RU2695893C1 - Method for surgical treatment of destructive spinal diseases - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to medicine. Method of surgical treatment of destructive spinal diseases consists in the fact that for substitution formed in the process of resection of defect spines, a composite implant is used: two support discs of porous bioinert material, between which there is a mesh brace of a container type, filled with bone cement with an antibiotic. Diameters of discs correspond to diameter of mesh brace and have rough surfaces for contact with bone.EFFECT: invention provides a strong support for an anterior column of the spinal column with a depot of large-volume antibiotics and sites for implant consolidation with small-volume vertebral bone tissue, but a large cross-sectional area.1 cl, 2 dwg, 2 ex

Description

The invention relates to medicine and can be used in traumatology, orthopedics, phthisiology and neurosurgery in the section of surgical vertebrology in the treatment of destructive diseases of the spine (spondylitis of any etiology, tumors, degenerative diseases, injuries).

A known method of surgical treatment of destructive diseases of the spine [Daniel X. Kim and others. "Spine. Surgical anatomy and operative technique ”, Moscow 2016, Panfilova Publishing House LLC, p. 784], which consists in resection of one or several vertebrae, stabilization and replacement of the defect with an autograft.

This method does not allow to begin early activation of the patient due to the lack of adequate supportability for the anterior column of the spine, in addition, during surgery for spondylitis there is a high probability of getting infectious complications and relapse. Often there are resorption and fracture of the graft. In addition, these surgical aids require additional surgical trauma in the form of an auto-osteograft graft (autobone).

A known method of treating destructive diseases of the spine "An implant for the treatment of hematogenous osteomyelitis of the spine" [Patent RU No. 129793 of 07/10/2013], in which an implant (spacer, polymethyl methacrylate implant) made of bone cement is used to replace the defect.

With this method, the frequency of infectious complications is small, but due to the lack of fusion (integration) of the implant with the bodies of the upper and lower vertebrae, the polymethylmethacrylate implant is often destabilized and requires subsequent surgical intervention to replace the spacer with a stabilizing implant. In addition, a bone cement spacer is poorly visualized by X-ray methods.

The closest technical solution for the treatment of destructive diseases of the spine is "A porous titanium implant to replace the vertebrae and interbody discs" [Patent RU No. 160 822 of 02/13/2015], which consists in resection of one or more vertebrae, stabilization and replacement of the defect with an implant made of porous titanium alloy. In this case, the fusion of the implant-bone system is achieved. Which leads to an early and persistent rehabilitation of the patient. But the danger of infectious complications remains, especially with interventions for infectious spondylitis.

The objective of the invention is to improve the quality of surgical treatment of patients with spondylitis of any etiology, tumors, degenerative diseases and injuries of the spine, due to the creation of a stable joint implant-vertebra, high-quality support of the anterior column of the spine with the formation of an antibiotic depot.

The problem in the method for the treatment of destructive diseases of the spine is solved as follows: in the use of biocompatible porous implants (e.g. nitinol, trabecular titanium, porous bioceramic implants, etc.), a mesh spacer of the container type (mesh cage) and bone cement with an antibiotic.

Known methods perform online access to the bodies of the affected vertebrae, radical removal of the affected tissue and decompression of the spinal cord in the required volume, then, before the introduction of the composite implant, the affected spine is reclaimed (repositioned). The size of the defect of the spine is determined. According to the received size, they cut the mesh strut of the container type and completely fill it with bone cement with an antibiotic. Before cement polymerization, the mesh spacer is closed from both ends with porous biocompatible support discs with diameters corresponding to the diameter of the mesh spacer and a height of 0.5 to 1.0 cm. Complete polymerisation of bone cement is expected. The implant is tightly inserted into the resulting intervertebral diastasis. Reclination is stopped, and the implant is tightly fixed in the bone bed. The surgical wound is drained and sutured in layers.

During the operation, the method of mobile computed tomography, electron-optical or X-ray imaging controls the installation of the implant, namely, the correctness of its position in the bone bed and the correct orientation relative to adjacent contacting vertebral bodies.

If necessary, carry out posterior instrumental stabilization of the spine, in combination with posterior fusion or without it.

A distinctive feature of the claimed method from the prototype is that for the replacement formed during the resection of a vertebral defect, a composite implant is used: two disks made of porous bioinert material, between which there is a mesh strut of container type filled with bone cement with an antibiotic. The size and shape of the implant varies from the size of the replaced defect. During the polymerization of bone cement, a strong bond is formed between all components of the implant. As a result, a solid support is created for the anterior column of the spine with a large volume of antibiotic depots and sites for consolidation of the implant with bone tissue of small vertebrae of large volume, but with a large cross-sectional area.

The invention is illustrated by x-rays, where in FIG. 1-2 in two projections shows a spinal defect replaced by a composite implant: 1 - vertebrae, 2 - porous biocompatible support disk, 3 - mesh spacer, 4 bone cement with antibiotic.

The efficiency of the proposed method is confirmed by the following examples:

1. Patient N., born in 1963, was treated in the department of urogenital and osteoarticular tuberculosis of GBU RO OKTSFP from 07.20.17 to 10.10.17 with a diagnosis of tuberculous spondylitis L2-L3, L5 -S1, complicated by epiduritis, paravertebral spermatic abscesses, chronic vertebrogenic lumbalgia with muscle-tonic syndrome, stage of exacerbation, lower paraparesis.

08.24.17, the patient underwent a two-stage radical reconstructive surgery: 1. Transpedicular spondylosynthesis Th11-S1 in combination with pelvic iliac fixation, 2. Left-sided lumbotomy, L2-L3 corporectomy of the vertebrae, spinal canal decompression, spinal fusion with a composite reinforced mesh implant with mesh antibiotic-bearing bone cement and support platforms made of porous titanium.

On the 7th day after the operation, the patient began to get up, learned to walk on crutches, was engaged in exercise therapy for joints of the lower extremities. After 1.5 months, the patient showed pronounced positive neurological dynamics, complete recovery in the motor and sensory sphere. Control radiographs and computed tomograms for almost 9 months did not reveal signs of relapse and complications of the disease. (Fig. 1 and 2)

2. Patient Tn, born in 1952, was treated in the Department of Urogenital and Osteoarticular Tuberculosis of GBU RO OKTSFP from 7.02.17 to 05.24.2017 with a diagnosis of Th10-Th12 tuberculous spondylitis complicated sap paravertebral abscesses, epidural abscess, compression of the spinal cord. 04/11/17, the patient performed a two-stage radical reconstructive surgery: 1. Transpedicular spondylosynthesis Th8-L3. 2. Right-sided thoracotomy, abscessotomy, Th10 vertebral body resection, Th11-Th12 corporectomy, anterior-lateral decompression of the spinal cord, ventral support spinal fusion with a composite reinforced titanium block-lattice implant made of antibiotic-bearing bone cement and support sites made of porous titanium. On the 10th day after the operation, the patient began to get up, learned to walk on crutches, was engaged in exercise therapy for joints of the lower extremities. After 3 weeks, the patient showed pronounced positive neurological dynamics, complete relief of pain in the spine, and no disorders in the motor and sensory areas were recorded.

The advantages of the proposed method:

- significantly reduces the risk of postoperative infectious-septic complications and the percentage of relapse in infectious lesions of the spine due to the presence of an antibiotic depot in the implant.

- creates a stable fixation of the implant in the intervertebral space, since the existing support discs have rough surfaces, which increases the friction force at the interface between the implant-bone and prevents the implant from migrating. Thus, in combination with the posterior instrumental fixation of the spine, the possibility of early activation and verticalization of the patient in the postoperative period is achieved.

- the porous trabecular structure of the supporting discs creates the conditions for the ingrowth of bone tissue and, as a result, the solid integration of the implant and vertebral bodies, which allows the formation of high-quality fusion.

- the reinforcing mesh strut of the container type (mesh cage) provides strength characteristics of the implant and is an X-ray reference point.

- it is possible to vary the size and shape of the implant depending on the size of the replaced defect.

The inventive method for the surgical treatment of destructive diseases of the spine is used in the surgical tuberculosis department for patients with osteoarticular and urogenital tuberculosis, GBU RO Regional Clinical Center for Phthisiopulmonology, Rostov-on-Don.

Claims (1)

A method of surgical treatment of destructive diseases of the spine, characterized in that for the replacement formed during the resection of the vertebrae of the defect, a composite implant is used, which is represented by two supporting disks made of porous bioinert material, between which there is a mesh strut of the container type filled with bone cement with an antibiotic, the diameters of the discs correspond to the diameter of the mesh spacer and have rough surfaces for contact with the bone.

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