SU1754085A1 - Plate for bony fragment compression - Google Patents

Abstract

Use: Increase the effectiveness of treatment by reducing the time it takes to build bone fragments. SUMMARY OF THE INVENTION: The plate comprises two brackets 1, 2, cylindrical 3 and flat sections, screw 5, nut 6, cylindrical guide 7, calibrated helical spring 8, compression, end surfaces 9, 10, and lower parts 11 of semi-circular brackets. 3 il.

Description

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The invention relates to medicine, namely to traumatology, in particular to devices for submersible compression osteosynthesis (for compressing bone fragments directly applied to the bone) .i

A known plate for simultaneous and dynamic compression of bone fragments, having a surface adjacent to the bone and containing holes for attachment to the bone. In this case, the antirotational effect is achieved by arranging holes in a checkerboard pattern, and dynamic compression is due to the presence of elongated holes on one side of the plate and the possibility of physiological compression within the length of these holes,

A disadvantage of the known construction is the inability to provide forced dynamic compression, which leads to delayed accretion of fragments or the development of a false joint.

There is a known contour for putting on a band in which, in order to create a connection between plaster splints, there are two three-lobe fixing plates fixed in plaster splints. The splints themselves are connected by several kontorzorov, in which there are springs that carry out a constant compression during the entire period of treatment.

Experience in the field of traumatology shows that during operations in a limited space at the fracture site, it is impossible to impose plaster splints and then the device should be applied directly to the shaft without interfering with the environment of soft tissues. In the known container there are protruding parts 1 spring, screw, bracket, which increases its dimensions, creates uncomfortable conditions for the patient. In addition, several (two or more) containers between gypsum tutors are used to create an antirotational effect, which complicates all the tools used in the operation.

A device for non-rigid fixation of bone fractures is known, containing movable guide clamps and stationary clamps located on the main and auxiliary supports movably interconnected with the possibility of adjustment, and also containing a spring, when released in the longitudinal direction relative to the fixed limb, fragments are compressed .

However, the known device cannot be used for carrying out an immersion compression osteosynthesis, it has sizes that are significantly protruding beyond the bone fragments, when it is used, the probability of damage to soft tissues is high.

Closest to the present invention is an adjustable tire at bone fracture, which contains two brackets fixed on bone fragments, connected to each other by a micrometric screw transmission, which includes a screw and a nut. The brackets have protrusions for attaching their lower gutter parts to bone fragments.

However, after the brackets are firmly fixed on the bone fragments by rotating the micrometer screw (with the nut unlocked), one-stage compression (compression) of the bone fragments is known. One-time compression of the fragments is known to be maintained for a short time, after which, if the secondary compression is not performed, the process of splicing is. The need to propidate periodic single-step compressions requires additional time and the fate of the attendants. The implementation of the known device also has technological difficulties, in particular the manufacture of a thread in a long section, the presence of a special key for a rotary shaft rotary knob. These drawbacks reduce the effectiveness of the treatment of broken bones, preventing its replication.

The purpose of the invention is to increase the effectiveness of treatment by reducing the time it takes to build bone fragments together, by creating constant dynamic compression between them, creating an antirotational effect on bone fragments as they grow together.

The goal is achieved by the fact that in the plate for compressing bone fragments containing two brackets fixed on the bone fragments, connected to each other by a micrometric screw gear, which includes a screw and a nut, the brackets are made to interact with each other through guide surfaces the screw gear is made in the form of a screw, which is a continuation of the guide surface of one of the brackets and, together with the nut screwed on it, is placed inside the base hole in orogo bracket and to the space between the resilient bracket further introduced

the element interacting with the end surfaces of the nut and the base surface of the second bracket, wherein the elastic element is designed as a helical compression spring.

The creation of an antirotational effect on fragments during their accretion is achieved by the fact that the guide surfaces of the brackets have cylindrical and flat sections.

FIG. 1 shows a plate for compressing bone fragments in axial section; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows a section BB in FIG. one.

The plate for compressing bone fragments contains two brackets 1 and 2 fixed to the bone fragments, interacting with each other through conjugated guide surfaces, having a cylindrical 3 and flat 4 areas. The brackets 1 and 2 are connected to each other by a micrometric screw gear, made in the form of a screw 5, which is a continuation of the cylindrical section 3 of the guide surface of the bracket 2. A screw 5 and a screw 5 and a nut 6 are placed on the screw part of the screw 5 7 of the bracket 1. Inside the cylindrical guide bracket 1, in the space between the brackets, an elastic element 8 is placed in the form of a calibrated helical compression spring in such a way that its end surfaces interact with the end faces and surfaces 9 and 10 belonging, respectively, the nut 6 and the base opening 7 bracket 1 adjacent to the bone surface 11 of both arms are curved radius RK, where R «- average radius of curvature of the surface of the bone.

A plate for compressing bone fragments is used as follows.

Before installing the plate on the bone, its brackets 1 and 2 are assembled so that the nut b on the screw 5 is in the extreme (left, in FIG. 1) position. In this case, a maximum gap is formed between the brackets. In this position, the plate is placed on bone fragments. This arrangement of the plate brackets further allows, as the bone fragments are spliced due to the axial movement of the nut b on the threaded part of the screw 5, to change the force of compression of the spring 8. providing a constant dynamic compression of the bone fragments. In this case, the movement of the brackets 1 and 2 one relative to another occurs simultaneously along the adjoining cylindrical 3 and flat 4 sections of the guide surfaces, as a result of which the possibility of rotation of the brackets with fragments is eliminated.

The proposed plate can be used for fixation of fragments of various bones: femoral, ulnar, tibialis, humerus, and others during external osteosynthesis operations.

The disc is simple in design, technological in manufacturing and convenient in practical use. Saving costly anticorrosive material has been achieved by making brackets from conventional structural steel and applying a protective anticorrosion layer to them.

The provision of constant dynamic compression ensured a reduction in the time of splicing of bone fragments (as compared with the traditionally used

plates by type of cyto plates) 1.42 times (for the femur), 1.62 times (for the bone of the forearm) and 1.56 times (for the radius).

Claims (1)

Invention Formula A plate for compression of fragments containing two kinematically connected to each other by means of a screw and a bracket nut with holes for screws placed in the lower part of the semi-oval shape, with the upper part of one of the brackets made in the form of a cylindrical guide, and the other in the form of a tubular surface, characterized in that, in order to increase the effectiveness of treatment by reducing the time to accretion of bone fragments by creating a constant dynamic compression between them, a calibrated compression spring screw has been inserted into it, placed inside the cylindrical guide and in contact with the tubular surface. Aa 6-6 fa.e