CZ5444U1 - Heel splinter for inner fixation of heel bone fractures - Google Patents

Description

Technical field

The technical solution relates to a heel plate for internal fixation of intra-articular fractures of the heel bone, consisting of a base body with holes for screws for fixing to the bone.

BACKGROUND OF THE INVENTION

Heel fractures account for 60% of torsal injuries. and 2% of all fractures. For intraarticular fractures in general

It is true that the necessary reduction of fragments can be achieved only operatively. In the conservative procedure of imperfect repositioning, it is not possible to dispense with an additional external fixation with a plaster bandage and also to lead to the early mobilization of the affected joint as well as the neighboring joints. Fractures that occur on the calcaneus are made up of a larger number of bone fragments of different sizes. It is therefore important to easily reposition them without the possibility of their subsequent displacement. Existing splints for the internal fixation of intra-articular fractures of the calcaneus are usually formed by a flat Y-shaped fastening profile in which a set of holes for fixing to the calcaneus by means of screws is formed. Such splints are more flexible than reconstruction splints, they easily adapt to the wall of the heel bone. A heel splint is known where its classic Y-profile is additionally provided with T-shaped front and rear sections. Such a solution allows multiple bolts to be screwed through the splint into the heel bone to improve fixation. A disadvantage of the known embodiments is that, with regard to the design of the screw holes, the design thickness of the splints is such that it does not allow easy spatial shaping without the risk of breakage, but also the inclination of the screws relative to the axis of the hole.

The essence of the technical solution

These drawbacks are largely eliminated by the proposed type of heel plate, which is based on at least one. 7 holes with a one-sided recess for the screw heads, made at an angle to the surface of the flat mounting profile, away from their centers, and radii R 2 to 4 mm are formed around the periphery of the flat mounting profile between the openings for easy plate shaping.

The advantage of the heel plate according to the technical solution is, in particular, that it enables its wide use in various types of heel bone fractures without major modifications by the surgeon. This is achieved by using different heel plate shapes to achieve the largest possible area of the lateral portion of the heel bone. The heel splints of this construction allow the bone screws to be inserted at different angles into almost all heel spaces after easy shaping. This is made possible by the insertion of spongy or cortical screws through the holes of the flat fastening profile at different angles and possibly outside of them. This measure achieves stable fixation of bone fragments.

Advantageously, the basic embodiment of the heel plate shown in Fig. 1 is formed in the left and right embodiments, depending on which lower limb it is applied to.

-1GB 5444 Ul

It is also advantageous that the heel splints are designed such that the insertion of the screws into the recess, which is made on one side, ensures that the screw heads are recessed deeper and thus facilitate the covering of the plate with soft tissues.

Overview of the drawings

The technical solution will be explained in more detail by means of the drawing, in which Fig. 1 shows a schematic representation of the basic design of the heel plate for the left limb, Fig. 2 shows the basic design of the heel plate in cross-section. Fig. 4 schematically illustrates a shortened Y-shaped heel plate whose legs form an angle of 60 °, and Fig. 5 illustrates a schematic shortened heel plate whose legs form an angle of 40 °. Examples of technical solution

The basic embodiment of the heel plate according to FIG. 1 comprises a flat inverted thin sheet fastening profile 1 in the form of an inverted lower-case letter h. from their midpoints. Bone screws 4, such as cortical or spongy, are used to fix the plate to the bone. For easy shaping and lightening of the plate, radii 2 θ of radius R 2 to 4 mm are formed on the periphery of the flat fixing profile between individual holes 2. Relief is done in a way that does not create stress concentrates, making the plate more resistant to fatigue fractures. It is possible to shorten the plate at the radius 2 as required. A further embodiment of a heel plate consisting of a 11-hole flat fastening profile 1 is shown in FIG. fracture. 4 and 5 show further variants of the shortened heel plates consisting of a flat Y-shaped fastening profile 1 with 7 holes 2, the arms of which form an angle of 40 to 60 °.

The technique of using the plate is as follows. The patient is placed on an operating table, preferably on an X-ray table. This ensures the possibility of controlling the heel bone reduction during the operation by means of the X-ray machine in two basic projections. The fracture is repositioned using the supplied instrumentation. First, the heel plate, i.e. the flat fastening profile 1 with holes 2, is applied to the heel and is laterally applied to the heel bone fragments. The fixing of the heel bone fragments by means of bone screws 4 is carried out in the usual manner. Industrial applicability

Heel splints according to the technical solution can be used in surgical and orthopedic workplaces to perform firm fixation of the heel bone fracture.

Claims (1)

PROTECTION REQUIREMENTS Heel splint for internal fixation of the heel bone fractures, consisting of a flat fastening profile with holes for screwing into the bone, characterized by having at least seven holes (2) with a one-sided recess (5) for the screw heads (4) made with respect to the surface of the flat mounting profile (1) at an oblique direction from their centers, radii (3) having a radius R of 2 to 4 mm are formed around the periphery of the flat mounting profile (1) between the individual openings (2) for easy plate shaping. I ’ 1 drawing