KR200380002Y1 - Device for injecting bone cement into bone - Google Patents

Abstract

The present invention relates to a bone cement injection device that can inject the bone cement into the pedicle screw nail fixed to the pedicle with low bone density to strengthen the pedicle screw area more securely.

The bone cement injection device of the present invention for realizing this is provided with a pedicle screw fastening member for fixing to a pedicle screw at one end of the elongated cylindrical body while a syringe for fastening the outlet of the syringe at the other end thereof. The cannula is provided with a handle formed with a fastening member, the invention is made to include an impact consisting of a handle is attached to one end of the cylindrical pressure rod longer than the cannula body is inserted into the cannula body.

Description

Device for injecting bone cement into bone

The present invention relates to a bone cement injection device capable of injecting bone cement into the pedicle with low bone density to enhance the strength of the pedicle. More specifically, by injecting bone cement into the pedicle screw fixed to the spine for spinal fusion. The present invention relates to a bone cement injection device that can firmly fix a pedicle screw by strengthening the strength around the pedicle screw.

In general, a patient with a damaged part of the spine that is difficult to stand upright has to perform an operation for attaching a prosthesis for assisting a damaged spinal part, and the support for the spine used is a damaged spine as shown in FIG. It is inserted into the upper and lower sides of the pedicle screw nail (20) that serves as a fixed stand and connected through each pedicle screw nail (20) consists of a rod (30) serving as a support.

However, patients with osteoporosis are more likely to break bones even with a weak external shock due to a decrease in collagen and calcium, which make up the bones. Therefore, when the pedicle screw nail 20 is mounted on the patients with osteoporosis, bone cement is injected into the pedicle 10 so as to firmly support the pedicle screw 20 so as to reinforce the strength of the pedicle 10. do.

Bone cement is a substance that is made to be as close as possible to the properties of bone and is intended to increase bone strength by penetrating into the bone tissue and filling the gap therebetween. It is usually injected into the bone using a syringe.

However, when the bone cement is first injected and then the pedicle screw 20 is treated, the strength of the pedicle 10 is increased, so that it is difficult to install the pedicle screw 20, and the pedicle screw 20 is In case of mounting, it is difficult to inject bone cement around the pedicle screw nail 20.

Thus, as shown in FIG. 2, a pedicle screw of a structure capable of injecting bone cement through the pedicle screw nail 20 has been developed.

That is, as shown in FIG. 2 of the accompanying drawings, the pedicle screw nail 20 is formed on the screw rod 11 is fixed to the pedicle 10, the upper portion of the screw rod 11 and the U-shaped groove and It consists of a head portion 13 having a screw portion 12, a fastening portion 14 coupled to the screw portion 12 to fix the rod 30, in particular an empty space ( The space of the area indicated by the dotted line) is formed so that the opening 15 is formed toward the head 13 so that bone cement can be injected into the screw rod 11 from the outside, and the spine at the side of the screw rod 11. An injection hole 16 penetrating the space portion is formed to allow the bone cement to be injected into the mirror 10.

Conventionally, when injecting bone cement into the opening 15 of the pedicle screw nail 20, a syringe is usually used. In the case of using a high viscosity bone cement because the inner diameter of the syringe needle is small, the syringe is used. It is difficult to eject high viscosity bone cement through the needle, which makes injection difficult. Thus, when the syringe is injected using a relatively low viscosity bone cement is used a lot.

However, low viscosity bone cements have relatively good fluidity and can be injected relatively easily into the bone at the desired location through the needle, but can flow from the injected location to the surroundings. The bone cement is injected into the site is a lot of holes formed by osteoporosis, so when the bone cement leaked into the nerve hole of the spine may cause nerve palsy, when entering the blood flow to the lungs or heart may cause embolism Problems arise.

The present invention was conceived in view of the above circumstances, injecting the bone cement into the cannula and fastening it to the pedicle screw, and then pushing the bone cement in the cannula into the pedicle screw with the pressure rod of the long axis. An object of the present invention is to provide a bone cement injector that allows the cement to be injected more easily in the vicinity of the pedicle screw.

The bone cement injection device of the present invention for realizing this is provided with a pedicle screw fastening member for fixing to a pedicle screw at one end of the elongated cylindrical body while a syringe for fastening the outlet of the syringe at the other end thereof. The cannula is provided with a handle formed with a fastening member, and the impact is formed by attaching a handle to one end of the cylindrical pressure rod longer than the cannula body while being inserted into the cannula body.

In the above, the interior of the cannula handle is formed with a space is characterized in that in communication with the cannula body.

In the above, the pressure rod that is connected to the handle of the impact is characterized in that the stopper is installed to limit the length of the advancement of the pressure rod inserted into the cannula body.

In the above, the cylindrical body of the cannula and the pressure rod of the impact is characterized in that formed of a stainless material harmless to the human body.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3a shows a perspective view of the cannula according to the present invention.

The cannula 40 includes an elongated cylindrical body 41 and a pedicle screw fastening member 42 for fixing one end portion thereof to the pedicle screw, and a syringe fastening member for fastening the outlet of the syringe for injecting bone cement. 43 is formed of a handle (44).

Cannula body 41 is formed of a stainless material harmless to the human body. The pedicle screw nail fastening member 42 formed on one side end portion is a bolt of a size that can be fastened to a female screw formed on the pedicle screw nail and is fixedly attached to an outer circumferential surface of the cannula body 41, and one side end portion of the cannula body 41 is fixed. The tip is fixed in a position that can be slightly fitted into the opening 15 of the pedicle screw nail 20.

Cannula handle 44 is coupled to the position opposite to the pedicle screw fastening member 42 in the cannula body 41, the tip of the syringe when injecting bone cement into the cannula body 41 using a syringe Syringe fastening member 43 for fastening is formed. In this embodiment, since the female screw portion for coupling the syringe needle to the syringe is formed at the outlet thereof, the male screw portion that can be fastened corresponding to the female screw portion of the syringe outlet is formed of the syringe fastening member 43.

On the other hand, the inner side of the cannula handle 44 and the syringe fastening member 43 is formed with a cylindrical groove communicating in parallel with the hollow of the cannula body (41). In addition, the interior of the cannula handle 44, as shown in FIG. 4, a space portion 45 is formed and a groove 46 communicating with the inner cylindrical groove of the cannula body 41 is formed. The groove 46 is intended to be accommodated in the space 45 without leaking to the outside when a part flows back in the process of injecting bone cement in the cannula body 41 into the pedicle screw.

Figure 3b shows a perspective view of the impact according to the present invention.

The impact 50 is for injecting the bone cement contained in the cannula 40 into the pedicle screw, and is inserted into the cannula body 41 to push the bone cement in the cannula body 41 and the pressure bar 51. It consists of a handle 52 for pushing the rod 51 into the cannula body 41. The pressure bar 51 is formed of a stainless material harmless to the human body, like the cannula body 41, the outer diameter is smoothly moved in the cannula body 41 while at the same time pushing the bone cement in the cannula body 41 The inner diameter of the cannula body 41 is formed to be approximately the same as the inner diameter of the cannula body 41 so that the air in the bone that repels the force to be pushed to the 51 can be naturally discharged to the outside, and the length of the cannula body 41 is Even when fully inserted into the body, it is formed to have a length enough to be left behind to provide sufficient pressure when pushing the bone cement.

In addition, a tubular stopper 53 of a length slightly longer than the finger thickness is attached to the rear end of the pressure bar 51 in a state of being connected to the pressure bar 51. This prevents fingers from being caught between the handle 44 and the handle 52 when the pressure rod 51 is inserted into the cannula body 41 without injecting bone cement or the handle 52 of the impact 50. ) Is to prevent contact with the syringe fastening member 43 of the cannula 40.

Figure 4 shows a cross-sectional view of the bone cement injection device is inserted into the impact cannula according to the present invention.

As shown, the pressure rod 51 has a length that can be fully inserted into the cannula body 41, while the play formed between the outer peripheral surface of the pressure rod 51 and the inner peripheral surface of the cannula body 41 is extremely small. Therefore, when the bone cement in the cannula body 41 is injected into the pedicle screw through the pressure rod 51, almost all the bone cement can be injected into the pedicle through the pedicle screw, and the pressure in the pedicle is increased. When the bone cement injected into the pedicle is pushed out partly, the space 45 is not pushed out of the syringe coupling member 43 at the rear of the cannula 40 through the groove 46 inside the handle 44. Will flow into.

Figure 5 shows a perspective view of a state in which the syringe is fastened to fill the bone cement in the cannula according to the present invention.

In order to inject the bone cement into the pedicle through the pedicle screw according to the present invention, the bone cement is first sucked into the syringe 60 and then injected into the cannula 40. To this end, the outlet of the syringe 60 in a state in which bone cement is sucked is coupled to the syringe fastening member 43 formed behind the handle 44 of the cannula 40 and the plunger 61 is pushed to the barrel 62. Inject bone cement into the cannula 40.

At this time, since the bone cement used is relatively high viscosity, even when the cannula 40 is laid horizontally in the state of removing the syringe, the bone cement housed inside is not easily flowed to the outside.

Figure 6 shows the state of use of bone cement injection apparatus according to the present invention.

As described with reference to FIG. 5, the cannula 40 in which the bone cement is injected is fastened to the pedicle screw 20 fixed to the pedicle using the syringe 60. At this time, the inlet tip of the cannula 40 fastens the pedicle screw fastening member 42 to the U-shaped groove and the threaded portion 12 of the pedicle screw 20 in a state of being introduced into the opening in the pedicle screw 20.

Subsequently, when the pressure rod 51 of the impact 50 is inserted into the body 41 of the cannula 40 while applying a force to the impact handle 52 in the longitudinal direction, the bone cement in the cannula body 41 is pedicle. It is injected into the bone through the screw (20).

On the other hand, the present invention can be applied to a variety of applications, for example, in the use of the present invention, as shown in Figure 7, the power source 72 in a state in which the pressing rod 51 is fixed with a 'c' shaped fixing means 71 Pressurizing means 73 received power from the force can be injected to the bone cement automatically while pushing and pushing the end of the pressure rod 51, where the driving of the power source 72 is the operator simply pedal (74) Step by step) can be configured to stably inject bone cement while checking with a pressure gauge (75), such that the appropriate amount (about 0.1 cc) is used step by step.

As described above, the present invention can effectively intensify the strength around the pedicle screw by injecting the bone cement through the pedicle screw fixed to the pedicle, and apply sufficient pressure to the bone cement contained in the cannula as an impact. As it becomes possible, there is an advantage of using bone cement of high viscosity. In addition, the backflow bone cement is introduced into the space portion of the handle attached to the cannula so that it does not leak to the outside, thereby preventing side effects due to the leaking bone cement during the injection process.

1 is a general state of the pedicle screw nail to be injected bone cement,

Figure 2 is an exploded perspective view of the pedicle screw of Figure 1,

3a is a perspective view of a cannula according to the present invention,

3b is a perspective view of an impact according to the present invention,

Figure 4 is a cross-sectional view of the bone cement injection device, the impact is inserted into the cannula according to the present invention,

5 is a perspective view of a state in which the syringe is fastened to fill the bone cement in the cannula according to the present invention,

6 is a state of use of the bone cement injection device according to the present invention,

7 is a view showing an application example of the present invention.

<Description of the symbols for the main parts of the drawings>

10-pedicle, 12-U-grooves and threads,

13-head, 15-opening,

20-pedicle screw, 30-rod,

40-cannula, 42-pedicle screw fastening member,

43-syringe fasteners, 50-impact,

51-pressurized rod, 53-stopper,

60-syringe.

Claims (4)

The cannula is provided with a pedicle screw fastening member for fixing to the pedicle screw at one end of the elongated cylindrical body, and a handle having a syringe fastening member for fastening the outlet of the syringe at the other end thereof. Bone cement injection device comprising an impact that is inserted into the body and the handle is attached to one end of the cylindrical pressure rod longer than the cannula body. The bone cement injector of claim 1, wherein a space is formed in the cannula handle to communicate with the cannula body. 2. The bone cement injector of claim 1, wherein the pressure rod that connects to the handle of the impact is provided with a stopper for limiting the length of advancement of the pressure rod inserted into the cannula body. The device of claim 1, wherein the cylindrical body of the cannula and the pressure rod of the impact are formed of a stainless material that is harmless to the human body.