RU2739856C1 - Method of treating compression fracture of vertebral bodies in children - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention refers to medicine, namely to physiotherapy and traumatology, and can be used for treating compression fracture of vertebral bodies in children. Shock wave is exposed to posterior parts of injured vertebra. Intensity of shock wave action is selected depending on individual tolerability of the procedure by the child. Number of exposure pulses should not exceed 10 thousand per procedure; the procedures are performed with course of 5-10 procedures with an interval of not less than 3 days. Shock wave can be focused or defocused. Shock wave exposure can be applied to a spinous process of the vertebra or a spine of the vertebral body.EFFECT: method provides more complete recovery of the compressed area of the vertebral body due to shock wave action in an individually selected mode.5 cl, 1 ex

Description

The proposed invention relates to the field of medicine, in particular to pediatrics, namely to physiotherapy and traumatology of orthopedics, and can be used in medical and medical institutions for the treatment of patients with compression fractures of the spine or wedge-shaped deformities of the vertebral bodies in orthopedic diseases (for example, disease Shoerman-Mau) in children.

The urgency of the problem of rehabilitation of children with a compression fracture of the spine is due to the high frequency of this pathology among the pediatric population. Over the past 10 years, children have seen an increase in spinal injuries caused by external causes. According to the statistics, the incidence of injuries among children does not tend to decrease. Along with an increase in the number of patients with trauma, the severity of clinical manifestations also increases. The emergence of anatomical and functional changes in the musculoskeletal system, the possibility of complications justify the search for new means of conservative therapy in the early stages of treatment of compression fractures in children [1].

At present, various methods of treating compression fractures of the spine using physical factors are known. Known methods of treating compression fractures of the spine in children using a low-frequency alternating magnetic field. It is generally accepted that magnetotherapy has a good analgesic effect, which favorably affects the reparative regeneration of the area of damaged vertebrae. The impact is carried out from the back above and below the injury site. A sinusoidal or half-wave form of the magnetic field is applied in a continuous mode, for a course of 10-15 impacts. However, the disadvantage of using this method is a certain limited effect in multiple localization of injury, as well as the need for a longer course of treatment to achieve the desired result, the lack of pathogenetic substantiation of the influence of magnetic fields on the processes of osteoreparation [2].

The closest in technical essence to the proposed method is a method of treating a compression fracture of the vertebral bodies in which the patient in the supine position is exposed to a physiotherapeutic effect, characterized in that the effect is carried out by a running pulsed magnetic field from the ALMAG apparatus, while the inductor coils are placed contact along spine over the projection area of the compression fracture, induction 20 mT, exposure time - taking into account the child's age: for children 8-11 years old - 8 minutes, 12-14 years old - 10 minutes, procedures are carried out daily, for a course of 8-10 procedures and from 3 -5 days, depending on the dynamics of clinical manifestations, children are prescribed a course of physiotherapy exercises for 1 complex, daily, No. 8-10 procedures [3].

The ALMAG magnetotherapy device, used in this method of treatment, is equipped with a flexible tape, into which four round inductors are mounted, which allows these inductors to be placed along the spine to increase the effect of the magnetic field. Nevertheless, the above invention (prototype) has its drawbacks, namely, there are no data confirming the pathogenetic chronobiological effect of low-frequency magnetic fields on osteoreparative processes, including compression fractures.

The technical result of the proposed method for the treatment of compression fracture of the vertebral bodies in children is to provide a pathogenetic effect on the injured bone tissue based on the laws of chronobiology of the injured vertebral body for the purpose of trophikostimulating and osteoreparative effects, which allows earlier and more fully restore the compressed vertebra.

The specified technical result is achieved by the fact that the patient in the supine position is exposed to a shock wave, while the impact is on the posterior parts of the damaged vertebra, the intensity of the shock wave is selected depending on the child's individual tolerance for the procedure, while the number of exposure impulses should not exceed 10 thousand per procedure, procedures are carried out in a course of 5-10 procedures with an interval of at least 3 days.

This effect provides a trophic-stimulating and osteoreparative effect, which allows earlier and more complete restoration of the compressed vertebra.

A defocused shock wave can be used for exposure.

A shock wave can be applied to the spinous process of the damaged vertebra. It is advisable to apply the emitter of the defocused shock wave to the spinous process of the damaged vertebra, as to the closest point on the skin. A feature of a defocused shock wave is its rapid attenuation in soft tissues at a distance from the pulse source.

A focused shock wave can also be used for exposure.

The impact of a focused shock wave can also be applied to the arch of the vertebral body, since it has a sufficient penetration depth while maintaining a given impact intensity.

DESCRIPTION OF THE METHOD

The patient in the initial lying position is exposed to a shock wave generated by a medical shock wave therapy apparatus on the posterior parts of the damaged vertebral body according to standard techniques (through a gel for physiotherapy). To exclude damage to the bone structure of the zone and provide a trophico-stimulating and osteotropic effect on the damaged vertebra, the intensity of the shock wave is chosen depending on the individual tolerance of the procedure by the child, while the number of exposure impulses should not exceed 10 thousand per procedure, the procedures are carried out in a course of 5-10 procedures with at least 3 days apart. According to the literature, a safe effect, including for cartilaginous tissue (which can conditionally include the tissues of the growth zones of the vertebra), is considered to be an effect with an energy density of no more than 0.5 MJ / mm ² . The higher power of the focused wave should be used with caution due to the existing publications on the adverse effects of the high-energy focused wave on the articular cartilage in laboratory rats (0.5 MJ / mm ² ) [4].

The number of impact impulses should not exceed 10 thousand in the case of using a defocused or focused shock wave. The shock wave emitter is applied to any posterior parts of the injured vertebra (spinous process or vertebral arch). The procedures are carried out with an interval of at least 3 days. There are 5-10 procedures per course. Repetition of the course of procedures is possible in 3 months.

RATIONALE FOR USING THE METHOD

In the modern literature, there are many publications on the effect of shock wave therapy (SWT) on the human musculoskeletal system.

There are numerous publications devoted to the effect of shock wave therapy on delayed consolidation of bone tissue. Under the influence of shock wave therapy in the bone marrow in the traumatic area, vasodilation occurs, as well as the release of blood cells from capillaries and sinusoidal vessels with the creation of massive areas of bone endosteal regenerate, which guarantees restoration of bone integrity, an increase in neovascularization and an increase in the regulation of angiogenic and osteogenic growth factors. The effect of the shock wave on the proliferation and osteogenic differentiation of human bone marrow mesenchymal stem cells is described.

UHT increases the proliferation and osteogenic differentiation of bone marrow stem mesenchymal cells [5, 6].

Due to the fact that mechanical stress through shock wave therapy is the strongest stimulus for the proliferation of bone tissue cells, one should associate this mechanical stress with piezoelectric effects occurring in bones [7].

In order to assess the remote effects of shock wave therapy, we carried out an experimental study in the course of which we evaluated the effect of radial shock wave therapy on the formation of piezoelectric discharges in the native bone outside the zone of direct exposure to the shock wave.

In the course of the experiment, it was found that the shock-wave effect on the bone causes the formation of piezoelectric discharges of maximum amplitude in the affected area with a gradual attenuation within one bone (not only in the affected area). It was found that piezoelectric discharges are recorded along the entire bone at a distance from the point of application of the shock wave. At the same time, it was noted that the shock-wave pulse forms piezoelectric discharges within one bone (it does not propagate to the conjugate bone ones, i.e., a shock-wave pulse applied to one vertebra causes piezoelectric charges only in this vertebra, and at a distance, but not causes piezoelectric discharges in adjacent vertebrae). This is consistent with the laws of distribution of acoustic waves in the medium (reflection, refraction, scattering ...). The maximum dissipation of shock wave energy will occur at the boundaries of contacts between media with different acoustic densities (in this case, bone and soft tissues, including intervertebral discs, growth zones). Thus, practically all the energy of the shock wave propagating through the bone will be dissipated at the points of contact between the bone and soft tissues (articular cartilage, synovial membrane, muscles) and will not be transferred to the adjacent bone.

Thus, a shock wave applied to the posterior parts of the vertebral body will cause piezoelectric discharges of various magnitudes in the entire volume of its bone mass and will have a tropostimulating and osteoreparative effect at a distance from the zone of direct contact within one bone segment.

EXAMPLES OF IMPLEMENTATION OF THE METHOD

Example 1. Patient A., 14 years old with a diagnosis of Compression fracture of the spine Th9. From the anamnesis it is known that the child was injured when falling from the horizontal bar. After the injury, there was a delay in breathing, there were complaints of back pain. The patient went to the emergency room, from where he was sent for hospitalization on an emergency basis. Upon admission: the condition is satisfactory. No complaints. Somatically healthy. Locally: visually the area of the back is not changed, with palpation and percussion of the thoracic spine, there is pain in the projection of the Th8-Th11 vertebrae. On spondylograms: decrease in body height, wedge-shaped deformity of the Th9 body. According to the results of MRI, a compression fracture of the Th9 vertebra was confirmed.

In the department, the child was on bed rest, was consulted by a physiotherapist, underwent a course of radial shock wave therapy on the spinous process of the Th9 vertebra, 5 procedures, an applicator 15 mm, exposure power 4 bar, the number of impulses 5 thousand per procedure, the interval between procedures 5 days. After completion of treatment, he was discharged home. On the control spondylogram a year after the moment of injury, there was a complete restoration of the height of the anterior section of the compressed vertebra.

The proposed method for the treatment of compression fracture of the spine in children was carried out in 15 patients, aged 14 to 16 years, who were inpatient treatment in the Department of Traumatology and Orthopedics.

As a result of the treatment by the proposed method, a favorable dynamics of the indicators for assessing the orthopedic status was established, a more complete restoration of the height of the anterior sections of the compressed vertebrae in the long-term period. The results achieved make it possible to expect that the proposed method of treatment will significantly prevent the development of post-traumatic spinal deformities and spondylopathies as the patient grows older.

Bibliography

1.R.L. Gally, D.W. Spite, P.P. Simon - Orthopedic Emergency. Spine, 1995, p. 335.

2. A.A. Ushakov, Practical Physiotherapy, - Medical Information Agency, Moscow, 2009, p. 134.

3. RU No. 2489180, Method for the treatment of compression fracture of the spine in children. Published: 10.08.2013. Bul. No. 22.

4. Mayer-Wagner S, Ernst J, Maier M, Chiquet M, Joos H, Miiller PE, Jansson V, Sievers B, Hausdorf J. The effect of high-energy extracorporeal shock waves on hyaline cartilage of adult rats in vivo // J Orthop Res. 2010 Aug; 28 (8): 1050-6. doi: 10.1002 / jor.21074.

5. H. Lohrer, T. Nauck, V. Korakakis, N. Malliaropoulos. Historical ESWT Paradigms Are Overcome: A Narrative Review // Biomed Res Int. 2016; 2016: 3850461. doi: 10.1155 / 2016/3850461.

6. Jai-HongCheng, Ching-Jen Wang. Biological mechanism of Shockwave in bone // International Journal of Surgery. Volume 24, Part B, December 2015, Pages 143-146, PMID: 26118613, doi: 10.1016 / j.ijsu.2015.06.059.

7. E. Fukada, I. Yasuda, On the Piezoelectric Effect of Bone // Journal of the Physical Society of Japan • October 1957, 12 (10): 1158-1162.

Claims (5)

1. A method of treating a compression fracture of the vertebral bodies in children by applying a physiotherapeutic effect on the patient in the initial lying position, characterized in that a shock wave is applied, while the effect is on the posterior parts of the injured vertebra, the intensity of the shock wave is chosen depending on individual tolerance procedures by a child, while the number of impulses of exposure should not exceed 10 thousand per procedure, procedures are carried out in a course of 5-10 procedures with an interval of at least 3 days. 2. The method according to claim 1, characterized in that a focused shock wave is used. 3. The method according to claim 1, characterized in that a defocused shock wave is used. 4. The method according to claim. 1, characterized in that the impact of the shock wave is applied to the spinous process of the vertebra. 5. The method according to claim 1, characterized in that the impact of the shock wave is applied to the arch of the vertebral body.