RU2691326C1 - Absorbable intramedullary nail for fixing fractures of long tubular bones - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention refers to medical equipment, namely to intramedullary devices used in traumatology and orthopedics, and is intended for combined osteosynthesis of fractures of long tubular bones. Rod is made in the form of tubular structure including wall and inner cavity. Rod is equipped with fixing elements for rod passing through the wall. Ratio of the wall thickness to the inner cavity diameter makes 1:10–1:5. Intramedullary nail wall includes through holes, the diameter of which makes 0.1–0.3 cm. If the holes diameter is 0.1 cm, their number makes 3–5 with the distance between the holes making at least 0.4 cm, with the hole diameter of 0.2 cm their number is 2–4 with distance between holes of not less than 0.6 cm, with diameter of holes of 0.3 cm their number is 1–2 with distance between holes of not less than 0.7 cm per 1 cmsurface area of the rod.EFFECT: invention provides higher clinical effectiveness in fractures of long tubular bones with complex architectonics.1 cl, 2 dwg

Description

The invention relates to medical equipment, namely to intramedullary devices used in traumatology and orthopedics, and is intended for combined osteosynthesis of fractures of long tubular bones.

According to various authors, the number of fractures of the long tubular bones is up to 50% among all injuries of the limb. The main difficulties in the surgical rehabilitation of patients with similar injuries are associated with the anatomical and functional features of the joints of the upper and lower extremities, as well as the formation of a variety of fragments that limit the capabilities of modern structures to stably fix the fracture.

In modern traumatology, various variants of osteosynthesis are widely used in the treatment of fractures of the long tubular bones - bone, intramedullary, extrafocal.

Of particular relevance is the combined osteosynthesis of long tubular bones, optimally combining both the positive aspects of the bone and intramedullary osteosynthesis.

A large variety of elements for intramedullary osteosynthesis does not exclude the same variety of subsequent problems and postoperative complications.

Thus, the prior art known intramedullary rod for fixing long tubular bones (Krishtal MM and others, Expandable self-locking intramedullary osteosynthesis core, Vector of TSU science, 2016, №1, pp. 17-22), made of biocompatible steel, having a triangular cross section and elements for expanding the inner bore.

The disadvantages of intramedullary osteosynthesis using this type of rod are traumatizing the endosteum, bone marrow and a.nutricia; violation of intraosseous blood flow and the inner growth layer of the bone - the endosteum - decreases the reparative potential of the bone. Fusion is due to the formation of periosteal callus; the need to use expensive special equipment (C-arc X-ray) and instrumentation.

The prior art absorbable intramedullary rod for fixing fractures of long tubular bones (RU 2316282 C1 (MATVEEV AL), 04/26/2006), made in the form of a tubular structure that includes a wall and an internal cavity, provided with fixing elements for holding through the wall of the rod. The resorbable material of the rod allows to reduce the degree of traumatization of the endosteum, but for a long time it prevents angiogenesis and reparative processes in the bone.

Thus, there is a need for an absorbable intramedullary rod, devoid of the above disadvantages.

The technical result of the invention is to increase the effectiveness of treatment of fractures of long tubular bones with complex architectonics (multiple fractures with mixing fragments) in combination with classical methods of fixation (metal and steel stent plates and screws, external fixation devices), anatomical reposition, restoration of intramedullary angiogenesis, which contributes to the consolidation acceleration , reduces the risk of complications (the formation of false joints, shortening of the limb) and, as a result, p Leads to faster functional recovery of the injured limb.

The technical result is achieved due to the fact that in a known absorbable intramedullary rod for fixing fractures of long tubular bones, made in the form of a tubular structure that includes a wall and an internal cavity, provided with fixing elements for conducting through the wall of the rod, the ratio of wall thickness to diameter is proposed internal cavity, comprising 1: 10-1: 5; while the wall of the intramedullary rod includes through holes, whose diameter is from 0.1-0.3 cm, with a hole diameter of 0.1 cm, their number is 3-5 with a distance between the holes of at least 0.4 cm, with a diameter holes 0.2 cm, their number is 2-4 with a distance between the holes of at least 0.6 cm, with a hole diameter of 0.3 cm, their number is 1-2 with a distance between the holes of at least 0.7 cm, 1 cm ² rod surface area.

FIG. 1 shows a schematic depiction of the proposed device.

FIG. 2 shows the location of the holes with their different diameters per 1 cm ² the surface area of the rod.

Absorbable intramedullary rod (Fig. 1) is made in the form of a tubular structure that includes a wall (1) and an internal cavity (2) and is equipped with locking elements (not shown) for passing through the wall (1) of the rod. The ratio of wall thickness (1) to the diameter of the internal cavity (2) is 1: 10-1: 5. The wall (1) of the intramedullary rod includes through holes (3), the diameter of which is 0.1-0.3 cm. With a diameter (Fig. 2) of the holes (3) equal to 0.1 cm, their number is 3- 5 with the distance between the holes (3) not less than 0.4 cm (I), with the diameter of the holes (3) equal to 0.2 cm, their number is 2-4 with the distance between the holes (3) not less than 0.6 cm ( II), if the diameter of the holes (3) is 0.3 cm, their number is 1-2 with the distance between the holes (3) not less than 0.7 cm (III) per 1 cm ^{2 of} the surface area of the rod. In the presence of a combination of holes (3) of different diameters, the distance between the holes (3) should be the necessary minimum specified for the holes of larger diameter.

The wall thickness (1) of the intramedullary rod, and specifically the stated ratio of its thickness to the diameter of the internal cavity (2) -1: 10-1: 5 - is significant, since with a multi-fragment fracture with large fragments with a ratio of 1: 10-1: 7 no the need to use a variety of locking elements, and accordingly, multiple reaming of the rod. At the same time, the strength of the structure does not suffer. If it is necessary to fix combinations of large and small fragments, as well as many small bone fragments and the corresponding number of core drills, the ratio will be more than 1: 7 to 1: 5, since this will allow fixing a larger number of fragments without losing the strength of the rod.

The presence of through holes (3) in the rod due to two significant points. First, the need for prefabricated holes for fixing bone fragments elements. In this case, the finished holes require reaming only in case of fitting to the size of the fixing element. Secondly, these holes are necessary for angiogenesis in the regenerative processes in the bone, without disrupting the intramedullary blood supply and not changing the intramedullary pressure, which will contribute to the normalization of osteogenesis and early consolidation of the fracture. This, in turn, will contribute to more rapid and effective functional recovery and recovery of the patient.

The diameter of the holes (3) and their number on the rod are significant for the following reasons. When the diameter of the holes is less than 0.1 cm, the holes will be thrombated during the operation, therefore, their function of becoming angiogenesis will be impaired. The diameter of the holes greater than 0.3 cm will affect the strength of the structure. It is equally important for the same purpose to arrange the holes in an optimal way: with a hole diameter of 0.1 cm, their number is optimally 3-5 with a distance between the holes of at least 0.4 cm, and with a hole diameter of 0.2 cm, their number is 2-4 with a distance between the holes of not less than 0.6 cm, with a hole diameter of 0.3 cm, their number is 1-2, with the distance between the holes of not less than 0.7 cm - per cm ^{2 of} the surface area of the rod.

The ratio of the wall thickness of the rod to the diameter of the internal cavity, the diameter of the holes and their number in each case depend on the architectonics of the fracture, but, accordingly, the thicker the wall, the greater the number can enter the design of the rod.

A resorbable intramedullary rod may include both openings of the same diameter or different, depending on the need for fixing elements, the size and number of bone fragments. The core can be made individually for each case on a 3D printer.

It is preferable to choose PLGA monomers as the material for the proposed resorbable intramedullary rod. PLGA monomers are lactic and glycolic acids, which are the normal chemical composition of mammalian cells. PLGA copolymers overcome previous problems that were associated with too fast decomposition of PGA materials and the slow process of decomposition of PLLA materials, thereby neutralizing the biodegradable properties of both polymers.

The PLGA material used in the production of biodegradable implants has a long history of safe clinical use and its biocompatibility has been proven in animal tests as well as in clinical trials. The implant breaks up under the influence of hydrolysis, producing acid as an intermediate product, and finally, it is metabolized to carbon dioxide and water and then naturally excreted from the body.

On the second day after implantation, the implant undergoes some changes: its length decreases by 2%, and the thickness increases by 0.5%, thus, an auto-compression effect is manifested and additional rigidity is achieved. If the bone tissue gradually becomes stronger in the process of splicing, then our implants, on the contrary, begin to dissolve, gradually losing their strength after 8 weeks. The resorption process begins after 8 weeks and ends after 2 years. Thus, no re-operation is required to remove the implant.

The use of the device is as follows.

In case of fracture of the long tubular bone, the proposed intramedullary rod is introduced into the bone-marrow channel.

Carry out the fixation of bone fragments on the rod through the holes (3) with the necessary number of attached fixing elements of the appropriate diameter. Use of fasteners made of biodegradable, or ceramic, or metallic materials. Alternatively, for this purpose it is possible to use any screw clamp or pin wider than the hole (3) by 0.1-0.25 mm (for example, Arthrex® BioComposite bioceramic clamp, spongy metal screw, etc.).

Apply any method suitable for a specific situation of bone osteosynthesis (using an Ilizarov apparatus, plates, etc.).

Thus, the use of the proposed resorbable intramedullary rod for fixing fractures of long tubular bones improves the treatment of fractures of long tubular bones with complex architectonics (multiple fractures with mixing fragments) in combination with classical methods of fixation (metal osteosynthesis with plates and screws, external fixation devices), contributes anatomical reposition of fragments and the restoration of intramedullary angiogenesis, which, in turn, allows to achieve speed consolidation, reduces the risk of complications (the formation of false joints, shortening of the limb) and, as a result, leads to more rapid functional restoration of the injured limb.

Claims (1)

Absorbable intramedullary rod for fixing fractures of long tubular bones, made in the form of a tubular structure, which includes a wall and an internal cavity, provided with fixing elements for conducting through the wall of the rod, characterized in that the ratio of wall thickness to the diameter of the internal cavity is 1: 10-1 :five; the wall of the intramedullary rod includes through holes, whose diameter is from 0.1-0.3 cm, with a hole diameter of 0.1 cm, their number is 3-5 with a distance between the holes of at least 0.4 cm, with a hole diameter of 0 , 2 cm, their number is 2-4 with a distance between the holes of at least 0.6 cm, with a hole diameter of 0.3 cm, their number is 1-2 with a distance between the holes of at least 0.7 cm per 1 cm ^{2 of} the surface area of the rod .

Images