RU2467715C1 - Method for stabilising vertebral body fractures complicated by osteoporosis - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, particularly vertebrology. A threaded rod is introduced in an injured vertebra, and cannulated threaded rods are introduced superjacent and subjacent vertebrae. Bone cement is introduced through the cannulated threaded rods into the vertebral bodies. It is followed by the transpedicular introduction of the threaded rods into the superjacent and subjacent vertebral bodies next nearest the injured one. On free ends of the rods, there are fixed support plates of a reposition device so that one plate fixes two vertebrae: with and without cement. The plates are coupled with screw pull rods movable relatively to each other. A free end of the threaded rod of the injured vertebra is attached to the central screw pull rod of the reposition device. Deformation is corrected. Displacement elimination and vertebral canal reconstruction is followed by rigid fixation of the external reposition device, and connection of the threaded rods introduced into the injured and adjacent vertebrae by screw bars in a position of maximum adaptation to a vertebral shape. The reposition device is removed.

EFFECT: method enables correcting all types of vertebral deformation and stabilising the injured segment.

1 ex, 1 dwg

Description

The invention relates to medicine, namely to the treatment of vertebral fractures complicated by osteoporosis.

Known methods for treating spinal fractures using transpedicular fixation systems (http://www.spineinfo.ru/systems/transpedfixation/), however, it is practically impossible to effectively treat vertebral fractures complicated by osteoporosis. The transpedicular screws are difficult to firmly fix in the vertebral body with a reduced mass of bone tissue and with a violation of its microarchitectonics. In addition, over time, the screws become loose (migrate) and the entire transpedicular fixation system loosens. The use of more transpedicular screws for fixation does not guarantee the exclusion of subsequent migration of screws and, in addition, leads to more trauma to bone tissue.

A known method of stabilization of the spine using a transpedicular fixation system in the presence of a pathologically altered vertebral structure (US Pat. No. 2285483). Each screw is made with a cavity for injecting bone cement into the vertebral body, through which bone cement is injected into the vertebral body. The screws of the transpedicular fixation system are inserted into the overlying and underlying whole vertebrae from both sides so that the screw passes through the leg of the vertebra into his body. Bone cement is injected into the vertebral bodies. Mount the stabilizing part of the transpedicular fixation system on the screws. The final fixation of the transpedicular fixation system is carried out after the reclamation of the spine.

However, the method does not allow restoration of the shape of the damaged vertebra and adjacent intervertebral discs, providing only stabilization in the position of the existing deformation.

The technical problem is the elimination of post-traumatic deformity of the spine and ensuring stable fixation of the spinal-motor segment in vertebral fractures complicated by osteoporosis, is solved as follows.

In the proposed method for stabilizing vertebral fractures complicated by osteoporosis, including access to the back surface of the damaged vertebra and to the overlying and underlying vertebrae adjacent to it and stabilization of the vertebral motor segment by the internal transpedicular system and bone cement, according to the technical solution, first into the damaged and higher and thoracic rods are transpedicularly introduced to the underlying osteoporotic vertebrae, and cannulated p is introduced into the bodies of the upper and lower vertebrae threaded rods through which bone cement is injected into the vertebral bodies, then threaded rods are introduced into the vertebral bodies, located one from the damaged one, and an external reposition device is mounted, the support plates of which are placed on the cannulated threaded rod and the threaded rod introduced into the vertebra through one from damaged, the support plates are interconnected by screw rods with the possibility of movement relative to each other, while the free end of the threaded rod introduced into the damaged vertebra is attached to the screw rod of the external reposition device, correction of the deformation of the spine and the reclamation of the damaged vertebra are carried out, after which the threaded rods inserted into the damaged and adjacent vertebrae are fixed with screw rods of the internal transpedicular system, and the external reposition device is dismantled.

The use of an external reposition device, the support plates of which are mounted on the free ends of the threaded rods and cannulated threaded rods, makes it possible to carry out controlled dosed reposition of the vertebrae in all planes and to develop compression and distraction forces of the required size to displace the vertebrae until all types of spinal deformities are completely eliminated, including including the elimination of chronic wedge-shaped spinal deformities and kyphotic spinal deformities in fractures. Fixing two vertebrae with one supporting plate and the ability to move the plates relative to each other, as well as fixing the free end of the threaded rod inserted into the damaged vertebra to the screw rod of the external reposition device, can purposefully affect the motor vertebral segment and the damaged vertebra during reposition in any plane and rigidly to fix them in the achieved position. The introduction of bone cement into the bodies of osteoporotic vertebrae through cannulated threaded rods allows the rods to be fixed for subsequent reliable manipulation of the vertebrae, and also strengthens the vertebral bodies, i.e. increases their mechanical strength, which reduces the risk of loosening of the threaded rods of the internal transpedicular system, increases the support ability of the spinal column. Rigid fixation by an external reposition device allows, without changing the physiologically correct position of the spine, achieved during correction, to carry out internal fixation of the damaged vertebral segment. Reliable fixation of the damaged vertebral segment by the internal transpedicular system helps prevent damage to nerve structures (spinal cord or roots), ensure early activation of the patient, and help optimal fusion of bone structures.

In the Ural Institute of Traumatology and Orthopedics, the proposed method performed more than 22 operations in patients with vertebral fractures complicated by osteoporosis. In all cases, deformation was corrected and the spinal column was strengthened, and the complete restoration of the shape of the damaged vertebral motor segment was achieved. Patients are activated on the 3-5th day after surgery. None of the patients showed inflammatory phenomena from the operated tissues.

Thus, the proposed method allows for metered controlled correction of existing spinal deformities in vertebral fractures and the presence of osteoporosis and to reliably stabilize the restored vertebral segment.

To implement the method, standard parts from the device for external fixation of the spine and internal transpedicular system are used.

An external reposition device consists of two supporting arcuate plates with longitudinal slots in which threaded rods are attached through expansion washers (convex and concave). The threaded rods are fixed so that one supporting arcuate plate fixes two adjacent vertebrae (the motor segment of the spine). The supporting arcuate plates through the brackets are interconnected by a central screw rod, consisting of two parts connected by a hinge and two side screw rods. Side screw rods are connected to the brackets through expansion washers.

The transpedicular system includes transpedicular cannulated threaded rods, screw rods, and blockers.

Surgery is performed under endotracheal anesthesia in the position of the patient on the abdomen. The skin incision is made in the midline over the spinous processes for 1-2 vertebrae above and below the damaged. The spinous processes and arches are skeletonized to the base of the transverse processes, locate and insert a threaded rod into the damaged vertebra and cannulated threaded rods into the upper and lower vertebrae. Depending on the integrity of the vertebral arch, a threaded rod is inserted into the damaged vertebra transpedicularly or directly into the body of the damaged vertebra. Bone cement is injected through the cannulated threaded rods into the bodies of the upper and lower lying, from the damaged, vertebrae. The overlying and underlying vertebrae located through one healthy from the damaged vertebra are determined, and threaded rods are introduced transpedicularly into them. To do this, use a pliers to remove the cortical layer of the arch to the cancellous bone above the site of insertion of the rod, with the help of an awl, outline and form the inlet channel along the arch to a depth of 3 cm.A suitable size threaded rod is inserted into the channel with a screwdriver and inserted into it with rotational movements. Then, at the free ends of the rods, with the help of compensating washers, arcuate support plates are fixed so that one plate fixes two vertebrae. The plates are interconnected using brackets and screw rods (central and two side). In this case, the support of the rods on the bracket also occurs by means of expansion washers. The free end of the rod inserted into the damaged vertebra is attached to the central screw rod of the external reposition device. Then, due to the possibility of moving the arched support plates of the external reposition device relative to each other, deformation correction (in all planes) of the damaged vertebral segment is performed. If necessary, for additional reposition and maintaining the system in tension use the compression-distraction efforts of the screw rods of the device. To do this, the middle link is mounted on the base plate using long brackets. Two lateral screw rods are fixed along the lateral edges of the support plates with shorter brackets. The position of the vertebrae is controlled using an X-ray apparatus with an image intensifier tube and visually according to the level of location of the support plates. After eliminating all types of vertebral displacements and restoring the shape of the spinal canal, all the nuts on the screw rods of the external reposition device are rigidly fixed. The internal transpedicular system is mounted on the damaged vertebral segment, for which the threaded rods are inserted pedpedically into the damaged and adjacent vertebrae with screw rods in the position of maximum adaptation to the shape of the spine. The external reposition device is dismantled. Layer wound closure is performed. All manipulations are carried out under image intensifier control.

Clinical example. Patient P., 66 years old, was treated at the UNIITO from 08/29/10 to 09/18/10 with a diagnosis of a pathological fracture of the L ₁ vertebral body (type A ₂ ). Systemic osteoporosis.

The operation was performed in the clinic: transpedicular spondylosynthesis of Th _XII- L _I -L _II vertebrae by the proposed method. Figure 1 presents x-ray; A - before the operation; B - after the operation.

For the operation, we used the details from the kit for transosseous spinal osteosynthesis of the Research Institute “Synthesis” (reg. Certificate No. FSR 2008/02148) and the external fixation device for the spine “Crab” (reg. Certificate No. FS 022b2004 / 1906-05). In the body of the vertebrae adjacent to the damaged, cannulated screws (rods) were installed through which bone cement was introduced. The body of the damaged vertebra L _I transpedicular have entered the threaded rod whose free end is further joined to an external screw rod reposition the device. In the body of Th _XI ; L _III vertebrae introduced transpedicular threaded rods of the "Crab" system. An external reposition device is mounted. Performed post-traumatic deformity correction. Restored the height of the damaged vertebra. The threaded rods of the internal transpedicular structure were fixed on the rod. An external reposition device was dismantled; external transpedicular screws from Th _XI bodies; L _III vertebrae removed.

Post-traumatic spinal deformity is eliminated, the shape of the damaged vertebra and adjacent intervertebral discs is restored, the damaged vertebral-motor segment is stabilized. On the second day, the patient was activated. A year later, computed tomography of the spine showed the preservation of the achieved correction of spinal deformity, the fusion of a vertebral body fracture.

Thus, the proposed method allows in the presence of osteoporosis to correct all types of spinal deformities and stabilize the damaged vertebral segment in vertebral fractures. The operation is effective and can be recommended for widespread use.

Claims (1)

A method for stabilizing vertebral fractures complicated by osteoporosis, including access to the posterior surface of the damaged vertebra and to the overlying and underlying vertebrae adjacent to it, stabilization of the vertebral motor segment by the internal transpedicular system and bone cement, characterized in that in the bodies of the damaged vertebra both above and below threaded rods are introduced pediculously from the damaged vertebrae, while cannulated threaded rods are inserted into the upper and lower vertebrae through the cat Orthogonal bone cement is introduced into the vertebral bodies, then threaded rods are inserted pediculously into the vertebral bodies located one after the damaged, and an external reposition device is mounted, the support plates of which are mounted on the cannulated and threaded rod inserted into the vertebra through one from the damaged one, the supporting plates are connected interconnected by screw rods with the possibility of moving relative to each other, while the free end of the threaded rod inserted into the damaged vertebra is attached to the screw rod in eshnego reposition the device, operate the spinal deformity correction, and then fixed threaded rods introduced into the damaged body and upstream and downstream from it vertebrae, transpedicular screw rods internal system and the external device reposition dismantled.

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