according to the present invention. FIG. 1 shows a connection element 1 of a spinal device 2 for the instrumentation of a spinal segment of a spinal column. The connecting element 1 consists of a connection connector 3 mounted on a polyaxial screw 4 comprising a bone anchoring portion 14 and a clamping screw 5 cooperating with a threaded portion 3d formed by the vertical walls 3a. 3b of said connector for translational immobilization and rotation within the connecting connector of a connecting rod 6. The connecting connector 3 has a U-shaped profile whose vertical walls 3a, 3b delimit between them an opening 3c allowing the establishment of the connecting rod 6. o The connecting connector 3 comprises in the bottom of the U-shaped profile a bore 3e for receiving the spherical head 9 of the poly axial screw 4 FIGS. 2 and 3 show a friction device 7 making it possible to maintain in an axial position, determined by the surgeon, the connection connector 3 with respect to the spherical head 9 of the polyaxial screw 4 and during the mounting age of the connecting rod 6 and before immobilization in translation and rotation of said rod inside said connector, 40 the friction device 7 comprises friction means consisting of at least one ring 8 made of a material to a high coefficient of friction coming to be positioned inside a groove 10 formed inside the bore 3e of the connection connector 3. 45 Said ring 8 is positioned inside the groove 10 so that it comes into contact and around the spherical head 9 of the poly-axial screw 4 during the assembly of said poly-axial screw inside the connection connector 3.

Indeed, when the poly-axial screw 4 is mounted inside the connection connector 3, it is noted that the spherical head 9 comes in its lower part to bear against a circular edge 11 arranged inside the bore 3e and whose inner diameter is smaller than the outer diameter of said spherical head preventing the latter from crossing and escaping from said connector. The profile, the thickness and the dimensions of the internal diameter of the circular edge 11 make it possible to position the spherical head 9 of the polyaxial screw 4 with respect to the ring 8 of the friction device 7. According to a preferred embodiment of the invention, According to the invention, it is envisaged that the ring 8 of the friction device 7 is positioned at the widest outer diameter of the spherical head 9 of the polyaxial screw 4, knowing that the latter is cooperating with a support ring 12. in which is housed the connecting rod 6 during the clamping 15 of the clamping screw 5. Indeed, the clamping screw 5 allows one hand to immobilize in rotation and in translation the connecting rod 6 to the inside the connection connector 3 between said clamping screw 5 and the support ring 12 and secondly to block said connector 0 of connection 3 to the spherical head 9 of the polyaxial screw 4 previously anchored in the body of a vertebra of the spinal segment to be instrumented by the transfer of clamping forces applied to the bearing ring 12. The ring 12 is pierced in the middle of a through bore 12b allowing access to a tool which is housed in a cavity 9a formed in the spherical head 9 of the poly-axial screw 4 for its rotation training and bone anchoring. Note that the friction means consist of at least one ring 8 O made of a titanium alloy material or a cobalt alloy. The friction means may consist of at least one ring 8 having an opening 13 allowing axial deformation of said ring during the introduction of the spherical head 9 of the poly-axial screw 4 inside the connection connector 3. FIGS. 4 and 5 show a variant of the arrangement of the friction device 7 when the internal diameter of the circular edge 11 formed in the bore 3e of the connection connector 3 is on the one hand less than the diameter 40 external part of the anchoring portion 14 of the poly axial screw 4, and secondly greater than the outer diameter of the spherical head 9 of said screw. In this case, the spherical head 9 of the poly-axial screw 4 is retained inside the connection connector 3 by means of two half-shells 15, 16 housed inside the groove 10 formed inside. of the bore 3e so that the ring 8 of the friction device 7 comes to bear on said half shells.

The internal profile of the two half-shells 15, 16 is of complementary shape to that external of the spherical head 9 of the poly-axial screw 4 in order to allow it to be locked in translation inside the connection connector 3. It has been shown in FIG. FIGS. 6 to 9 different embodiments of the friction device 7 whose friction means consist of a ring 12 which bears against the spherical head 9 of the polyaxial screw 4 after deformation of the connection connector 3.

0 For this purpose the connection connector 3 comprises in the thickness of its vertical walls 3a, 3b and above the position of the ring 12 horizontal holes 3f closed on the side of the opening 3c of said connector by an internal wall 3g . The horizontal holes 3f are provided to receive the ends of a tool, not shown, for deforming in the direction of the opening 3c under a force the internal partitions 3g so that the deformed portion 3h of the latter cooperates with notches 12d formed in the upper part of the ring 12.

The deformed part 3a of the partitions 3c makes it possible to keep the ring 12 against the spherical head 9 of the polyaxial screw 4 so that said ring 12 constitutes a friction connection on said spherical head 9 making it possible to maintain in an axial position determined by the surgeon the connection connector 3 with respect to the poly axial screw 4 and during the mounting of the connecting rod 6 and before immobilization in translation and in rotation of said rod inside said connector. The ring 12 comprises a housing 12a whose inner face is of complementary profile to that of the spherical head 9 of the polyaxial screw 4 in order to receive the latter is formed on all the spherical profile of said head 9 in contact with a zone friction. The ring 12 is pierced in the middle of a through bore 12b allowing access to a tool that is housed in the cavity 9a formed in the spherical head 9 of the polyaxial screw 4 for its rotation and anchoring drive. bony. The ring 12 comprises at the opposite of the housing 12a a cavity 12c with a cylindrical profile designed to receive the connecting rod 6.

The ring 12 comprises at the opposite of the housing 12a the notches 12d receiving the deformed portion 3h of the partitions 3g of the connecting connector 3. The notches 12d are formed in a direction which is perpendicular to that of the housing 12a provided for receiving the rod link 6.

According to the different embodiments, the friction device 7 may comprise friction means which consist of: - Either a ring 8 housed in a groove 10 arranged in the internal part of the connection connector 3 so as to cooperate with the part of the outermost diameter of the spherical head 9 of the polyaxial screw 4 without distinction of the outer diameter of the anchoring portion 14 of said polyaxial screw 4 (Figures 2 to 5), - Or a ring 12 coming after deformation of the internal partitions 3g of the connection connector 3 in abutment with the upper spherical head face 9 of said polyaxial screw 4 without distinction of the external diameter of the anchoring part 14 of said polyaxial screw 4 ( FIGS. 6 and 9). Either of a ring 8 housed in a groove 10 provided in the internal part of the connection connector 3 so as to cooperate with the part of the widest outer diameter of the spherical head 9 of the poly screw. -axia 4 5 and a ring 12 coming after deformation of the internal partitions 3g of the connecting connector 3 bears against the upper face of the spherical head 9 of said polyaxial screw 4 without distinction of the outer diameter of the anchoring portion 14 said polyaxial screw 4 (Figures 7 and 8).

It should further be understood that the foregoing description has been given by way of example only and which does not in any way limit the scope of the invention which would not be overcome by replacing the details of execution described by any other equivalent. 2

Claims (10)

REVENDICATIONS1. Friction device for a polyaxial screw (4) comprising a threaded bone anchoring part (14) integral with a spherical head (9) housed in a connecting connector (3), characterized in that it consists of friction means (8, 12) being positioned against the spherical head (9) of the polyaxial screw (4) in order to be able to pre-position axially before its immobilization said connection connector (3) with respect to the position of axial anchoring of said polyaxial screw (4). 2. Device for friction of a polyaxial ball head screw according to claim 1, characterized in that the friction means consist of at least one ring (8) housed in a groove (10) arranged in a bore (3e) of the connection connector (3). 3. Device for friction of a poly-axial ball head screw according to claim 2, characterized in that the ring (8) is made of a material with a high coefficient of friction. 20 4. Device for friction of a poly-axial ball head screw according to claim 2, characterized in that the ring (8) is made of a titanium alloy material or cobalt. 25 5. Device for friction of a polyaxial ball head screw according to claim 2. characterized in that the ring (8) has an opening (13) for axial deformation of said ring during the establishment of the spherical head (9) of the polyaxial screw (4). 6. Device for friction of a polyaxial ball head screw according to claim 2, characterized in that the ring (8) is positioned at the widest outer diameter of the spherical head (9) of the screw. polyaxial (4). 35 7. Device for friction of a poly-axial ball head screw according to claim 2, characterized in that the ring (8) is in abutment against two half-shell (15, 16) housed in the groove (10) arranged in the bore (3e) the inner part of the connecting connector (3) when the inner diameter of said connector is smaller than the outer diameter of the anchoring portion (14) of the polyaxial screw (4). 8. Device for friction of a poly-axial ball head screw according to claim 6, characterized in that the internal profile of the two half-shell (15, 16) is of complementary shape to that external of the spherical head (9). ) of the poly-axial screw (4) to allow its locking in translation within the connecting connector (3). 9. Device for friction of a poly-axial ball head screw according to claim 1, characterized in that the friction means consist of a ring (12) coming after deformation of the internal partitions (3g) of the connection connector. (3) resting against the spherical head (9) of the polyaxial screw (4). 10.Dispositif friction of a poly-axial ball head screw according to claim 9, characterized in that the ring (12) comprises a housing (12a) whose inner face is of complementary profile to that 0 spherical head (9) of the polyaxial screw (4). Device for friction of a polyaxial ball head screw according to Claim 9, characterized in that the ring (12) has on the opposite side of the housing (12a) notches (12d) receiving the deformed portion (3h) of internal partitions (3g) of the connection connector (3). 12.Dispositif friction of a poly-axial ball head screw according to claim 1, characterized in that the friction means consist of a ring (8) housed in a groove (10) arranged in a bore ( 3e) of the connecting connector (3) so as to cooperate with the part of the largest outer diameter of the spherical head (9) of the polyaxial screw (4) and a ring (12) coming after deformation of the internal partitions (3g) of said connection connector (3) bearing against the upper spherical head face (9) of said polyaxial screw (4). 25