RU100717U1 - ROD FOR FIXING THE POSITION AND FORM OF TUBULAR BONES - Google Patents

Abstract

 1. A rod for fixing the position and shape of the tubular bones, containing an expansion element located along the longitudinal axis of the rod and made in the form of a hollow tube with ribs located along the longitudinal axis, and with the possibility of filling the inner cavity of the expansion element and increasing its cross section in the radial direction and also a head and an end nozzle located respectively at the proximal and distal ends of the rod, characterized in that in the initial state the expansion element has a transverse cross ix, approximate to a triangular profile. ! 2. The rod according to claim 1, characterized in that the outer surfaces of the ribs are rounded. ! 3. The rod according to claim 1, characterized in that the ribs are located inside the expansion element in the corners of the polygon. ! 4. The rod according to claim 1, characterized in that the ribs are made radially protruding outward for the expansion element. ! 5. The rod according to claim 1, characterized in that the ribs have a variable thickness. ! 6. The rod according to claim 1, characterized in that the expansion element and stiffeners are made of various biocompatible materials. ! 7. The rod according to claim 1, characterized in that the head contains a nipple (one or two-way valve). ! 8. The rod according to claim 1, characterized in that the interface between the end nozzle and the head with the expansion element has a shape close to a triangular profile.

Description

This useful model relates to medicine, namely to traumatology, to devices for stimulating osteosynthesis of bone fractures, in particular for the surgical treatment of fractures of tubular bones with an intramedullary canal.

Tubular bone fractures are usually treated using intramedullary pins, which contain a tubular element longitudinally inserted into the bone marrow, a joint head screw that is inserted into the corresponding saddle, formed in a large trochanter for guiding osteosynthesis in accordance with the fracture, and stabilizing screws located in the distal part of the pin, that is, in that part, which when using the device is located closer to the knee, which allows you to lock the pin on the femur.

This type of intramedullary pin for the treatment of trochanteric fractures has some drawbacks. In practice, it was determined that when using devices of this type, the risk of infection increases due to additional incisions required to install stabilizing screws in the distal part of the pin.

In addition, the installation of such screws, due to the difficulty of alignment and alignment with special sockets formed on the pin, is very difficult and requires a relatively long operation time, and is also associated with repeated exposure of the patient and surgeon to x-rays, which is required to ensure the correct course operations.

In addition, the use of such devices requires a relatively long time to recover the patient. In fact, in the first postoperative period, the stabilizing screws are fixed stably, without any gap, in special sockets formed on the pin, as a result of which during this first stage of recovery it is impossible to load the leg to stimulate a fracture fracture. Only during the second period, the type of connection of the stabilizing screws with the intramedullary pin changes and after an additional operation passes from stable distal blocking to dynamic distal blocking, and as a result, stimulation of a bone fracture becomes possible.

Known intramedullary pin for the surgical treatment of trochanteric fractures of the femur, containing a tubular element in which a screw is attached to the joint head, and a stabilizing element that contains a pair of wire rods, bent at an angle at one end and installed longitudinally with respect to the tubular element inside it, which exit through two holes formed in the distal part of the specified tubular element (see RF patent No. 2289351, IPC АВВ 17/72 (2006.01), 2005).

The disadvantage of this device is the difficulty of installing such a pin, which requires the drilling of a sufficiently large hole in the bone, which leads to trauma to the bone material, as well as the possibility of infection in the bone canal.

Also, for the internal stabilization of broken long bones, relatively large steel nails are used having a predetermined U-shaped or V-shaped cross section. Nails stabilize bones in accordance with the principle of providing support at three points, namely at the beginning, at the end and in the middle section of the nail. In order to position such nails, large openings must be made across the surface of the bone, and then through the medullary cavity of the bone, matching the diameter of the implanted nail (see AS USSR No. 1757653, IPC 5 A61B 17/58, 1992 , A.S. USSR 1659034, IPC 5 А61В 17/58, 1991).

The use of such a device has the following drawback: almost all medullary cavities must be drilled in order to make such an opening, and as a result, in particular, blood supply to the bone is impaired. In addition, due to support at three points, the force is transmitted through a relatively small area, and additional mechanisms, such as fastening screws, etc., must be used to ensure rotational stability.

Removing the intramedullary nail after the bone has grown together is also a procedure requiring a relatively high degree of effort. The nail is stuck in the medullary cavity and must be knocked out of the cavity using special tools and with the application of relatively large forces. In this process, the medullary cavity may experience significant damage.

An intramedullary nail is known in which the shaft consists of a hollow body made of an alloy with shape memory, which can take two possible forms depending on temperature. Then, when it is already installed, the intramedullary nail can be transformed from having a small cross section to having a large cross section, and vice versa due to the temperature effect (see Germany patent No. 3201056, IPC 7 A61B 17/58, 1983).

The disadvantage of this intramedullary nail is that the use of the heat required to expand the diameter of the nail shaft also causes thermal stress in the bone and bone marrow.

A nail is known in which a single expanding chamber surrounds the main body of the nail completely (see US Patent No. 5102413, IPC 7 A61B 17/68, 1992).

The disadvantage of this solution is ...

A nail is known for fixing the position and shape of broken long bones, having a rod with a central main section and several chamber-like expansion elements installed around the main section and elongated along the length of the rod, and internal pressure can be created in the said expansion elements by means of liquid or gas when they are located in the bone, which causes them to expand in the radial direction. The nail may contain one expansion element, in which there are ribs located along the longitudinal axis and radially protruding outward from the specified expansion element (see RF patent No. 2180813, IPC 7 AB 17/72, 2002). This decision was made as a prototype.

The disadvantage of this solution is the design complexity. In addition, in the case where several expansion elements are installed around the main section, the mounting of the expanding elements is difficult and unreliable. As shown by the practice of using the prototype, its disadvantage is unreasonably excessive injuries of the bone marrow when the extension element of the rod goes into the expanded state (when the rod is made with one extension element). This is due to the kinematics (movement) of the ribs during the transition of the expansion element from the unexpanded state to the expanded one: the ribs perform a rotational-translational movement, spinning in a spiral in the direction of the bone walls, as a result of which bone marrow destruction is observed.

In addition, there is an increased likelihood of formation of bone pressure sores due to the high pressure on the surface of the medullary canal of the eight pointed edges of the bar ribs.

According to medical practice with the use of such rods, one of the significant drawbacks is the insufficient strength of the rod tip, which in some cases leads to its crushing during insertion into the medullary canal.

The objective of this utility model is to eliminate these drawbacks, simplify the design of the rod to fix the position and shape of broken tubular bones, which allows for good stabilization, can be implanted without significant damage to the medullary cavity and which also does not create any thermal stress in the bone and bone marrow and thus reduces the risk of infection. In addition, the task is to minimize damage to the bone marrow during the transition of the rod to the expanded state and with reverse narrowing, as well as the possibility of reducing damage to the bone marrow canal by reducing the maximum pressure on its surface.

The problem is solved due to the fact that in the known rod for fixing the position and shape of the tubular bones, containing an expansion element located along the longitudinal axis of the rod and made in the form of a hollow tube with ribs located along the longitudinal axis, and with the possibility of filling the inner cavity of the expansion element and increasing its cross section in the radial direction, as well as the head and end nozzle located respectively at the proximal and distal ends of the rod, in accordance with the useful model, in the initial state, the expansion element has a cross section close to a triangular profile.

The outer surfaces of the ribs are rounded.

The edges are located inside the expansion element at the corners of the polygon.

The ribs are made radially protruding outward for the expansion element.

The ribs have a variable thickness.

The expansion element and stiffeners are made of biocompatible materials.

The head contains a nipple (single or double-sided valve).

The interface between the end nozzle and the head with the expansion element has a shape close to a triangular profile.

The technical result from the use of the totality of features of a utility model is to simplify the design while increasing the stiffness in the initial state, ensuring good stabilization and fixing the position and shape of the broken tubular bones. Also, the technical result consists in the possibility of implantation of the rod without significant damage in the medullary cavity, while its fixation is provided without thermal stress in the bone and bone marrow and, thus, the risk of infection is reduced.

The technical result also consists in minimizing damage to the bone marrow during the transition of the rod to the expanded state and with reverse narrowing, as well as the possibility of reducing damage to the bone marrow canal by reducing the maximum pressure on its surface, which is due to the execution of the cross section of the expansion element close to the triangular profile.

Figure 1 - General view of the rod

Figure 2 is a longitudinal section of a rod

Figure 3 - section aa of figure 2 in the initial and expanded position.

The rod for fixing the position and shape of the tubular bones, contains an expansion element 1 located along the longitudinal axis of the rod. The expansion element 1 is made in the form of a hollow tube with ribs 2 located along the longitudinal axis. The expansion element 1 and the stiffeners 2 are made of various biocompatible materials. The expansion element 1 is configured to fill its inner cavity and increase its cross section in the radial direction. In the initial state, the expansion element 1 has a cross section close to a triangular profile.

The ribs 2 can be formed together with the expansion element 1 or rigidly connected to it. The outer surfaces of the ribs 2 are rounded (see figure 2), which reduces injury to the bone marrow and bone material. The ribs 2 can be located inside the expansion element 1 at the corners of the triangle, while the corners 3 are rounded to reduce the maximum pressure on the surface of the medullary canal. The ribs 2 may have a variable thickness along the surface of the expansion element.

The ribs can be made radially protruding outward for the expansion element.

The rod also contains a head 4 and an end nozzle 5 located respectively at the proximal and distal ends of the rod. The interface between the end nozzle 5 and the head 4 with the expansion element 1 has a shape close to triangular, the same as the expansion element 1 in the initial state.

The head 3 is intended for installation in it of a nipple (one- or two-way valve), which ensures the flow into the expansion element 1 of the liquid (preferably physiological saline).

The use of the rod is as follows.

Previously, the rod is in a compressed state, so that when it is inserted into the medullary canal, the bone tissues are practically not damaged. Next, the rod is passed through the medullary canal of the proximal or distal fragments and set it in the destroyed part of the bone. Under the control of the tube, the liquid (physiological solution) is supplied to the expansion element 1 of the rod, controlling the pressure - 30-70 atmospheres, but not more than 70 atmospheres. This procedure is absolutely safe. Since the fluid is an incompressible medium, any leakage leads to a release of pressure without risk to the patient. As a result, the cross section of the expansion element increases in the radial direction. The maximum outer cross-sectional dimension of the extension element may be somewhat larger than the corresponding circumference described around the vertices of the ribs 2.

When fluid is supplied to the rod, uniform pressure is exerted through the outer surfaces of the ribs 2 of the expansion element 1 to the mating contact surfaces of the bone due to the uniform and gradual increase in the transverse size of the expansion element. In this case, the rod takes shape in accordance with the inner diameter of the intramedullary canal. The fastening of the rod inside the bone is carried out by increasing the transverse size of the extension element 1 of the rod in accordance with the inner diameter of the intramedullary channel and tight contact of the outer surface of the ribs of the rod with the mating contact surface of the bone.

Thus, a strong fixation of the main bone fragments is achieved. The rod can be used in traumatology, surgery and for other medical purposes (for example, to strengthen the bone in osteoporosis).

All elements of the rod can be manufactured using modern equipment.

Claims (8)

1. A rod for fixing the position and shape of the tubular bones, containing an expansion element located along the longitudinal axis of the rod and made in the form of a hollow tube with ribs located along the longitudinal axis, and with the possibility of filling the inner cavity of the expansion element and increasing its cross section in the radial direction and also a head and an end nozzle located respectively at the proximal and distal ends of the rod, characterized in that in the initial state the expansion element has a transverse cross ix, approximate to a triangular profile. 2. The rod according to claim 1, characterized in that the outer surfaces of the ribs are rounded. 3. The rod according to claim 1, characterized in that the ribs are located inside the expansion element in the corners of the polygon. 4. The rod according to claim 1, characterized in that the ribs are made radially protruding outward for the expansion element. 5. The rod according to claim 1, characterized in that the ribs have a variable thickness. 6. The rod according to claim 1, characterized in that the expansion element and stiffeners are made of various biocompatible materials. 7. The rod according to claim 1, characterized in that the head contains a nipple (one or two-way valve). 8. The rod according to claim 1, characterized in that the interface between the end nozzle and the head with the expansion element has a shape close to a triangular profile.