RU2837528C1 - Subchondral stressed reinforcement method - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to traumatology and orthopaedics, and can be used for subchondral reinforcement of intra-articular fractures. Method involves subchondral delivery of two pins through fragments of an articular surface of the bone, bending the outer ends of the pins and pressing them to the bone with a plate by means of screws. Fragments of the articular surface of the bone are repositioned and fixed by the introduction of the pins; outer ends of the pins are bent at the articular surface at angle of 130-140°. Distal to the first bend at the level of the intact bone, the pins are bent in the same plane at angle of 90-95°. Points of entry of the bent ends of the pins into the intact bone section are marked and holes are made. Bent ends of the pins are immersed in the holes until they are borne against the bone, and the outer portions of the pins are pressed to the bone with the help of screws.

EFFECT: method provides eliminating the possibility of the pin ends displacement from under the external fixation apparatus and development of vertical instability of the strained pins by eliminating the possibility of the pin ends displacement from under the external fixation apparatus and the development of vertical instability of the strained pins.

1 cl, 15 dwg, 2 ex

Description

The invention relates to the field of medicine, in particular to traumatology and orthopedics, and can be used in the treatment of comminuted fractures of articular surfaces of bones.

A method of subchondral stress reinforcement is known, described in the patent of the Russian Federation No. 2555108 for the invention “Method of subchondral stress reinforcement” according to class A61B 17/56, declared on 23.09.2013 and published on 10.07.2015.

This method of subchondral stress reinforcement includes inserting spokes through the fracture zone and bending their outer ends, wherein one end of the spokes, at least two, is inserted subchondrally through the fragments of the articular surface above the bone defect area to its cortical layer, then mechanical stress is created in the spoke, for which an arcuate bend is formed at the outer end of each spoke, and the free linear section of the spoke after bending is deflected at an angle of 45-60° relative to the longitudinal axis of the bone, after which it is pressed to the bone with a plate using screws.

The disadvantages of this method are the insufficient effectiveness and quality of treatment, due to the possibility of displacement of the ends of the spokes from under the external fixation apparatus and the development of vertical instability of the tense spokes.

The objective of the claimed invention is to improve the efficiency and quality of treatment of intra-articular bone fractures using subchondral stress reinforcement.

The technical result that allows solving the specified problem is the elimination of the possibility of displacement of the ends of the spokes from under the external fixation device and the development of vertical instability of the tense spokes.

The said result is achieved by the fact that in the method of subchondral stress reinforcement, including the introduction of the ends of the spokes, at least two, subchondrally through the fragments of the articular surface above the area of the bone defect, bending their outer ends and pressing them to the bone with a plate using screws, according to the invention, the outer ends of the spokes near the articular surface are bent at an angle of 130-140°, then distal to the first bend at the level of the intact bone, the spokes are bent in the same plane at an angle of 90-95°, after which the bent ends of the spokes are immersed until they stop in the holes previously made in the bone below the fracture line, and the outer sections of the spokes are pressed to the bone with a bone plate using screws.

Bending the outer ends of the spokes near the articular surface at an angle of 130-140°, then bending the spokes distal to the first bend at the level of the intact bone in the same plane at an angle of 90-95°, after which the bent ends of the spokes are immersed into the holes previously made in the bone below the fracture line until they stop, and pressing the outer sections of the spokes to the bone with a bone plate using screws, makes it possible to eliminate the possibility of displacement of the ends of the spokes from under the external fixation apparatus and the development of vertical instability of the tense spokes and thereby increase the effectiveness and quality of treatment of intra-articular bone fractures using the subchondral tense reinforcement method.

The proposed set of essential features imparts new properties to the claimed method of subchondral stress reinforcement, which make it possible to solve the stated problem.

The claimed method of subchondral stress reinforcement is novel compared to the prototype, differing from it in that the outer ends of the spokes near the articular surface are bent at an angle of 130-140°, then distal to the first bend at the level of the intact bone, the spokes are bent in the same plane at an angle of 90-95°, after which the bent ends of the spokes are immersed until they stop in the holes previously made in the bone below the fracture line, and the outer sections of the spokes are pressed to the bone with a bone plate using screws.

The applicant is not aware of a method of subchondral stress reinforcement that has the above-mentioned distinctive essential features that make it possible to clearly achieve the same technical result, therefore the applicant believes that the claimed invention meets the criterion of “inventive step”.

The claimed method can find wide application in the field of medicine, in particular, in traumatology and orthopedics, and can be used in the treatment of comminuted fractures of articular surfaces of bones, therefore it meets the criterion of “industrial applicability”.

The claimed method of subchondral stress reinforcement is a set of actions that allow increasing the efficiency and quality of treatment of intra-articular bone fractures by the method of subchondral stress reinforcement, and consists of introducing the ends of at least two spokes subchondrally through the fragments of the articular surface above the area of the bone defect, bending their outer ends near the articular surface at an angle of 130-140°, then bending the spokes in the same plane at an angle of 90-95° distal to the first bend at the level of the intact bone, further immersion until the stop of the bent ends of the spokes in the holes previously made in the bone below the fracture line, and pressing the outer sections of the spokes to the bone with a bone plate using screws.

The essence of the invention is illustrated by the drawings, which are shown in:

Fig. 1. General view of the initial fixation of bone fragments with a pin.

Fig. 2. General view of the double bend of the needle when fixing bone fragments.

Fig. 3. General view of fixation of bone fragments with a curved pin.

Fig. 4. General view of the fixation of bone fragments with a pin pressed against the bone plate.

Fig. 5 and 6. Radiographs of the patient’s right knee joint in two projections upon admission for treatment.

Fig. 7 and 8. Radiographs of the patient’s right ankle joint in two projections upon admission for treatment.

Fig. 9 and 10. Radiographs of the patient’s right ankle joint in two projections after surgery.

Fig. 11 and 12. Radiographs of the patient’s right knee joint in two projections after surgery.

Fig. 13 and 14. Radiographs of the patient's left ankle in two projections upon admission for treatment.

Fig. 15. X-ray of the patient’s left leg after surgery.

The claimed method of subchondral stress reinforcement is implemented as follows.

When preparing for surgical treatment of intra-articular bone fractures using subchondral stress reinforcement, the nature of the fracture and the location of the fragments of the articular surface of the bone are studied using X-rays and other studies, and based on this, the process of repositioning and fixation of the fragments using pins is planned, and the required number of pins is determined.

After treating the surgical field, surgical access to the fracture is performed, the fragments of the articular surface of the bone are repositioned and the fragments are fixed by inserting the ends of at least two pins subchondrally through the fragments 1 of the articular surface above the area of the defect 2 of the bone (see Fig. 1), without reaching the opposite cortical layer and without perforating it (only one pin 3 is shown in the drawings for simplicity).

Next, the needle 3 is pulled back by 4-5 mm and its outer end is bent near the articular surface at an angle of α 130-140°, after which, distal to the first bend at the level of the intact bone, the needle 3 is bent in the same plane at an angle of P 90-95° (see Fig. 2), and the entry point of the bent end of the needle 3 into the bone is marked. At this entry point of the needle 3 into the bone, located outside the fracture area (below the fracture line), a hole is made with a drill and the bent end of the needle 3 is immersed in it, driving both ends of the needle 3 into the bone until they stop (see Fig. 3). In this case, as a result of the deformation of the needle 3 at the bending point, a stressed U-shaped structure of the needle 3 is formed, with the help of which a damping stress compression of the united bone fragments is realized.

In a similar way to the first spoke 3, other spokes are inserted, which are necessary for rigid fixation of the fragments of the articular surface of the bone. The minimum number of spokes necessary for rigid fixation is two spokes. Then, osteosynthesis of the bone is performed, pressing the outer sections of the spokes 3 to the bone with a bone plate 4 (or bone plates) with holes using screws 5, screwed into the bone (see Fig. 4).

Thus, the implementation of the claimed method of subchondral stressed reinforcement makes it possible to create, using a combination of stressed spokes, a damping stressed compression of the combined bone fragments, preventing their secondary displacement after surgery, and, due to additional resistance to axial load due to reliable fixation of the ends of the spokes in the holes in the bone, to eliminate the possibility of displacement of the ends of the spokes from under the bone plate and the development of vertical instability of the stressed spokes.

Clinical example 1.

Patient C, 42 years old.

Diagnosis: The patient was hospitalized in the trauma department with the diagnosis: Closed intra-articular comminuted fracture of the lateral condyle of the right tibia with displacement, closed intra-articular fracture of the distal epimetaphysis of the right tibia with displacement (see Figs. 5 and 6, 7 and 8).

Treatment scheme: Upon admission, plaster immobilization was performed. After the edema subsided, the patient underwent surgical treatment in two stages. On the seventh day after the injury - open reposition, external osteosynthesis of the distal epimetaphysis of the right tibia with a supporting titanium plate with reinforcement of the fragments of the articular surface with stressed U-shaped pins, performed according to the claimed method (see Figs. 9 and 10). During the operation, the pins were bent at angles of 133° and 95°. On the eleventh day after the injury, the second stage of surgical treatment was performed: open reposition of the lateral condyle of the right tibia, external osteosynthesis with a titanium plate with angular stability and reinforcement of the fragments of the articular surface with stressed U-shaped pins, performed according to the claimed method (see Figs. 11 and 12). During the operation, the needle bends were made at angles of 135°, 140° and 90°, 92.5°.

In the postoperative period, therapeutic physical training was performed, walking with additional support means - crutches. Full load on the limb began from the fourth month.

Treatment results: Movements in the knee and ankle joints were fully restored, the joints are stable. The patient returned to professional activity. No secondary fracture displacement was noted.

Clinical example 2.

Patient M., 44 years old.

Diagnosis: Hospitalized with the diagnosis: Closed fracture of the distal epimetaphysis of the left tibia with displacement. Closed fracture of the lateral malleolus of the left leg with displacement (see Figs. 13 and 14).

Treatment scheme: Initially, plaster immobilization was performed. On the tenth day after hospitalization, after the swelling had subsided, the patient underwent surgical treatment: open reposition of the distal epimetaphysis of the left tibia, osteosynthesis with an AO titanium plate with angular stability, a supporting titanium plate with reinforcement of bone fragments of the articular surface with stressed U-shaped pins, made according to the claimed method (see Fig. 15). During the operation, the pins were bent at angles of 130°, 137° and 94°, 91°.

At the stage of fracture fusion, rehabilitation was performed in the form of therapeutic physical training with a gradually increasing load on the limb. Full body weight load was carried out from the fourth month after osteosynthesis.

Treatment results: As a result of the treatment, the full range of motion in the ankle joint was restored, the patient returned to her professional duties. No secondary displacement of the fractures was observed.

The claimed method of subchondral stressed reinforcement, in comparison with the prototype, has a higher therapeutic efficiency and quality of treatment due to the elimination of the possibility of displacement of the ends of the spokes from under the external fixation apparatus and the development of vertical instability of the stressed spokes.

In addition, the claimed method is easier to use clinically and allows to reduce the time of the operation.

Claims (1)

A method of subchondral reinforcement of intra-articular bone fractures, including subchondral insertion of two spokes through fragments of the articular surface of the bone, bending the outer ends of the spokes and pressing them to the bone with a plate using screws, characterized in that the fragments of the articular surface of the bone are repositioned and fixed by inserting the spokes; the outer ends of the spokes are bent at the articular surface at an angle of 130-140°, then distal to the first bend at the level of the intact bone, the spokes are bent in the same plane at an angle of 90-95°, the entry points of the bent ends of the spokes into the intact section of the bone are marked and holes are made, the bent ends of the spokes are immersed in the holes until they stop in the bone and the outer sections of the spokes are pressed to the bone with a plate using screws.