KR101125230B1 - Gap measuring device for artificial knee joint - Google Patents

Abstract

The present invention relates to a device for measuring the gap of the artificial knee joint. The present invention comprises two cylinder housings installed in parallel at regular intervals; A piston movably installed in the cylinder housing; A cylinder rod installed at one end of the piston and extending to the outside of the cylinder housing; A tibia plate fixed to the cylinder housing and supported by the tibia; A femur plate fixedly installed at each end of the cylinder rod and supported on the inner side and the outer side of the femur; It is made of a transparent material to the cylinder housing, and comprises a graduation window marked with a scale for measuring the position of the piston. According to the present invention, the femur plate is in close contact with the femur by a constant force by pneumatic or hydraulic pressure has the effect of accurate extension and bending interval measurement. In addition, the femur plate is installed so as to be movable, respectively, there is an effect that can accurately measure the interval between the inside and outside of the femur.

Artificial knee joint, temple, flexion

Description

Gap measuring device for artificial knee joint

The present invention relates to an artificial knee joint, and more particularly, to a device for measuring the gap of the artificial knee joint using pneumatic or hydraulic pressure to more accurately measure the extension and flexion gap of the artificial knee joint.

Artificial knee arthroplasty, which replaces a knee joint damaged or modified by congenital malformation, trauma, disease, or degenerative arthritis, is widely used. Total knee arthroplasty is increasing rapidly as the elderly population increases. Artificial knee arthroplasty is known as a good procedure to alleviate pain and restore joint function in patients with end-stage arthritis, but some patients have complications such as joint stiffness, instability and premature wear of polyethylene.

The most important thing in the procedure of total knee arthroplasty is the correct leg alignment and measurement of flexion and extension interval. The flexion interval and extension interval are well illustrated in FIGS. 1 and 2.

Referring to this, the extension interval in the knee arthroplasty refers to the interval between the lower end of the femur (1) and the osteotomy surface of the upper tibia (2) in the state of pinning the knee, as shown in Figure 1, As shown in FIG. 2, the bending interval refers to the interval between the rear end of the femur 1 and the osteoarticular surface of the top of the tibia 2 in a curved state, ie, in a curved state.

As a mechanism for measuring the bending interval and extension interval described above, there have been a spreader, a spacer block, and a trial component.

However, the above-described prior art has the following problems.

First, the spreader has the advantage of being able to quantify the bending and extension intervals in mm units. However, there is a problem in that the interval cannot be kept constant because the interval must be increased by frequency operation.

Second, the spacer block can be compared with the bending and extension intervals, for example by inserting a fixed block of a predetermined thickness in increments of 2 mm, there is a problem that accurate measurement is difficult when the bending and extension intervals are 2 mm or less.

Third, unlike the spreader or spacer block, the trial component can continuously measure the distance from 0 ° to the maximum bending and extension, but has a problem in that it cannot reflect the tension of the soft tissue at a predetermined angle.

Looking at the bending and extension interval measuring apparatus used in the prior art as seen above, it can be seen that the two problems must be largely solved. That is, during surgery, the flexion and extension interval of the knee should be accurately measured, and the gap between the knee joint should be maintained with a constant force in the state positioned between the knee joint. Conventional instruments have shown problems such as difficulty in maintaining spacing when accuracy is high and accuracy when maintaining spacing.

As such, if the artificial knee joint is not accurately measured, the extension and flexion movements may not be performed smoothly in a state where the artificial knee joint is replaced, and it may cause problems in the muscles and ligaments of the leg.

Accordingly, it is an object of the present invention to solve the problems of the prior art as described above, to provide a gap measuring device of the artificial knee joint that can be closely adhered to the femur with a constant force to make a more accurate gap measurement.

It is another object of the present invention to provide an apparatus for measuring a gap between a knee joint having a structure capable of measuring the gap between the inside and the outside of the femur.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

According to a feature of the present invention for achieving the object as described above, the present invention comprises a cylinder housing; A piston movably installed in the cylinder housing; a cylinder rod installed at one end of the piston and extending out of the cylinder housing; A tibia plate fixed to the cylinder housing and supported by the tibia; It is fixed to the front end of the cylinder rod, characterized in that it comprises a femur plate supported on the femur.

The piston is characterized in that the movable by the cylinder housing by hydraulic or pneumatic.

The femur plate, the inner plate for supporting the inside of the femur; It characterized in that it comprises an outer plate for supporting the outside of the femur.

A hollow inlet bar is connected between the cylinder housings, and the inlet bar is connected to a tube through which air or oil passes.

A partition wall is installed at the center of the inflow bar so that air or oil is separated and introduced into the partition wall.

One end of the tube is characterized in that the pressure gauge for measuring the pressure inside the cylinder housing is connected.

In the center of the tibial plate is characterized in that the avoidance groove is formed in the recess to prevent interference with the cruciate ligament.

The cylinder housing is made of a transparent material, characterized in that the graduation window is displayed to display the scale for measuring the position of the piston is installed.

According to another feature of the invention, the present invention comprises: two cylinder housings installed in parallel at regular intervals; and a piston movably installed in the cylinder housing; A cylinder rod installed at one end of the piston and extending to the outside of the cylinder housing; A tibia plate fixed to the cylinder housing and supported by the tibia; A femur plate fixedly installed at each end of the cylinder rod and supported on the inner side and the outer side of the femur; The cylinder housing is made of a material that can be seen, characterized in that it comprises a scale window for displaying the scale for measuring the position of the piston.

The piston is characterized in that the movable by the cylinder housing by hydraulic or pneumatic.

The femur plate, the inner plate for supporting the inside of the femur; It characterized in that it comprises an outer plate for supporting the outside of the femur.

In the center of the tibial plate is characterized in that the avoidance groove is formed in the recess to prevent interference with the cruciate ligament.

A hollow inlet bar is connected between the cylinder housings, and the inlet bar is connected to a tube through which air or oil passes.

A partition wall is installed at the center of the inflow bar so that air or oil is separated and introduced into the partition wall.

One end of the tube is characterized in that the pressure gauge for measuring the pressure inside the cylinder housing is connected.

In the present invention, by using a pneumatic cylinder or a hydraulic cylinder to measure the extension and flexion interval of the artificial knee joint, the femur plate is in close contact with the femur by a constant force by pneumatic or hydraulic pressure has the effect of accurate extension and flexion interval measurement.

In addition, the femur plate is installed so as to be movable, respectively, there is an effect that can accurately measure the interval between the inside and outside of the femur.

As a result, since the gap measurement of the artificial knee joint is made through the apparatus for measuring the distance between the artificial knee joints according to the present invention, the patient's legs are not exerted after the operation, and thus side effects do not occur and the patient's satisfaction is increased.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the gap measuring device of the artificial knee joint according to the present invention will be described in detail.

Figure 3 is a perspective view showing the distance measuring device of the artificial knee joint according to the present invention, Figure 4 is a perspective view showing that air or oil is introduced into the cylinder housing constituting an embodiment of the present invention. In the following description, reference numerals of FIGS. 1 and 2 are used as necessary.

As shown in these figures, the apparatus for measuring the distance between the artificial knee joints according to the present invention includes a cylinder housing 10; A piston (13) movably installed in the cylinder housing (10); A cylinder rod 14 installed at one end of the piston 13 and extending to the outside of the cylinder housing 10; A tibial plate 24 fixed to the cylinder housing 10 and supported by the tibia 2; It is fixed to the front end of the cylinder rod 14, and includes a femur plate 20 supported on the femur (1).

The cylinder housing 10 is installed in parallel at two regular intervals. A predetermined moving space 11 is formed in the cylinder housing 10, and the cylinder housing 10 is connected and fixed to each other through a connection bar 12. In this embodiment, a pneumatic cylinder or a hydraulic cylinder is preferably used.

The cylinder housing 10 is preferably provided in two parallel to each other as in the present embodiment. This will be described below, but to measure the distance between the inside and outside of the femur (1), respectively. However, the cylinder housing 10 is not necessarily installed in two, but may be configured as one to measure the extension and bending intervals.

In addition, the piston 13 is installed to be movable in the moving space 11 of the cylinder housing 10. One end of the piston 13 is provided with a cylinder rod 14. The cylinder rod 14 may be integrally formed with the piston 13 or may be configured to be coupled to one end of the piston 13 as a separate component.

On the other hand, in the present embodiment, as the parts respectively supported on the femur (1) and the tibia (2), the femur plate 20 and the tibia plate 24 is provided. The femur plate 20 is fixed to the tip of the cylinder rod 14, as can be seen in Figure 3, the inner plate 21 and the outer side of the femur 1 supporting the inside of the femur 1 It consists of an outer plate 22 for supporting. 1 and 2, since the parts protruding inward and outward are different from each other, measuring the extension and flexion intervals for each of the femurs 1 may improve the accuracy of the gap measurement.

The femur plate 20 is a plate shape is formed in a substantially curved outer surface. The femur plate 20 has a shape in which the width increases toward the outside from the tip of the cylinder rod 14.

The tibial plate 24 is installed to be fixed to one side of the cylinder housing 10. In this embodiment, the tibial plate 24 is installed to be fixed to the rear of the cylinder housing 10, respectively. The tibia plate 24 serves to support the upper end of the tibia 2 as shown in FIGS. 5 and 6.

On the other hand, the tibial plate 24 has a relatively larger area than the femoral plate 20, one side of the avoidance groove 26 is formed. The avoidance groove 26 is formed to prevent interference with the cruciate ligament when measuring the distance of the artificial knee joint.

Referring back to FIG. 3, the inlet bar 30 is installed between the cylinder housings 10. The inflow bar 30 is installed in parallel with the connection bar 12. The inflow bar 30 is a portion in which air or oil is introduced from the outside. To this end, the inlet bar 30 has a hollow shape, and the part connected to the cylinder housing 10 is open. This is illustrated well in FIG.

In addition, a partition wall 31 is installed at the center of the inflow bar 30. The partition wall 31 serves to allow the air or oil introduced from the two parts to be separated without being mixed and introduced into the cylinder housing 10. The pressure gauge 36 to be described later by the partition wall 31 may measure the pressure acting on the inner plate 21 and the outer plate 22, respectively.

The inlet bar 30 is provided with a tube connecting portion (32). The tube connection part 32 is constituted by a pair, and the tube 34 is connected to each other. The tube 34 is a portion through which air or oil passes, and a pressure gauge 36 is connected to one end of the tube 34. The pressure gauge 36 is a part for measuring the pressure of the pneumatic cylinder or the hydraulic cylinder.

On the other hand, the cylinder housing 10 is provided with a graduated window 40, respectively. The scale window 40 is made of a transparent material such as transparent glass, the scale is displayed. The graduated window 40 is a part that allows one end of the piston 13 to be seen from the outside, and the operator can easily measure the extension and the bending interval through the graduated window 40 with the naked eye.

According to the apparatus for measuring the gap of the artificial knee joint according to the present invention as described above, it is possible to measure the extension and flexion interval of the artificial knee joint using a pneumatic cylinder or a hydraulic cylinder, so that the accurate gap can be measured, and the femoral plate by pneumatic or hydraulic pressure. 20 and the tibial plate 24 can be supported in close contact with the femur 1 and the tibia 2, respectively, so that the interval can be maintained with a constant force.

Hereinafter, the operation of the artificial knee joint gap measuring apparatus according to the present invention having the configuration as described above will be described in detail.

First, the operator places the femoral plate 20 and the tibia plate 24 between the femur 1 and the tibia 2 as shown in FIGS. 5 and 6 to measure the extension and flexion intervals of the artificial knee joint. Position it. Here, the tibial plate 24 is supported by the tibia 2 as a reference plate. In this state, the operator introduces air or oil at a predetermined pressure through the tube 34.

Air or oil passing through the tube 34 is introduced into the inlet bar 30 through the tube connection part 32, respectively, into the moving space 11 of the cylinder housing 10. This is illustrated well in FIG.

Air or oil introduced into the moving space 11 pushes one end of the piston 13 to a predetermined pressure, and the inner plate 21 and the outer plate 22 move upward, respectively, and the femur 1 Close to) When the inner plate 21 and the outer plate 22 are in close contact with the femur 1, respectively, the operator checks the position of the piston 13 through the scale window 40, and extends the extension and flexion intervals of the artificial knee joint. It can be measured.

As described above, in this embodiment, since the inside and the outside of the femur 1 can be measured, more accurate extension and bending intervals can be measured, and the support of the femur 1 with a constant force by pneumatic or hydraulic pressure is an error. Accurate measurements are possible without

On the other hand, when the extension and flexion interval of the artificial knee joint to be replaced is measured, the artificial knee joint is installed after the lower femur and the upper tibia through the femur and tibial osteotomy.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self evident.

For example, in the present embodiment, although the distance between the artificial knee joint is measured by a pneumatic cylinder or a hydraulic cylinder, it is not necessarily limited thereto, and may be measured by a cylinder using another driving source.

1 is an illustration showing the extension interval of the artificial knee joint.

Figure 2 is an exemplary view showing the bending interval of the artificial knee joint.

Figure 3 is a perspective view showing a gap measuring device of the artificial knee joint according to the present invention.

Figure 4 is a perspective view showing that air or oil is introduced into the cylinder housing constituting an embodiment of the present invention.

5 is an exemplary view showing the extension interval measured by the apparatus for measuring the distance between the artificial knee joint according to the present invention.

Figure 6 is an illustration showing the measurement of the bending interval by the gap measuring device of the artificial knee joint according to the present invention.

Explanation of symbols on the main parts of the drawings

1: femur 2: tibia

10: cylinder housing 12: connecting bar

13: piston 14: cylinder rod

20 femoral plate 21 inner plate

22: outer plate 24: tibia plate

26: evasion groove 30: inflow bar

31 partition wall 32 tube connection

34 tube 36 pressure gauge

40: scale window

Claims (15)

Cylinder housing; A piston movably installed in the cylinder housing; A cylinder rod installed at one end of the piston and extending to the outside of the cylinder housing; A tibia plate fixed to the cylinder housing and supported by the tibia; It is fixed to the front end of the cylinder rod, and includes a femur plate supported on the femur, The piston is the artificial knee joint gap measurement device, characterized in that the movable by the cylinder housing by hydraulic or pneumatic. According to claim 1, The femur plate, An inner plate for supporting the inside of the femur; Apparatus for measuring the gap of the artificial knee joint, characterized in that it comprises an outer plate for supporting the outside of the femur. The method of claim 1, A hollow inlet bar is connected between the cylinder housings, and the inlet bar is connected to a tube through which air or oil passes. The method of claim 3, wherein A partition wall is installed at the center of the inflow bar so that air or oil is separated and introduced into the partition wall. The method of claim 4, wherein One end of the tube is connected to the pressure gauge for measuring the pressure in the cylinder housing, characterized in that the artificial knee joint gap measuring apparatus. 6. The method according to any one of claims 1 to 5, An interval measuring device of the artificial knee joint, characterized in that formed in the center of the tibial plate to avoid interference with the cruciate ligament. The method of claim 6, The cylinder housing is made of a transparent material, the interval measuring device of the artificial knee joint, characterized in that the graduation window is displayed is displayed for measuring the position of the piston. Two cylinder housings installed in parallel at regular intervals; A piston movably installed in the cylinder housing; A cylinder rod installed at one end of the piston and extending to the outside of the cylinder housing; A tibia plate fixed to the cylinder housing and supported by the tibia; A femur plate fixedly installed at each end of the cylinder rod and supported on the inner side and the outer side of the femur; It is made of a transparent material in the cylinder housing, and comprises a graduation window marked with a scale for measuring the position of the piston, The piston is the artificial knee joint gap measurement device, characterized in that the movable by the cylinder housing by hydraulic or pneumatic. The method of claim 8, wherein the femur plate, An inner plate for supporting the inside of the femur; Apparatus for measuring the gap of the artificial knee joint, characterized in that it comprises an outer plate for supporting the outside of the femur. The method of claim 8, An interval measuring device of the artificial knee joint, characterized in that formed in the center of the tibial plate to avoid interference with the cruciate ligament. The method according to any one of claims 8 to 10, A hollow inlet bar is connected between the cylinder housings, and the inlet bar is connected to a tube through which air or oil passes. The method of claim 11, A partition wall is installed at the center of the inflow bar so that air or oil is separated and introduced into the partition wall. 13. The method of claim 12, One end of the tube is connected to the pressure gauge for measuring the pressure in the cylinder housing, characterized in that the artificial knee joint gap measuring apparatus. delete delete

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