RU2454963C1 - Apparatus for treating injuries and diseases of long tubular bones in children - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to traumatology-orthopedics, and is intended for treatment of fractures of long tubular bones. Apparatus contains supports in form of arc-shaped plates, curved on radius in their own plane, and bent in said plane in form of projections from end parts of plate towards its convexity. Projections and end parts of plate are provided with holes with bilateral countersunk. Along plate made are holes located on radius, threaded rods, connecting said supports, intraosseous rods, rod-fixers, and remote rod-fixer in form of bar. Holes, located along plate, are made square. Base of remote rod-fixer is provided with square boss, located along axis, which has threaded axial hole for screw. On wide sides of bar made are transversal teeth, along axis of these sides made is through slot, whose width corresponds to diameter of used intraosseous threaded rods, whose fixation in bar is realised with nuts and washers of square shape, which have on one of working surfaces teeth corresponding in shape to teeth on bar sides.

EFFECT: invention makes it possible to reduce operation trauma, improve treatment outcome, create relative conveniences for patients.

4 dwg

Description

The invention relates to medicine, namely to traumatology, orthopedics, and is intended for the treatment of fractures of long tubular bones.

Currently, for the treatment of fractures of long tubular bones, rod compression-distraction apparatuses of external fixation are most widely used [1]. The number of intraosseous rods used in adults varies from 6 to 8. The use of a four-section external fixation apparatus was first proposed by G.A. Ilizarov is the “classic” version of the arrangement of the external fixation apparatus, be it G.A. Ilizarova, or his spoke analogs, or one-sided rod fixation devices. The 4-support arrangement of the apparatus involves the use of two supports - the distal and proximal - as the “base” supports, they are distracted and eliminated by the displacement of bone fragments along the length and along the axis (rotational), and two reponing ones - they are removed by removing the displacement of the fragments along width.

The fundamental difference between external fixation devices when used in children is both to reduce the number of fixation elements used (in our case, intraosseous rods) and the number of supports used. Instead of reponing supports G.A. The Ilizarovs were invited to use remote brackets, which halved the weight of the device.

Thus, the closest, in its technical solution, to the invention is a two-section apparatus G.A. Ilizarova, where instead of reponing supports, external brackets are used [2]. However, along with the advantages of the design used, its disadvantages are the bulkiness and excessive weight of the apparatus.

The essence of the invention lies in the combination of distinctive features sufficient to achieve the desired technical result, which consists in reducing the invasiveness of the operation, creating convenience for the patient while improving treatment outcomes.

This result is achieved by the fact that the apparatus for treating injuries and diseases of long tubular bones in children contains supports in the form of arched plates curved along the radius in its own plane and bent in this plane in the form of protrusions from the end sections of the plate towards its convexity. The protrusions and end sections of the plate are equipped with holes with a double-sided countersink, and along each plate there are holes arranged along the radius. The apparatus contains threaded rods connecting these supports, intraosseous rods, rod fixators, and an external rod fixator in the form of a bar. The holes along the plate are square. The base of the beam is equipped with a square boss, located along the axis, and has an axial threaded hole for the screw. On the wide sides of the beam transverse teeth are made. A through groove is made along the axis of these sides of the timber. The width of the said groove corresponds to the diameter of the intraosseous threaded rods used, which are fixed in the beam with nuts, with square washers having teeth on one of the working surfaces. In shape, the teeth on the surface of the washers correspond to the teeth on the surface of the timber.

A longitudinal through groove located along the axis of the beam is designed to fix the rod at the required bone level.

A square boss on the base of the beam, with an axial threaded hole for the screw, for fixing the remote rod clamp on the support of the device is necessary to exclude the possibility of rotation of the beam, with the threaded rod installed, in the supports.

The teeth made across the wide sides of the beam provide a stable, reliable fixation of the rods at the required level in the rod retainer by preventing longitudinal sliding of the rod when fixing it with nuts and square washers having teeth on the working surfaces corresponding to the teeth on the sides of the beam.

The illustrations show: in Fig. 1 is a general view of the apparatus, in Fig. 2 is an assembled remote arm, in Fig. 3 is a radiograph of a patient's limb upon admission, and in Fig. 4 is a radiograph of a patient's limb after an operation.

The apparatus for reposition and fixation of fractures of long tubular bones contains supports 1 in the form of plates bent radially in their own plane and bent in this plane in the form of protrusions 2 from the end sections of the plate towards its convexity. In this case, the end sections of the plates 1 are equipped with holes 3, and the protrusions 2 have holes 4 with a two-sided countersink so that the holes 4 in the protrusions 2 are located to the periphery from the holes 3 in the end sections of the plates 1. Along the plate 1 there are square radiused holes 5. The supports of the apparatus 1 are interconnected by means of threaded rods 6 installed in the holes 3 of the end sections 2 of the plates 1, and fixed in them by means of spherical nuts 7. The remote rod 8 is made in the form of a beam and has a base and a longitudinally placed square boss 9 for installation in the holes 5 of the support 1, with a threaded hole 10 along the axis of the rod clamp 8 for fastening with a screw 11. Transverse teeth 12 are made on the wide sides of the bar of the rod clamp 8. A through groove 13 is made along the axis of these sides of the bar, the width of which corresponds to the diameter of the intraosseous threaded rods used 14. The rods 14 are fixed in the external stem-clamp 8 with nuts 15 with square washers 16 having teeth 17 on one of the working surfaces in shape corresponding to the teeth 12 on the surfaces of the extension bracket 8. If necessary, the movement along the bone and fixation of the intraosseous rods 14 installed in the rod retainer 8 is made with spherical nuts 7. The holes 4 in the protrusions 2 are designed to install additional threaded rods 18.

The apparatus is used as follows.

Before the operation, in order to clarify the position of the fragments, an X-ray of the damaged limb is made in direct and lateral projection. On the skin, projection, mark the position of these fragments. Two intraosseous rods are introduced into the proximal fragment from the lateral side, each at an angle of 90 ° to the bone fragment so that the upper intraosseous rod is located below the growth zone of the greater trochanter, and the lower one is above the line of bone fracture. Accordingly, on the distal fragment, the intraosseous rods are positioned as follows: the upper one is below the fracture line, the lower one is above the growth zone of the femoral condyles. After distal and proximal pairs of intraosseous rods 14 are drawn, proximal and distal supports 1 are mounted on them, respectively, in the form of curved plates so that the threaded rods 6 connecting them are parallel to the direction of the bone fragments defined on the radiograph made in lateral projection. Intraosseous rods 14 are installed in the longitudinal grooves 13 of the external rod clamps 8, fixed with nuts 15 using square washers 16, placing the toothed surfaces of the washers 16 and rod clamps 8 towards and parallel to each other. The rod clamps 8 are fixed on the plates 1 with a screw 11. After installation, the distal and proximal supports 1 are connected to each other using threaded rods 6 and spherical nuts 7, using the holes 3 in the plates 1.

The removal of fragments along the length is carried out by moving the spherical nuts 7 along the threaded rods 6 connecting the distal and proximal supports 1. The fragments are repositioned in the lateral projection by pre-setting the distal and proximal supports on the rods, strictly 90 degrees to the axis of each bone fragment . When the parallelism of the arrangement of the threaded rods 6 connecting the distal and proximal supports 1 is achieved, the fragments are repositioned in the sagittal plane. The displacement of fragments in the anteroposterior projection is eliminated by moving (pulling or pulling) the intraosseous rods 14 by working with the nuts 8. After the reposition is completed and correction is achieved, for the period of stabilization, to prevent varus deformation of the apparatus, additional threaded rods 18 are installed in the holes 4 of the protrusions of 2 plates 1. The compression created on the threaded rods 18 located lateral to the threaded rods 6, mounted in the holes 3 of the plates 1, stop the forces aimed at the formation of the varus deformity and apparatus.

Clinical example

Patient G., born in 1998, East. bol. No. 4378, was admitted to the Department of Pediatric Traumatology of the Republic of Kazakhstan Clinical Hospital on January 21, 2010 with a diagnosis of Closed fracture of the middle third of the left femur with displacement. After preoperative preparation and production of general anesthesia, the patient was laid on an orthopedic table on which the primary reposition of the fragments was performed (usually only the displacement along the length of the fragments is eliminated). Radiography of a limb segment was performed in two projections with “marks” to clarify the location of the fracture line and determine the displacement of the fragments (Fig. 3). Distal and proximal base rods were drawn into the distal and proximal bone fragments. At a distance of 1.5 - 2 cm from the fracture line, repairing intraosseous rods were made depending on the fracture line and the nature of the displacement of the fragments. The reposition was carried out by repairing intraosseous rods according to the above method. Two intraosseous rods are introduced into the proximal fragment from the lateral side, each at an angle of 90 ° to the bone fragment so that the upper intraosseous rod is located below the growth zone of the greater trochanter, and the lower one is above the line of bone fracture. Accordingly, on the distal fragment, the intraosseous rods are positioned as follows: the upper one is below the fracture line, the lower one is above the growth zone of the femoral condyles. After distal and proximal pairs of intraosseous rods are drawn, proximal and distal supports in the form of curved plates are mounted on them, respectively, so that the threaded rods connecting them are parallel to the direction of the bone fragments defined on the radiograph made in lateral projection. Intraosseous rods are installed in the longitudinal grooves of the external stem fixators, fix them with nuts, using square washers, placing the toothed surfaces of the washers and rod fixators towards and parallel to each other. The rod fixators are fixed on the plates with a screw. After installation, the distal and proximal supports are interconnected using threaded rods and spherical nuts, using holes in the plates.

Elimination of the displacement of fragments along the length is carried out by moving the spherical nuts along the threaded rods connecting the distal and proximal supports. Reposition of fragments in the lateral projection is done by pre-installing the distal and proximal supports on the rods with respect to the axis of each bone fragment strictly by 90 degrees. When the parallelism of the arrangement of the threaded rods connecting the distal and proximal supports is achieved, the fragments are repositioned in the sagittal plane. The displacement of fragments in the anteroposterior projection is eliminated by moving (pulling or pulling) the intraosseous rods by working with the nuts that fix the rods in the fixation rod. After the reposition is completed and correction is achieved for the stabilization period, for the prevention of varus deformation of the apparatus, additional threaded rods are installed in the holes of the plate protrusions. The compression created on additional threaded rods located lateral to the threaded rods, mounted in the holes of the plates made in the end sections of the plate, stops the forces aimed at the formation of the varus deformation of the apparatus.

The device is stabilized by installing lateral threaded rods on which compression is created. The limb load is allowed for 4 days. Examination of the patient a month after exercise. Determined by the consolidation of the fracture (figure 4). The patient serves himself, moves with reliance on the operated limb, without additional devices. Dismantling the device made 3 months after application. The patient was prescribed physiomechanical procedures ..

Information sources

1. RF patent No. 2201168, А61В 17/66, BIPM, 2003, No. 9.

2. A set of compression-distraction apparatus G.A. Ilizarova for the upper limb, lower leg, thigh. Passport A.101.00.00.00.PS (Operating Instructions and Technical Description), Gudermes, 1991.

Claims (1)

An apparatus for treating injuries and diseases of long tubular bones in children, containing supports in the form of arched plates curved along the radius in its own plane and bent in this plane in the form of protrusions from the end sections of the plate to the side of its convexity, while the protrusions and end sections of the plate are equipped holes with a double-sided countersink, and along the plate there are holes placed along the radius, threaded rods connecting these supports, intraosseous rods, rod fixators, and an external rod fixator in the form of br whisker, characterized in that the holes located along the plate are made square, the base of the remote fixer is equipped with a square boss located along an axis having a threaded axial hole for the screw, transverse teeth are made on the wide sides of the beam, a through groove is made along the axis of these sides, width which corresponds to the diameter of the intraosseous threaded rods used, which are fixed in the beam with nuts with square washers having teeth on one of the working surfaces about the shape corresponding to the teeth on the sides of the timber.

Images