LT6427B - Proximal femoral osteosynthesis plate - Google Patents

Abstract

Invention is a surgical device that is particularly designed for proximal femurosteosynthesis. The purpose of present invention is to provide a fixation plate having optimal surface contact with bone in order to reduce complication rate and increase device reliability; as well as to ensure the effectiveness of osteosynthesis of various proximal femoralfractures, and reduce secondary bone fracture rate. The purpose is achieved as follows: proximal femoral osteosynthesis plate has screw holes axis of which are tilted in certain angle towards the bone center, and are situated in different sides of the center line of plate shaft portion; neither of the adjacent holes is in the same longitudinal line; geometrical angles of the proximal plate portion are selected to provide the optimal contact between the inside surface of the proximal portion of the plate ant anatomical surface of the greater trochanter, to ensure that the largest possible inside surface of the plate comes into contact with lateral surface of the bone; along the area where proximal portion of the plate meets the shaft portion, the stiffening ribs are designed. The novelty of the device is that the angulations of the axis of screw holes in the osteosynthesis plates for fixation of pertrochanteric fractures, intertrochanteric fractures, common fractures, femur neck and pertrochantericfractures, are selected based on anthropometrical analysis of the femur bone.

Description

The invention relates to surgical devices, in particular to osteosynthesis plates of femur fractures. According to international classification A61B17 / 58 Surgical instruments, devices or methods of osteosynthesis, eg bone plates, screws or the like.

Orthopedics have long used bone fracture plates (osteosynthesis plates), which are basically implants of one or more parts. These implants can be supplied in various lengths and modifications according to the state of the art.

Known firms in Arthrex, Ine. osteosynthesis plaque of bone fractures consisting of two integral parts, the body and the proximal end. The body part moves to the proximal part as it is distributed (see EP 2 730 244 A1).

The disadvantage of such a plate is the configuration of the screw holes and the thickness of the plate does not guarantee mechanical stability of the plate.

Known femoral osteosynthesis plates of the proximal end of the femur known to Depuy Synthes Products, LLC. Elongated plate consisting of two integral parts - body and proximal end. The body part moves to the proximal part as it is distributed (see WO 2015/088760 Al).

The disadvantage of such a plaque is that 37.5-42.1% of patients treated in this way complain of pain in the femur (Oh CW et al., 2009, Wirtz C et al., 2013, Saini P at ai., 2013). The cause of the pain is an inflammation of the lumbosacral sac of the femoral lobe, which is not completely attached to the lateral surface of the proximal femur (Oh CW et al., 2009, Saini P at ai., 2013). Such plate orifice configurations do not provide mechanical stability in the case of complex fractures. Such plates have diagonal lines on the screw openings in the body, which can lead to bone breakage during treatment.

It is an object of the present invention to provide maximal plaque fit to the femoral major lumbar vertebra, thereby reducing the likelihood of complications, which would enhance its reliability, as well as to provide different osteosynthetic efficiency of different femur proximal end fractures by the likelihood of a secondary bone fracture (due to the insertion of the plate), with the screw holes not aligned.

The plaques provided allow for osteosynthesis of the femur proximal end fracture, and its construction is based on detailed anthropometric measurements of the population, thus ensuring maximum plaque fit to the bone and minimizing the risk of complications.

The openings in the body part of the plate are tilted at an angle to the center of the femoral body so that the screws are inserted through the thickest part of the bone and spaced apart on each side of the centerline of the body and no adjacent hole is in line , thus preventing bone breakage by inserting the screws, and the number of openings is proportional to the length of the plate, and the locking screw opening at the intersection with the lower surface along the plate has slopes that allow the angle of the screw to enter the bone Analysis of anthropometric data selected so that the lower surface of the proximal end is as close as possible to the anatomical curvature of the greater part of the bone and thus fits as closely as possible to the bone, thereby providing an even distribution of forces acting on the proximal end of the femur rupture and prevents the development of femoral varus deformity by fixation of bone fragments, and the distal end of the plate gliding to the lateral surface of the femoral body facilitates implantation under the muscle and less trauma to the surrounding soft tissues and the proximal end is thicker than the at the transition point, there are stiffeners at the edges of the upper surface of the plate that reinforce the plate at this point. Four modifications of the proximal end of the plate have been developed to allow them to be used to treat a broader range of femoral proximal fractures, while maintaining very good mechanical properties of the plate, which increases resistance to flexural-tensile forces acting on bone healing.

The drawings show:

FIG. 1 Femoral proximal end osteosynthesis plate for osteosynthesis of peritoneal fractures (vi);

FIG. 2 Plates (vi) local incisions of proximal end 2 and apertures for non-locking screw 7, inclination angles of apertures relative to sagittal plane;

FIG. 3 Detail view D, apertures for non-locking screw 7 detail;

FIG. 4 Section C-C, slanting of the tapered aperture in the body portion of the locking screw;

FIG. 5 Section B-B, slanting of the tapered aperture in the body portion of the locking screw;

FIG. 6 Section of plate (vi) Inclination of G-G aperture to frontal plane;

FIG. 7 Section H-H of plate (vi), oblique inclination of the opening to the frontal plane;

FIG. 8 Section l-l of plate (vi), inclination of the opening relative to the frontal plane;

FIG. 9 Femoral proximal end fracture osteosynthesis plate for intergroup fracture osteosynthesis (v2);

FIG. 10 Local section 2 of the proximal end of the plate (v2), angles of inclination of the apertures relative to the sagittal plane;

FIG. 11 Section G-G of plate (v2), oblique inclination of the opening to the frontal plane;

FIG. 12 Section H-H of plate (v2), oblique angle of aperture to frontal plane;

FIG. 13 Section l-l of plate (v2), inclination of the opening in relation to the frontal plane;

FIG. 14 Universal femoral proximal end fracture osteosynthesis plate (v3);

FIG. 15 Local section 2 of the proximal end of the plate (v3), oblique angles of the apertures relative to the sagittal plane;

FIG. 16 Section G-G of plate (v3), oblique inclination of the opening to the frontal plane;

FIG. 17 Section H-H of plate (v3), slope of the opening in relation to the frontal plane;

FIG. 18 Section l-l of plate (v3), slope of the opening in relation to the frontal plane;

FIG. 19 Femoral proximal end osteosynthesis plate for osteosynthesis of femoral neck and suppurative fractures (v4);

FIG. 20 Local section 2 of proximal end of plate (v4), oblique angles of apertures with respect to sagittal plane;

FIG. 21 Section G-G of plate (v4), slope of the opening in relation to the frontal plane;

FIG. 22 Section H-H of plate (v4), inclination of aperture with respect to frontal plane;

FIG. 23 Section l-l of plate (v4) with oblique inclination of the opening in the frontal plane.

The plate consists of:

- body part of the plate; 2 - proximal end of plate; 3 - lower surface of plate; 4 - top surface of the plate; 5 - rising edge of non-locking screw openings; 6 - openings for locking screws; 7 - openings for non-locking screws; 8 - openings for Kirchner wires; 9 - right lateral surface of plate; 10plate left lateral surface; 11 - centerline of body part; 12 - lower slope of unlocked screw openings; 13 is the first segment (proximal to the body) of the proximal end of the plate; 14 is the second segment (proximal to the body) of the proximal end of the plate; 15 is the third segment (from the body) of the proximal end of the plate; 16 - Incisors of implant ends; 17 - stiffeners; a - angle of inclination of the opening in relation to the sagittal (lateral) plane; β is the angle of inclination of the opening in relation to the frontal (front) plane.

The fracture osteosynthesis plate of the proximal end of the femur works as follows.

The osteosynthesis plate (Fig. 1, Fig. 9, Fig. 14, Fig. 19) of the proximal end of the femoral fracture is fixed by screws to the fractured bone during surgery, thereby reinforcing the fractured bone fragments. The plate (Fig. 1, Fig. 9, Fig. 14, Fig. 19) consists of two main components, the body part (1) and the proximal end (2). The body part (1) of the plate is not straight, it is curved with a certain radius to correspond as closely as possible to the anatomical shape of the femoral body (not shown). The concave lower surface (3) of the plate is in contact with the bone (not shown). The convex surface (4) above it does not come into contact with the bone (not shown), but upon implantation it is in contact with soft tissue (not shown). The upper surface is connected to the lower surface by side surfaces (9, 10). The plate has three types of openings through the lower surface (3) to the upper surface (4): locking screws (6), non-locking screws (7) and openings for Kirchner wires (8).

The sections (Fig. 4, Fig. 5) show that the openings (6) of the locking screws are tapered

- narrows from the upper surface (4) to the surface (5). The openings (7) of the non-locking screws are of elongated shape (Fig. 2, Fig. 3), and one edge (5) of the elongated opening (7) rises at a certain angle towards the upper surface (4). The geometry of the openings (6, 7) may vary depending on the plate configuration. All openings (6) in the body portion (1) of the plate are angled at an angle to the center of the femoral body (not shown) to insert the screws (not shown) into the thickest part of the bone (not shown) (Fig. 4 and Fig. 2). 5). The openings (6) are spaced apart over the entire length of the body and no adjacent openings are in line (Fig. 1). They are located on different sides of the center line (11) of the body portion (1) of the plate, thus preventing bone breakage by introducing screws. The openings (7) are not tilted and are located in the center of the body part (1) of the plate. The longitudinal section (Fig. 2, Fig. 3) shows a non-locking opening (7) which has a slant (12) at its intersection with the lower surface (3) along the plate. Their purpose

- give the surgeon more freedom to change the angle of inclination of the screw (not shown) by inserting it into the bone (not shown). The proximal end (2) of the plate consists of three segments (13,14 and 15) (Fig. 2, Fig. 10, Fig. 15, Fig. 20), which seamlessly connect to each other and form a single unit. Each individual segment forms an angle in the frontal plane with respect to the body portion (1) of the plate (Fig. 2, Fig. 10, Fig. 15, Fig. 20). The angles are chosen so that the lower surface (3) of the proximal end (2) is as close as possible to the anatomical curvature of the greater part of the bone and as close as possible to the bone, thereby ensuring an even distribution of forces acting on the proximal end of the femur. varus development of deformation by fixation of bone fragments. The third segment (15) of the proximal end (2) (furthest from the body portion of the plate (1)) and the far end of the body portion (1) are inclined (16) for easy insertion of soft tissue under the tissue. The proximal end (2) of the plate differs depending on the modification of the plate, the proximal end of the plate modifications vi, v2 and v3 differ from each other in the number of openings for the screws (6), their proximity and their inclination angles. The proximal end of the v4 modification plate varies in length (does not have a third segment (15) which the rest of the modifications have) and in the angles and arrangement of the screw holes (6) therein. The plate has at least three openings (6) for locking screws at the proximal end. Each opening (6) is inclined with respect to two planes (frontal (anterior) and sagittal (lateral) planes) (Fig. 6, Fig. 7, Fig. 8, Fig. 11, Fig. 12, Fig. 13, Figs. 16, Fig. 17, Fig. 18, Fig. 21, Fig. 22, Fig. 23) at such angles (α, β) that it is convenient to insert the screws so that the screws go into the femoral neck (not shown) without intersecting with other. The apertures at the proximal end of the plate (2) are larger in diameter than the body portion of the plate (Fig. 1, Fig. 9, Fig. 14, Fig. 19). The proximal end (2) also has two openings (8) for Kirsner wires.

The proximal end (2) is thicker than the body part of the plate (1) and the transition from one part to the other is smooth. At the transition point at the edges of the upper surface of the plate (4) are stiffening ribs (17) (Fig. 1, Fig. 9, Fig. 14, Fig. 19) which strengthen the plate at this location and increase the resistance of the plate to flexural tensile forces. during healing.

Claims (5)

DEFINITION OF INVENTION 1. An osteosynthesis plate of the femur proximal end fracture made of titanium alloy consists of two integral parts, the body part and the proximal end, the proximal end being wider relative to the body, the plate curved to a certain extent to conform to the anatomical shape of the femoral body, apertures formed at the proximal end of the plate for screws that are rotated in different directions to the femoral neck and head, characterized in that the openings in the body of the plate are angled at a certain angle to the center of the femoral body and spaced apart and no adjacent orifice is in line, and the number of orifices is proportional to the length of the plate; furthermore, the aperture of the locking screw at the intersection with the lower surface is inclined along the plate and the proximal end of the plate, according to anthropomet selected with the lower surface of the proximal end as close as possible to the anatomical curvature of the greater lumbar spine, thus fitting as wide a surface as possible to the bone, with the distal end of the plate gliding to the lateral surface of the femoral body and the proximal end thicker than the body of the plate and there are stiffeners at the proximal end transition to the body at the edges of the upper surface of the plate. 2. The femoral proximal end fracture osteosynthesis plate according to claim 1, characterized in that the axial different directions of the proximal end openings for osteosynthesis of the peritoneal fracture are selected by anthropometric data analysis. 3. The femoral proximal end fracture osteosynthesis plate according to claim 1, characterized in that the axial different directions of the proximal end openings for osteosynthesis of the intergovernmental fractures are selected by anthropometric data analysis. 4. The femoral proximal end fracture osteosynthesis plate according to claim 1, wherein the axial different directions of the proximal end openings for universal femoral proximal end fracture osteosynthesis are selected from anthropometric data analysis. 5. The femoral proximal end fracture osteosynthesis plate according to claim 1, wherein the axial different directions of the proximal end aperture fractures for osteosynthesis of the femoral neck and perineal fracture have been selected by anthropometric data analysis.