KR100465197B1 - Injection method for bone cement of a bone porosity and device thereof - Google Patents

Abstract

The present invention relates to vertebral plastic surgery for injecting reinforcing materials into bone or body tissue.

The present invention constitutes a probe, a primary expansion conduit, a secondary expansion injection conduit, and a material injection conduit for guiding injection of reinforcement material and a puncturing means for inserting a substance into the vertebral body into the injection material, so that when the reinforcement material is injected, Air and other foreign substances present in the injection conduit are discharged into the space between the substance injector and the substance injection conduit to reduce the pain of patients with conventional general anesthesia through partial anesthesia and injection of reinforcement materials without air. Maintaining the density accurately prevents the patient's blood from filling inside the bone, while changing the injector only when the patient's condition requires more injection of the reinforcing material than the volume in the material injection conduit. Osteoporosis to prevent the procedure from interrupting when the usual infusion is exceeded, such as infusion. It provides a reinforcing material in the injection device and the injection method.

Description

Injection method for bone cement of a bone porosity and device

The present invention is a reinforcing material {eg; The present invention relates to a vertebral plastic surgery that enables the injection of bone cement. In particular, the bone cement having optimal viscosity is made in advance so that the reinforcement material such as bone cement is continuously injected into the bone or body tissue. Osteoporotic bone, which fills the injector with a little less than the inlet conduit and injects the reinforcing material, the air present in the inlet conduit and other foreign matter naturally discharges into the space between the injector and the inlet conduit It relates to a reinforcing material injection device and its injection method.

As is well known, wounds in the bone can be caused by osteoporosis, tumors or other pathogenicity, and degenerative osteoporosis is most likely to occur in older people, especially women.

The cause of osteoporosis is at least partly due to genetic effects and lowering circulating estrogen levels.

Although calcium replacement therapy may have some beneficial effects, the need for higher amounts of calcium leads to other less beneficial results, so the prognosis for people with demineralization bones is particularly It was not good.

In the United States, much attention has been paid to the fact that there are about 1.2 million people with bone disease caused by osteoporosis every year, and vertebral compression failure is a major problem for older people due to the long-term nature of the condition. It is an orthopedic concern.

Historically, osteoporosis vertebral compressions have been treated for the first week after onset by resting, getting a vibrating agent and intravenous hydration.

Then, according to the doctor's preference, a prescription was made for soft or hard spine bags.

However, in the above case, the patient was severely uncomfortable and sometimes even more uncomfortable than the pain of the vertebral bodies. The weakening of the cause also led to further osteoporosis.

In addition, there is a problem of the cost of longer hospitalization, and such long periods of inactivity have a negative effect on the patient's normal health.

In addition, traditional surgical techniques employed to alleviate spinal compressions often involve negative surgical procedures, often involving invasive surgery.

Such techniques generally lengthen the patient's recovery period, and unfortunately limit the success rate in alleviating pain and returning the patient to normal life.

For example, when the spongy bone becomes diseased due to osteoporosis, ischemia necrosis, or cancer, the cortical bone surrounding attention becomes more likely to be fractured or collapsed.

This is because the cavernous bone no longer provides internal support for the surrounding cortical bone.

There are also several other bone diseases, including infected bones, hard bones, or fractures due to severe trauma.

These conditions can lead to malformations, chronic complications, and overall adverse effects on quality of life if not treated successfully.

In the related art, there is a device and a method for correcting the condition of osteoporosis and fracture of bone or other human and animal bone system not caused by osteoporosis (Korean Patent Application No. 2001-7001940, hereinafter referred to as Prior Art 1), as well as inside the cavernous bone. An apparatus and method suitable for injecting a substance into a bone at or near compression failure have been developed (Korean Patent Application No. 2001-7011844, hereinafter referred to as Prior Art 2).

In other words, the prior art 1 employs an expandable body to press the cavernous bone to provide an internal cavity.

In addition, in the case of the prior art 1, when the reinforcing material is injected into the bone, the injection device is approached to the pedestal (pedical) and then artificially inflate the pedestal, so that the osteoplasty is performed. There is a disadvantage in that the patient must be general anesthesia, such general anesthesia was soon accompanied by the pain of the patient.

In addition, the cavity receives the filler material and the filler material is cured to provide new internal structural support for the cortical bone.

However, many internal parts of the body, such as the vasculature and the interior bone, have complex and asymmetric geometries, and even if some internal parts of the body are somewhat symmetrical, they approach the natural axis of symmetry. It was still difficult to do.

In addition, the prior art 2 is designed to inject a reinforcing material through the device by establishing an introduction channel through the device and cortical bone safely into the hole or cortical contact with the cortical bone.

In other words, the prior arts 1 and 2 add a step of adopting a rubber balloon, which is an inflation device in the vertebral body, to the vertebral vertebral surgery technique to concentrate the osteoporotic sponges from the center to the wall surface of the vertebral body.

However, the above step is to ensure an additional space to accommodate the fluid reinforcement material, that is, bone cement through the syringe inside the spinal column, spinal osteotomy technique using a surgical device must be punctured through the cervical spinal column There is a secondary weakness of the potential risk of damaging the spinal column.

Without this natural substrate, the unstructurde bolus of the reinforcing material is formed at the head of the vertebral body when the reinforcing material is injected into the hole created in the compression step.

Because the pressure of the cavernous bones cracks the walls of the vertebrae, it is difficult for the reinforcement injected into the vertebral body to make a strong direct bond with the vertebral walls, thus potentially weakening the vertebral bodies after surgery.

On the other hand, the prior art 2 was not easy to inject the reinforcing material when injecting the reinforcing material after finally installing the material injection conduit.

Thus, in the above prior art 2, the viscosity of the reinforcing material is made very low to facilitate the injection of the reinforcing material, and then filled with the material injection conduit using a syringe and then injected into the bone using the flanger. To this end, a constant tolerance was maintained between the material injection conduit and the flanger.

In other words, if the viscosity of the reinforcing material is high, since the air in the blood and the material injection conduit is not discharged between the material injection conduit and the plunger due to the above tolerance, the viscosity of the reinforcing material has to be diluted to a low level.

However, the above method was not suitable as an alternative to the complications caused by the leakage of reinforcement into cracked bone gaps that have been suggested in spinal surgery.

In addition, since there is a possibility that the reinforcing material injected into the cracked part may leak out, it is inconvenient to inject the reinforcing material carefully into the material injection conduit and wait a long time until the viscosity of the reinforcing material becomes the desired viscosity. In addition, since the environment in the material injection conduit cannot be accurately identified, there are many problems if the proper viscosity is not achieved.

For example, if the viscosity of the reinforcing material is thin, spillage may occur severely. If the viscosity is high, the injection itself may be difficult due to the habit of hardening of the reinforcing material.

In addition, in the prior arts 1 and 2, since the tolerance between the material injection conduit and the flanger is small, when the reinforcement material needs to be supplemented during the injection of the reinforcement material, the reinforcement material is immediately reinforced due to the hardened material in the space between the flanger and the material injection conduit. Inconvenience to replace the material injection conduit without the injection of the material was followed, accordingly, in the prior art 1 and 2, the operation of the reinforcing material cannot be continuously performed, such as the operation of the procedure must be performed again from the beginning. It was.

In addition, in the prior arts 1 and 2, when the bone is drilled, the size of the hole is adjusted using only the extension sheath in the guide wire, which is unclear when the injection position of the reinforcing material is unclear when the puncture of the spongy bone inside the bone is not accurately drilled. As a result, the injection of reinforcing materials becomes difficult.

On the other hand, US Patent No. 3,993,079 (hereinafter, referred to as Prior Art 3) has been developed as a technology prior to the prior arts 1 and 2, and the present invention is an improved invention based on the prior art 3.

That is, the present invention has been made to solve the above conventional problems, in addition to the conventional probe and primary expansion conduit and secondary expansion injection conduit and material injector used in the vertebral body shaping procedure, the insertion of substances into the vertebral body By constructing a material injection conduit designed to be larger than the diameter of the material injector to guide the injection of the perforated material and the reinforcement material, air and other foreign substances in the material injection conduit naturally exist when the reinforcement material such as bone cement is injected. By discharging into the space between the injector and the infusion canal, partial anesthesia in osteoplasty can reduce the pain of the patient due to conventional general anesthesia, and also inject the reinforcement material without air. By keeping the density accurate, the patient's blood, etc. can be prevented from filling inside the bone Providing a reinforcing material injecting apparatus and the injection method in the porous bone marrow, which is aimed to haryeoneunde.

Another object of the present invention is to make a reinforcing material having an optimum viscosity in advance and inject it into the material injection conduit, so that the viscosity of the reinforcing material is low so that the reinforcing material can be discharged to the cracked portion in advance. It is to provide a reinforcing material injection device and a method for injecting the bone in the bone.

Still another object of the present invention is to improve the conventional problem of securing a conventional injection amount when using a substance injector, so that the reinforcement material having optimal viscosity can be continuously injected into the bone or tissue of the body, Depending on the patient's condition, when the injection of more reinforcing material is required than the volume in the material injection conduit, the procedure can be prevented from being interrupted when the normal injection amount is exceeded. It is to provide a reinforcing material injection device and the method of injection in the osteoporotic bone.

Another object of the present invention, while drilling the reinforcing material in the bone through the puncturing means when the reinforcing material injecting the reinforcing material while guiding the injection position of the reinforcing material accurately, while the reinforcing material is highly viscous reinforcement Osteoporotic bone that allows partial anesthesia during osteoplasty while reducing the pain of patients with conventional general anesthesia by allowing the reinforcement to induce expansion through the property of preventing the material from leaking into the cracked part. It is to provide a reinforcing material injection device and its injection method.

1 is a coupling of the probe and the primary expansion conduit in one embodiment of the present invention.

Figure 2 is a cross-sectional view of Figure 1 as an embodiment of the present invention.

Figure 3 is a combination of the probe and the primary expansion conduit and secondary expansion injection conduit in one embodiment of the present invention.

Figure 4 is a cross-sectional view of Figure 3 in one embodiment of the present invention.

Figure 5 is a coupling of the perforated member in one embodiment of the present invention.

Figure 6 is a cross-sectional view of Figure 5 as an embodiment of the present invention.

Figure 7 is a coupling of the perforated member and the secondary expansion injection conduit in one embodiment of the present invention.

8 is a cross-sectional view of FIG. 7 as an embodiment of the present invention.

Figure 9 is a coupling diagram connecting the external syringe to the material injection conduit in one embodiment of the present invention.

10 is a coupling diagram of a state in which the substance injection conduit is inserted into the secondary expansion injection conduit in one embodiment of the present invention.

11 is a cross-sectional view of FIG. 10 in one embodiment of the present invention.

12 is a coupling diagram of a material injection conduit and a material injector in one embodiment of the present invention.

Figure 13 is a cross-sectional view of Figure 12 in one embodiment of the present invention.

Figure 14 is an injection state of the reinforcing material in one embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

One ; Probe 2; Primary expansion conduit

3; Secondary expansion injection conduit 4; Substance injector

4a; First handle 10; Perforated member

11; Drill drill 11a; 3rd handle

11b; Drill portion 12; Drill injection conduit

20; Material injection conduit 21; 2nd handle

22; Syringe connection 30; Plating

100; External syringe A; Space

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a coupling diagram of a probe and a primary expansion conduit as an embodiment of the present invention, Figure 2 is a cross-sectional view of Figure 1 as an embodiment of the present invention.

3 is a coupling diagram of a probe, a primary expansion conduit, and a secondary expansion injection conduit as an embodiment of the present invention, and FIG. 4 is a cross-sectional view of FIG. 3 as an embodiment of the present invention.

Figure 5 is a coupling of the perforated member in one embodiment of the present invention, Figure 6 is a cross-sectional view of Figure 5 as an embodiment of the present invention.

Figure 7 is a coupling of the perforated member and the secondary expansion injection conduit in one embodiment of the present invention, Figure 8 is a cross-sectional view of Figure 7 as an embodiment of the present invention.

9 is a coupling diagram connecting an external syringe to a material injection conduit according to one embodiment of the present invention, and FIG. 10 is a coupling view of a state in which a material injection conduit is inserted into a secondary expansion injection conduit according to an embodiment of the present invention. 11 is a cross-sectional view of FIG. 10 as an embodiment of the present invention.

Figure 12 is a coupling diagram of the material injection conduit and the material injector in one embodiment of the present invention, Figure 13 is a cross-sectional view of Figure 12 as an embodiment of the present invention, Figure 14 is a embodiment of the reinforcing material of the present invention The state of injection is also.

As shown in Figures 1 to 14, the primary expansion conduit (2) having a probe (1), and the graduation indicator (2a), of course, to inject a reinforcing material such as bone cement into the interior of the vertebral body, In the conventional reinforcement material injection device composed of a secondary expansion injection conduit (3) and a material injector (4) having a first handle (4a),

A member 10 which is inserted into the secondary expansion injection conduit 3 and serves to inject the reinforcing material into the vertebral body to accurately guide the injection position of the reinforcing material while acting as an injection pipe;

It further comprises a material injection conduit 20 having a second handle 21 to continuously guide the injection of the reinforcing material into the hole in the vertebral body perforated from the punching member 10.

According to another aspect, the punching member 10,

A drill drill 11 having a third handle 11a and a drill portion 11b and a drill drill 11 are inserted into the vertebral body so as to drill a hole into which a reinforcing material can be injected. 11) characterized in that it consists of a drill injection conduit 12 to adjust the insertion depth.

According to another aspect, between the material injection conduit 20 and the material injector 4,

When the reinforcing material is injected is characterized in that the space (A) for guiding the air and other foreign matter present in the material injection conduit 20 to be discharged to the outside.

According to yet another aspect, the second handle 21,

By replacing the material injector (4) is characterized in that to form a syringe connector 22 for guiding the connection of the external syringe 100 so that the injection of the reinforcing material through the material injection conduit 20 is made continuously.

According to another aspect of the probe (1), primary expansion conduit (2), secondary expansion injection conduit (3), drilling drill 11, drill injection conduit 12, material injection conduit 20 In the upper and lower part or the lower part,

Secondary infection according to the vertebral cosmetic surgery, as well as to form a plated portion 30 to facilitate the treatment according to the vertebral cosmetic surgery.

On the other hand, the reinforcing material injection method into the vertebral body made by the injection device,

Inserting the probe 1 into the center of the vertebral body and engaging the primary expansion conduit 2 with the probe 1 to position the primary expansion conduit 2 on the surface of the vertebral body;

Inserting the primary expanding conduit (2) inward from the surface of the vertebral body;

Fastening the secondary expansion injection conduit (3) to the primary expansion conduit (2) to position the secondary expansion injection conduit (3) on the surface of the vertebral body;

Inserting the secondary expansion injection conduit (3) inward from the surface of the vertebral body;

Removing the probe (1) and the primary expansion conduit (2) from the secondary expansion injection conduit (3);

After inserting the drilling member 10, which is a combination of the drill drill 11 and the drill injection conduit 12 into the secondary expansion injection conduit (3), a hole through which the reinforcing material is injected into the vertebral body through the drill drill 11 Puncturing;

Removing the punching member 10 from the secondary expansion injection conduit 3 and connecting the external syringe 100 filled with the reinforcing material to the material injection conduit 20;

Inserting the material injection conduit 20 connected to the external injection device 100 into the secondary expansion injection conduit 3 and introducing the reinforcing material filled in the external injection device 100 into the material injection conduit 20;

Checking the viscosity of the reinforcing material introduced into the material injection conduit 20 and then removing the external syringe 100 from the material injection conduit 20;

Inserting a material injector 4 into the material injection conduit 20 and sliding the material injection conduit 20 to inject the reinforcing material filled in the material injection conduit 20 into the interior of the vertebral body through a hole drilled in the vertebral body; Characterized in proceeding to.

Referring to Figures 1 to 14 attached to the operation of the embodiment of the present invention configured as described above are as follows.

First, the probe 1 having the plating part 30 in the upper and lower end portions is inserted into the center of the vertebral body.

Thereafter, as shown in FIGS. 1 and 2, the primary expansion conduit 2 having the plating portion 30 as well as the scale display portion 2a is fastened to the probe 1 inserted in the center of the vertebral body.

And, with the primary expansion conduit 2 positioned on the surface of the vertebral body, the primary expansion conduit 2 is inserted inward from the surface of the vertebral body.

In the next procedure, as shown in FIGS. 3 and 4, the secondary expansion injection having the plated portion 30 at the lower portion thereof is manufactured to have a predetermined diameter so that both the probe 1 and the primary expansion conduit 2 can be accommodated. After the conduit 3 is fastened to the primary expansion conduit 2, the secondary expansion injection conduit 3 is positioned on the surface of the vertebral body.

Thereafter, the secondary expansion injection conduit 3 is inserted inward from the surface of the vertebral body, and then the probe 1 and the primary expansion conduit 2 are removed from the secondary expansion injection conduit 3.

Next, as shown in FIGS. 7 and 8, the drilling member 10, which is a combination of the drill drill 11 and the drill injection conduit 12 having the plating part 30, is formed as the secondary expansion injection conduit 3. Insert it.

That is, the drilling member 10 is a drill drill 11 having a third handle (11a) and a drill portion (11b) to drill a hole into which the reinforcing material can be injected into the vertebral body, and the drill drill (11) inside To be inserted into the drill injection conduit 12 to adjust the insertion depth of the drill drill 11, but the bar is inserted into the drill injection conduit (12).

Then, after inserting the drill injection conduit 12 into which the drill drill 11 is inserted into the secondary expansion injection conduit 3, when the operator turns the third handle 11a formed on the drill drill 11, The drill part 11b formed in the drill drill 11 drills a hole through which a reinforcing material may be injected into the vertebral body.

Then, the drill drill 11 and the drill injection conduit 12 serves as an injection pipe when the reinforcement material such as bone cement is injected, and accurately guides the injection position of the reinforcement material, as well as a highly viscous reinforcement. The ability to prevent the material from leaking into the slightly cracked portion allows the reinforcement to induce expansion in the bone.

Here, the drill injection conduit 12 into which the drill drill 11 is inserted serves to adjust the insertion depth of the drill drill 11.

On the other hand, after the hole drilling is finished by the drilling member 10, the drilling member 10 is removed from the secondary expansion injection conduit (3).

Thereafter, the reinforcement material having an optimum viscosity is prevented from being discharged to the cracked portion due to the low viscosity, and then, the reinforcement material is made in advance and injected into the external syringe 100, and as shown in FIG. ) Is connected to the material injection conduit 20 having the plated portion 30 at the lower portion.

That is, since the second handle 21 of the material injection conduit 20 is formed in the syringe connection part 22, the external syringe 100 into which the reinforcing material is injected into the syringe connection part 22 can be connected.

In the next procedure, after inserting the material injection conduit 20 connected to the external syringe 100 into the secondary expansion injection conduit 3 as shown in FIGS. 10 and 11, the operator is filled in the external syringe 100. Reinforcing material is introduced into the material injection conduit (20).

Thereafter, the operator once again confirms the viscosity of the reinforcing material introduced into the material injection conduit 20, and then removes the external syringe 100 from the material injection conduit 20.

In the following procedure, after inserting the material injector 4 into the material injection conduit 20 as shown in Figures 12 and 13, by pressing the first handle (4a) of the material injector 4, the material The reinforcing material filled in the injection conduit 20 is such that the injection can be made into the vertebral body through a hole drilled in the vertebral body.

At this time, when the reinforcing material is injected into the vertebral body through the substance injection conduit 20, the air present in the substance injection conduit 20 as well as other foreign substances may be injected into the substance injector 4 and the substance injection conduit. Since it is to be discharged to the outside through the space (A) formed between the 20, the injection of the vertebral body through partial anesthesia is possible, as well as the air is not included in the reinforcement material while maintaining the density of the patient accurately The blood and the like can be prevented from filling inside the bone.

On the other hand, when the injection of the reinforcing material into the vertebral body through the material injection conduit 20 as described above, if the injection of more reinforcing material than the volume in the material injection conduit 20 according to the condition of the patient, After removing the material injector 4, the external injection device 100 is connected to the material injection conduit 20 again.

Then, it is possible to continuously inject the reinforcing material into the interior of the vertebral body, and to improve the problem of procedure interruption that may occur when the conventional injection amount is exceeded.

As described above, the present invention allows osteoporosis as well as the air present in the material injection conduit to be naturally discharged into the space between the material injection and the material injection conduit when the reinforcing material such as bone cement is injected. Partial anesthesia can reduce the patient's pain caused by conventional general anesthesia, and maintain the injection density of reinforcing material accurately in the absence of air to prevent the patient's blood from filling inside the bone. It is characterized by.

In addition, the present invention has a feature that can be prevented in advance that the reinforcing material is discharged to the cracked portion is low viscosity of the reinforcing material.

In addition, according to the condition of the patient, when the injection of more reinforcing material than the volume in the material injection conduit is required, the procedure is stopped when the conventional injection amount is exceeded, such as continuous injection of the reinforcing material by replacing only the material injector. It is a characteristic to prevent becoming.

In addition, the present invention, while injecting the reinforcing material, the puncture member serves as an injection pipe while guiding the injection position of the reinforcing material accurately, while reinforcing material through the highly viscous reinforcing material is prevented from leaking into the cracked part By allowing the material to induce swelling, partial anesthesia is possible during osteoplasty while reducing the pain of the patient due to conventional general anesthesia.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

Claims (6)

Ordinary reinforcement material injection consisting of a probe, a primary expansion conduit having a graduation mark, a secondary expansion injection conduit, and a material injector having a first handle to inject a reinforcing material such as bone cement into the vertebral body In the apparatus, A member which is inserted into the second expansion injection conduit and serves as an injection pipe, and drills a hole into which a reinforcing material can be injected into the vertebral body to accurately guide the injection position of the reinforcing material; And a material injection conduit having a second handle so as to continuously guide the reinforcement material injection from the puncture member to the hole in the vertebral body which is punctured. The method of claim 1, wherein the perforation member, A drill drill having a third handle and a drill portion to drill a hole into which a reinforcing material can be injected into the vertebral body, and a drill injection conduit for adjusting the insertion depth of the drill drill while allowing the drill drill to be inserted therein; Device for injecting reinforcing material in osteoporotic bone. According to claim 1, Between the material injection conduit and the material injector, Apparatus for injecting reinforcement material in osteoporotic bone, characterized in that the space is formed to guide the air and other foreign matter present in the material injection conduit to be discharged to the outside when the reinforcement material is injected. The method of claim 1, wherein the second handle of the material injection conduit, Reinforcement material injection device for osteoporotic bone, characterized in that for forming a syringe connection for guiding the connection of the external syringe to continuously inject the reinforcement material through the material injection conduit through the replacement of the material injector. According to claim 1, wherein the upper and lower portions or the lower portion of the probe, the primary expansion conduit, secondary expansion injection conduit, drilling drill, drill injection conduit, material injection conduit, Apparatus for injecting a reinforcing material in osteoporotic bone, characterized in that the formation of a plate for promoting the treatment according to the vertebral cosmetic surgery, as well as the secondary infection during the vertebral cosmetic surgery. Inserting the probe into the center of the vertebral body and then engaging the primary expansion conduit with the probe to position the primary expansion conduit on the surface of the vertebral body; Inserting the primary dilatation conduit inward at the surface of the vertebral body; Fastening a secondary expansion injection conduit to the primary expansion conduit to position the secondary expansion injection conduit on the surface of the vertebral body; Inserting the secondary expansion injection conduit inwardly at the surface of the vertebral body; Removing the probe and the primary expansion conduit from the secondary expansion injection conduit; Inserting a drilling member which is a combination of a drilling drill and a drill injection conduit into the secondary expansion injection conduit, and then drilling a hole into which a reinforcing material is injected into the vertebral body through the drilling drill; Removing the perforated member from the secondary expansion injection conduit and connecting an external syringe filled with a reinforcing material to the material injection conduit; Inserting the substance injection conduit connected to the external syringe into the secondary expansion injection conduit and introducing the reinforcing material filled in the external syringe into the substance injection conduit; Checking the viscosity of the reinforcing material introduced into the material injection conduit and removing the external syringe from the material injection conduit; Inserting a substance injector into the substance injection conduit and sliding it to inject the reinforcing material filled in the substance injection conduit into the vertebral body through a hole drilled in the vertebral body; Reinforcing material injection method in the osteoporotic bone, characterized in that proceeding to.