RU2671518C2 - Method of magnetic apposition and immobilization of bone fragments of the facial skull - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to medicine, in particular to surgery, traumatology, and can be used in osteoplastic surgery or in the treatment of patients with bone fractures of different locations. To fix fragments and/or fragments of bones, fixators are installed under the head of which, neodymium magnets with magnetic energy from 302 to 422 kJ/mwere placed, in the form of a ring with a countersink. Then perform a manual reposition of the fragments. Screws, screw nails, rungs, rods can be used as fixators.EFFECT: method, due to the use of fixators with a powerful permanent rare-earth neodymium magnet allows to achieve a sufficient adhesion force and reliably fix the fragments.1 cl, 1 tbl, 5 dwg

Description

The invention relates to medicine, in particular to surgery, traumatology, and can be used when performing osteoplastic operations or in the treatment of patients with bone fractures of various localization.

An electromagnetic device for reposition of fragments in fractures of long tubular bones is known, which comprises an upper rod, a lower rod and an operator, in which the upper rod is movably connected to the operator and the operator is movably connected to the lower rod. An electromagnetic device for reposition of fragments of long tubular bones is characterized in that it additionally has an upper permanent magnet, an iron core, a lead coil and an electronic controller in which the lower part of the upper rod and the permanent magnet are rigidly connected to each other. The upper permanent magnet is located in the operator, the iron core is fixed in the operator, the coil is located outside the iron core so that the axis of the coil coincides with the axis of the upper rod, and the coil is connected to an electronic controller (CN 203524827, A61F 5/042; A61N 2/02).

In this embodiment, it is proposed to use not a method but a device. The device is not based on a magnetic field, but based on an electromagnetic field. Used to reposition, not to immobilize, bone fragments. Quite complicated (consists of a large number of components and quite expensive).

A known system of complex maxillofacial prosthetics on closed implants, which contains an external silicone or plastic prosthesis and at least two flat magnetic implants, each of which is coated with titanium and equipped with flexible tips. Each implant is designed to be placed in the bone bed formed for it. Implants are individually selected in shape and size. After dissection of the soft tissues and the creation of the bone bed, the implant is installed subperiosteally and covered with soft tissues with a thickness of not more than 6 mm. The external part of the prosthesis contains inside itself or on the surface a magnetic element located in the projection opposite to the magnetic implants, which are fixed with flexible ears, the bone surface fixed with titanium screws (EA 201200465 A1, A61F 2/14, A61F 2/50, A61F 2 / 78, publ. 2013.08.30). This method does not apply to reposition and immobilization of bone fragments.

Known compression and distraction apparatus for distraction or compression in a non-invasive manner to the patient’s skeleton or to the implant, which is used to attach the first and second component of the device to the bone (adjacent bones), and all of these elements are interconnected by a magnet connected through an adjustable length reducer and drive means located outside the patient to generate a moving and adjustable electromagnetic field (YU 79702, A61B 17/00; A61B 17/80; A61B 17/86; A61F 2/00; A61F 2/38; A61F 2/44; A61F 2 / 48).

The disadvantage of this device is its massiveness, the need to use an electromagnet, and the fact that it is a compression-distraction apparatus and cannot be used for reposition and immobilization.

A device and method for reposition of long tubular bones is known, in which reposition of fragments of long tubular bones is ensured by a system of magnets and repair rods. The system includes a pair of rod devices, each of which has a flexible rod, at one end of which there is a magnet. The magnetic parts of the rods are inserted into the opposite ends of the bone and move along the bone until the magnets are brought into collinear alignment, in which these rods provide reposition of the fracture (US 5693054, A61B 17/72).

This method requires a significant intramedullary canal for bone reduction and is very traumatic.

The basis of the invention is the creation of a method of magnetic reposition and immobilization of bone fragments of the facial part of the skull, which would be relatively simple and cheap due to the use of clamps with a powerful permanent rare-earth neodymium magnet.

The solution to this problem is provided by the fact that in the method of magnetic reposition and immobilization of bone fragments of the facial part of the skull for fixation into bone fragments for fixation into fragments and / or bone fragments, fixators containing neodymium magnets with magnetic energy from 302 to 422 kJ / m ³ are installed, then perform manual reposition of the fragments. Screws, screws, knitting needles, rods can be used as clamps.

The method can be used for both temporary and final reposition and immobilization of bone fragments (fragments), when performing both intrafocal and extrafocal osteosynthesis. Using the method facilitates the work of the doctor, reduces the risk of intra- and postoperative complications, reduces the patient's rehabilitation time.

In contrast to the known methods of reposition and (or) fixation of bone fragments (fragments) of bone fragments, the proposed solution does not use mechanical methods of matching, fixation and compression, but a magnetic field of a permanent strong magnet.

The choice of this alloy is due to the fact that the strength of such permanent magnets significantly exceeds ferrite analogues and is about 2 times stronger than the magnetoplast. This type of magnet is able to maintain weight 40-50 times more than its own. The constancy of the neodymium magnet allows it to maintain its properties for a long time (a decrease in the induction force of about 2% over 5 years). Magnets from this alloy are not affected by other materials with weaker field parameters. Table 1 shows the parameters of the selected type of magnets.

In addition to the claimed technical result, local exposure to a magnetic field reduces pain sensitivity, causes vasodilation, lowers blood viscosity, reduces blood clots in blood vessels, improves microcirculation, which leads to increased oxygenation of tissues. In addition, the magnetic field has a local anti-inflammatory effect. Under the influence of magnetic fields, tissue regeneration processes are accelerated.

The invention is illustrated in FIG. 1, which shows the traditional method of intermaxillary fixation, FIG. 2, which shows A - a neodymium magnet in the form of a countersink ring, B - a screw for the lower jaw, C - a view of the magnet on the screw, Fig. 3, which shows the installation locations of the neodymium magnet screws and the direction of the force lines of the rapprochement of the clamps under the influence of a magnetic field, FIG. 4, which shows a method for introducing intraosseous retainers with neodymium magnets to immobilize fragments of a toothless jaw. In FIG. 5 shows the localization of neodymium magnets for fixing fragments of the nasal bones.

An EXAMPLE OF USING THE METHOD OF MAGNETIC FIXATION OF BONE FRAGMENTS WHEN EXECUTING INTERMANDULAR IMMOBILIZATION OF JAW FRAGMENTS (FRAGMENTS).

With the standard technique of intermaxillary fixation, intraosseous self-tapping screws are screwed into the interroot spaces of the upper and lower jaw. At the last stage, the bite is fixed using rubber rings or steel ligatures, which catch on the head of the screws (Fig. 1).

Using the methods of magnetic reposition and immobilization that we proposed for a similar purpose, we used ordinary screws for osteosynthesis of the jaws, under the cap of which neodymium magnets in the form of a ring with a countersink were installed (Fig. 2).

Installing screws with neodyne magnets in typical places allows you to achieve sufficient traction and reliably fix jaw fragments and the patient’s bite (Fig. 3). In FIG. Figure 4 demonstrates the placement of screws with magnetic caps when fixing fragments of a toothless lower jaw in patients with fractures while preserving the height of the bite by introducing fixatives into the crests of the alveolar part and alveolar process of the upper and lower jaws.

This method of magnetic reposition and immobilization can be used in many other modifications and in the treatment of fractures of other skeleton bones.

In FIG. 5, a second variant of the method is illustrated, which can be illustrated by the example of insertion of neodymium magnets into the nasal passages during a fracture of the nasal bones and retraction of fragments in the region of the ramp inside. In this case, a neodymium magnet is inserted into the nasal passage, and a similar magnet or bandage with ferrite liquid or magnetophores is applied on top or in a plaster cast.

The use of this method allows you to save nasal breathing through the nostril from the side of fixation of fragments (unlike traditional gauze turunda), additional care for the dressing is not required. Removing the fixative structure is painless, as it does not adhere to the mucosa (unlike traditional gauze turunda).

Claims (2)

1. The method of magnetic reposition and immobilization of bone fragments of the facial part of the skull, characterized in that for fixation in the bone fragments, fixators containing neodymium magnets with magnetic energy from 302 to 422 kJ / m ³ are installed, then the fragments are manually repositioned. 2. The method according to p. 1, characterized in that the screws used are screws, screws, spokes, rods.

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