BG1793U1 - Hip joint stem - Google Patents

Abstract

Utility model relates to stem of hip joint from titanium alloy, which is used in orthopedics and traumatology of medical practice. The structure of the stem solves problems of various clinical cases of trauma, fractures in osteoporosis, wear of cartilage tissue and congenital dislocations by high flexibility and variability. The stem consists of two parts: cervical - conical (A) and the stem-fixative (B) , having separately and in mutual connected, a variety of anatomical and biomechanical characteristics and dimensions which exist in a variety of natural femur. Thus, their combination is selected according to the particular clinical case. The two parts (A, B) of the stem are positioned to each other with two pins (7, 8) in their geometrically similar flat contact surfaces (4, 9) at the appropriate angle (alpha) and rigidly clamped together with the clamping screw (3). The same goes through the neck-conical portion (A) and screwed into stem fixation (B) and in the mounted therein a polyethylene insert (10), which serves to prevent the uncontrolled unscrewing it.

Description

The useful model relates to the hip joint, which is used in the field of orthopedics and traumatology in the surgical treatment of diseases of the femur and its trochanteric part, such as injuries and fractures in osteoporosis, cartilage wear, congenital luxations and other.

BACKGROUND OF THE INVENTION

Composite stems of the hip joints, made of two parts shiitoconus and stem-fixation, are interconnected on their flat-contact parts. The famous stem is made of titanium alloy. / ZimmerM / L Taper Hip Prosthesis /

The technical essence of the utility model

The task of the utility model is to create a hip joint that has the potential for maximum flexibility with respect to a wide range of clinical requirements and anatomical features of the patient.

The problem is solved with a hip joint consisting of two cervical-conical and stem-fixation interconnected on its flat-contact surfaces, the stem being made of titanium alloy. According to a useful model, the two parts are secured to each other by two pins which are located on the flat-contact surface of the stem-fixing part and enter openings on the flat-contact surface of the cervical-conical part. The two parts are fixed to each other with a clamping screw passing through the neck-cone part and screwing into the stem-fixing part and into a plastic insert mounted in the stem of the stem-fixing part.

An advantage of the utility model is that it offers, on a case-by-case basis, a large variance in the biomechanical dimensions and anatomical angles of the cervical-cone and stem-fixation part. The high flexibility, which the technical features described, create exceptional possibilities for refining the operative intervention. It is also advantageous that, upon direct implantation in the operative field, the proposed model enables quick and trouble-free positioning and fixed fixation of both parts with the clamping screw. A strong and durable connection is also ensured by screwing the clamping screw into a self-unwinding plastic insert.

The proposed design of the utility model provides the technical ability to be manufactured on universal machine tools, which makes it economically viable in terms of manufacturing investment.

Explanation of the annexed figures

An exemplary embodiment of the utility model is shown in the drawings of the figures, where:

Figure 1 is a view of the conical portion with the clamping screw and a view of the flat-contact surface thereof;

Figure 2 shows the stem-fixing part with the polymer insert in it and a view of its flat-contact surface;

3 is a cross-sectional view along the C-C of the stem-fixing part, the arrangement in the stem of the polymer insert with the opening through it for the clamping screw;

Figure 4 shows two projections of the stem-fixation portion, its zones defining the length, thickness and width in the trochanteric region of the femur and its canal;

Figure 5 is a general view of a monolithically assembled hip stem of the utility model;

Figure 6 is a general view of the stem according to the utility model.

Exemplary implementation and application of the utility model

The neck-cone portion A of FIG. 1 is determining both the length of the neck 1 and the angle of attachment relative to the stem-fixing portion B of FIG. 2. This length is very different, as is the angle that anatomically moves between 125 ° -135 °. Through the neck-cone part A passes the opening 2 for the clamping screw 3, and on its flat-contact surface 4 are two openings 5, 6, in which when positioning the two parts A, B in FIG. 1, 2 on

1793 Ul stem, respectively, enter the two pins 7,8 fig. 2. They are located on the flat-contact surface 9 of the stem-fixing part B of FIG. 2. From the same contact surface 9, the hole 2 'with a metric thread starts to go. 2, in which the clamping screw 3 is screwed. 1. This opening intersects 90 ° from the polymer insert 10 of FIG. 2, FIG. 3, which only has a threaded hole. The effect of this turning is to prevent uncontrolled unrolling.

The stem-fixing portion B of FIG. 4 is determining the length 11, the thickness 12,12 'and the width 13 of the stem in the area of the trochanteric part of the femur and its canal. The stem is made of titanium alloy, T16A14V (BT-6), which has the appropriate purpose, physicochemical properties and bioavailability. The high-pressure polyethylene polymer also covers the above requirements for this production.

Claims (1)

1. A hip joint consisting of two cervical-conical (A) and stem-fixing (B) joints connected to each other by flat-contact surfaces, the stem being made of a titanium alloy, characterized in that the two parts (A and B) are secured to each other by two pins (7, 8) which are located on the flat-contact surface (9) of the stem-fixing part (B) and enter openings (5, 6) on the flat- the contact surface (4) of the neck-cone part (A), the two parts (A, B) being fixed to each other by a clamping screw (3), n passing through the neck-cone part (A) and screwing into the stem-fixing part (B) and into the plastic insert (10) mounted in the stem of the stem-fixing part (B).