RU2017461C1 - Method for treating false joints and retarded consolidation of shin ossa fractures - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: essence of this method resides in fixing extremity in required position using external fixation apparatus, providing compression of fragments, subperiosteally positioning demineralized osteal allotransplant, and then exposing nonadhesive zone to low-intensive audio-frequency electromagnetic field during post-operative period. EFFECT: adhesion period reduced by two months.

Description

 The invention relates to medicine, namely to traumatology and orthopedics, and is intended to accelerate the fusion of bone fragments in patients with pseudoarthrosis and delayed consolidation of fractures of the lower leg.

A known method of stimulating osteogenesis, including in patients with impaired reparative processes (Klyavins I.E. et al., Author St. N 973109, 1980), when an area of damaged bone tissue is affected by an alternating pulsed electromagnetic field with an amplitude of 0.1 -2.0 mT, with a duty cycle of 10-10 ³ , a width of the amplitude spectrum of harmonic components from 0-10 kHz to 0-200 kHz and a current shape factor of 3.2-36.5. The duration of treatment is 2-8 months. The method was applied in 31 patients with overgrown fractures and false joints. The limb supportability during the implementation of the proposed method is restored 2 months earlier in comparison with the known methods of treating false joints.

 However, in this case, the method is performed without prior surgical intervention aimed at stabilizing bone fragments, which is an important condition for consolidation, since it is known that the instability of fragments is one of the main causes of violation of osteoreparation. It should be noted that although in this method there is such a powerful factor for optimizing osteogenesis as a low-intensity electromagnetic field, but it is present only one, and the point of application is only tissue of the false joint.

 In the proposed method, there are several factors for optimizing osteogenesis (low-intensity electromagnetic field and morphogenetic protein of decalcified allograft), which are already quite powerful in themselves, but, acting together, against the background of stabilization of bone fragments by an external fixation apparatus, enhance the overall effect of exposure, because It is known that a weak, variable, pulsed electromagnetic field accelerates calcification, decalcification and demineralization, and also affects the synthesis and tabolism of the organic matrix of bone tissue (Tkachenko S.S., Rutsky V.V., 1975; Pfafrod G.O. et al., 1987; Bassett, 1984). Thus, the electromagnetic field acts on the tissues of the false joint and the decalcified transplant, accelerating their transformation, and the morphogenetic protein of the decalcified transplant, being a powerful osteoinducer and activating under the influence of the electromagnetic field, in turn enhances the reparative processes in the tissues of the false joint.

 Closest to the claimed is a method of treating patients with false joints of the tibia by compression-distraction osteosynthesis, in which the non-fusion zone in the postoperative period is exposed to direct electric current (cathodic polarization) of 6-20 μA, published in the book "Theoretical and practical aspects of transverse compression and distraction osteosynthesis ", Kurgan, 1976, S. 233-234.

 In the proposed method and prototype, the periods of bone consolidation are the same, but it should be noted that the age of patients treated up to 60 years, and in the prototype method up to 27 years. It is well known that at a younger age, reparative processes are most pronounced. The negative point of the prototype method is also the invasiveness of the technique, when the spoke electrode passes near or directly through the zone of the pseudoarthrosis. Around the electrode often appears irritation and inflammation of the skin, patients experience discomfort. In the proposed method, electromagnetic action is carried out on the zone of the pseudoarthrosis through the skin, without even contacting it, while at the same time causing the same changes in the tissues of the pseudarthrosis as the current. The point of application of electromagnetic waves in the proposed method is also a morphogenetic protein of decalcified bone allograft, which, activated by the action of an electromagnetic field, accelerates the process of consolidation.

 The aim of the invention is to reduce the treatment time and reduce the number of unsatisfactory outcomes in the treatment of patients with impaired reparative osteogenesis of the lower leg bones.

The method according to this invention is as follows. Extragneous osteosynthesis of fragments and alloplasty of the non-fusion zone with a demineralized bone graft were performed in patients with pseudoarthrosis of the lower leg bones. From the sixth day after the operation, the false joint zone was irradiated with a low-intensity electromagnetic field of the sound frequency range using the Alpha Pulsar electromagnetic field generator. The field strength during irradiation is 0.1-2.0 mT, duty cycle 10-10 ³ , the width of the amplitude spectrum of the harmonic components of the current pulses from 0-20 kHz to 0-200 kHz, the current shape factor 3.2-36.5, exposure duration on the first day 30 minutes, then the exposure increased by 10 minutes daily, ultimately reaching 120 minutes. An increase in the exposure of radiation in dynamics is due to an increase in the efficiency of electromagnetic exposure (Demetsky A.M. et al., 1980). The course of treatment was 3 weeks. This is enough to start the process of osteoreparation, then it proceeds in the self-regulation mode (Degen I.L., 1970, 1971; Kaplan A.V. et al., 1980, 1981, 1982; Landa V.A., 1982; Heitner H. et al., 1987; Bassett, 1978). At an exposure of 30-90 minutes, the device worked in I mode (with a constant pulse frequency of 50 Hz), at an exposure of 100-120 minutes the device worked in II mode (the pulse frequency became random), this excluded the adaptation of irradiated tissues to the factor of external physical impact. Inductor windings were applied bilaterally, strictly symmetrically to each other, parallel to the long axis of the limb.

 For alloplasty used bone tissue taken from a corpse and demineralized with hydrochloric acid according to the methodology adopted in LNIITO them. R.R. Vredena (Savelyev V.I., 1989). Extra focal osteosynthesis was performed under conduction anesthesia (V. Kustov, 1987) according to the method of G.A. Ilizarov (1954).

 To perform alloplasty of the non-fusion zone, a soft tissue incision was made to the bone over the projection of the pseudoarthrosis, the periosteum was peeled off and 5-8 pieces of allo bone were placed periosteally, measuring 0.2 x 0.5 x 5.0 cm from all sides, surrounding the bone. After hemostasis, the wound was sutured in layers. In the postoperative period, patients were not allowed to walk for 2-3 days. After that, patients began to walk with a gradual load on the sore limb.

 Monitoring the progress of the reparative process was carried out clinically and radiologically. Osteometry, thermometry, rheovasography, and thermal imaging were also used.

 Patient B., 29 years old, I / B 4269/89 was admitted to the 10th department on 19/09-1989, with a diagnosis of pseudarthrosis of the left tibia in the middle third. Injury 9/10/1988 - road, with a diagnosis of open fracture of both bones of the left lower leg in the middle third was treated in the CRH with skeletal traction, then a circular gypsum dressing was applied for 3 months. The fracture did not grow together. Operated in a military hospital - made a metal osteosynthesis of a tibia with a plate and immobilization with a circular plaster cast for the middle third of the thigh for 4.5 months. The fracture did not grow together, there was a fracture of the metal structure and the formation of the false joint of the tibia. Operated at LNIITO on 09/27/1989 - extrafocal osteosynthesis and alloplasty of the false joint were performed with a demineralized bone graft. In the postoperative period, the area of the false joint was irradiated with low-intensity electromagnetic energy. The postoperative period is smooth, the wound healed first. Radiologically, 2 months after the operation, enhanced periosteal corn formation was noted. 4 weeks after surgery, the patient fully loaded the operated limb. The consolidation of bone fragments, confirmed by x-ray and osteometric research methods, was completed by the end of the 5th month from the day of surgery. Significant periosteal callus was clinically observed, there were no pains when walking in the area of bone damage. After removal of the external fixation apparatus, additional immobilization of the lower leg was not required; the patient immediately began treatment aimed at restoring the function of the joints of the limb.

Claims (1)

 METHOD FOR TREATMENT OF FALSE JOINTS AND SLOW CONSOLIDATION OF FOOT BONE FRACTURES by fixation and compression of fragments by an external fixation apparatus, characterized in that, in order to accelerate the fusion, an additional subperiosteal demineralized non-invasive bone-bearing allograft is placed into the region of the pseudarthrosis, and the electrosurgery is sound frequency field.