KR102713912B1 - Humeral Stem for Fractures - Google Patents

Abstract

The present invention relates to a humerus stem for fracture, and more particularly, to a humerus stem for fracture, which is characterized in that when performing artificial shoulder joint replacement surgery on a patient who has suffered a shoulder fracture, the surgical time is shortened and the surgical risk of the patient is lowered by not having to form a hole for passing a suture through the humerus shaft.

Description

Humeral Stem for Fractures

The present invention relates to a humerus stem for fracture, and more particularly, to a humerus stem for fracture, which is characterized in that when performing artificial shoulder joint replacement surgery on a patient who has suffered a shoulder fracture, the surgical time is shortened and the surgical risk of the patient is lowered by not having to form a hole for passing a suture through the humerus shaft.

The shoulder joint refers to the joint between the scapula (scapula) and the humerus (humerus). The scapula has a glenoid that accommodates the humerus, and the hemispherical humeral head is formed at the very top of the humerus.

In order to form a ball and socket joint, the humeral head comes into contact with the glenoid of the scapula and moves to enable natural arm movement. When the shoulder joint loses its function due to arthritis, trauma, etc., an artificial shoulder joint replacement surgery is performed to replace the destroyed joint with an implant so that the shoulder joint can perform its normal function.

Figure 1 is a drawing illustrating the anatomical shape of a typical humerus, which is disclosed in U.S. Patent Publication No. US2011/0054478A1 (March 3, 2011).

Referring to Figure 1, the proximal humerus (H) is divided into a convex humeral head (HH), a concave humeral neck (HN) adjacent to the humeral head, a greater tubercle (GT) and lesser tubercle (LT) which are protruding projections on the humerus, and a biceps groove (BG) which is concave and located between the greater tubercle and lesser tubercle.

In an artificial shoulder joint replacement surgery, the humeral head (HH) of FIG. 1 is resected, the humeral stem (Humeral Stem) of the artificial shoulder joint implant is inserted into the medullary cavity of the humerus, and then a humeral head (Humeral Head) conforming to the anatomical shape is combined with the humeral stem, or a humeral tray (Humeral Tray) that is opposite to the anatomical shape is combined.

However, in the case of patients who have suffered a humerus fracture, artificial shoulder joint replacement cannot be performed using the general surgical method. In this case, the surgeon connects the bone fragments separated into the greater tuberosity (GT) and lesser tuberosity (LT) using sutures.

Figure 2 is a drawing illustrating a surgical procedure using a conventional fracture humerus stem (90), which is disclosed in Stryker. (2007). Reunion Fracture System Surgical Protocol.

Referring to FIG. 2, a conventional humerus stem (90) for fracture has a suture hole (911) formed on the body portion (91), and a suture is connected to a bone (B1, B2) separated from a humerus shaft (HS), and the suture connected to the separated bone passes through the suture hole (911) to connect to the opposite bone, thereby causing the bones separated through the suture (S) to gather around the stem (90) and restore their original shape.

In this process, the conventional technology performed a drilling operation to form a hole (D) for passing longitudinally connected sutures (SL) through the humeral shaft (HS) in order to longitudinally connect transversely connected sutures (SH) among sutures (S), as illustrated in FIG. 2.

Simply putting a few holes in the skull may not seem like a big deal, but adding these holes in a surgical environment where blood, bodily fluids, etc. are flowing and the patient is under anesthesia can actually increase the surgical time, and this increased surgical time can ultimately lead to a higher surgical risk for the patient undergoing the surgery.

In addition, the process of drilling a hole (D) as shown in Fig. 2 for inserting a suture into the humeral shaft (HS) of a patient whose bone strength is already weakened due to a fracture is by no means an easy task, and especially in the case of patients with low bone density, such as the elderly, problems such as the bone surrounding the hole being broken together or the bone falling off in pieces due to the impact during the drilling process may occur.

That is, forming a hole for suture connection in the humeral shaft (HS) using the conventional technique not only increases the surgical time and thus the risk of the surgery, but also causes the problem of unnecessary loss of the patient's bone that could be preserved.

When a hole (D) is made in the humeral shaft (HS) and a longitudinal suture (SL) is connected to a transverse suture (SH), it may be expected that one side of the longitudinal suture (SL) will be fixed to the humeral shaft (HS) and thereby prevent separation of the humeral stem (90) inserted into the humeral shaft (HS) by pulling on it. However, in reality, the fixing force developed by the suture itself was insufficient to prevent detachment of the stem (90), and since sufficient fixing force was already developed between the humeral stem (90) and the humeral shaft (HS) by bone cement, etc., it was not necessary to form a hole on the humeral shaft (HS) to pass the longitudinal suture through it.

Accordingly, the related industry is demanding the development of a new technology that can shorten the surgical time and lower the surgical risk of patients by allowing the surgery to be performed without making unnecessary holes on the humerus to insert sutures when performing artificial shoulder joint surgery on fracture patients.

United States Patent Publication No. US2011/0054478A1 (2011.3.3.)

Stryker. (2007). Reunion Fracture System Surgical Protocol.

The present invention has been devised to solve the above problems.

The purpose of the present invention is to provide a fracture humeral stem applicable to the shoulder of a fracture patient so that shoulder joint replacement can be performed quickly and accurately.

Another object of the present invention is to reduce the surgical risk for a patient by shortening the surgical time without having to form a hole for passing a suture through the humeral shaft.

Another object of the present invention is to omit the drilling process for inserting a suture into the humerus during an artificial shoulder joint replacement surgery for a fracture patient, thereby preventing unnecessary bone loss caused by damage such as bone around the hole being crushed or broken together by the drilling impact.

Another object of the present invention is to enable patients with low bone density or low bone strength, such as the elderly, to easily undergo artificial shoulder joint replacement surgery even if they have suffered a shoulder fracture, by not having to directly drill a suture hole in the patient's humerus.

Another object of the present invention is to form a hole that penetrates the front and rear sides of a body part on the outside of the body part and then penetrates the other side, thereby making the thickness of the connecting part through which the suture needle passes relatively thin, thereby allowing a suture needle of a curved shape to easily pass through the connecting part.

Another object of the present invention is to provide a connecting insertion portion including a front inclined surface and a rear inclined surface so that the insertion depth increases from the inside to the outside of the stem, thereby facilitating the passage of a suture needle and shortening the surgical time.

Another object of the present invention is to prevent the problem of a significant decrease in the strength of the stem due to the formation of a recessed portion by forming a suture connection hole that penetrates the anterior and posterior inclined surfaces in a parallel direction of the anteroposterior axis of the stem, while shortening the length of the suture connection hole through which the suture needle passes, so that the surgeon can easily insert and remove the suture needle into and from the suture connection hole during the procedure.

Another object of the present invention is to reinforce the strength of a stem that has been reduced by forming a front-back and side reinforcement surface that is formed to extend from an end of the front-back and side slopes so that the depth of penetration becomes shallower, thereby forming the front-back and side slopes.

Another object of the present invention is to form a pin portion protruding on the outside of the body portion so that a separated bone portion can be easily connected to the stem through a suture, and to prevent rotation of the stem, while ensuring that the direction in which the pin portion protrudes is in the direction in which the biceps groove is located, thereby forming a reference for confirming the exact insertion position during the procedure.

Another object of the present invention is to configure a pin portion facing the biceps groove so that a retroversion can be referred to during the stem insertion process.

Another object of the present invention is to provide a first pin portion positioned in the anterior direction at a predetermined angle based on the medial-lateral axis of the stem, and a second pin portion positioned in the posterior direction at a predetermined angle based on the medial-lateral axis of the stem, such that when the same stem is implanted into the humerus of the right arm, one of the pins points to the biceps groove of the right humerus, and when the same stem is implanted into the humerus of the left arm, the other of the pins points to the biceps groove of the left humerus.

Another object of the present invention is to prevent unnecessary waste of cost by configuring the first pin portion and the second pin portion to be symmetrical with respect to the inner and outer axes of the stem so that the same stem can be used for both the right humerus and the left humerus, thereby facilitating inventory management, etc.

Another object of the present invention is to prevent rotation of the stem by the pin by forming a suture penetration hole on the wing portion of the pin portion, and to restore the original anatomical shape of the humerus by passing a suture connected to a separated bone through the suture penetration hole, thereby gathering the separated bones together centered on the stem inserted into the humerus shaft.

Another object of the present invention is to form a fastening portion on the inside of the body of the stem so that a separated bone portion can be easily fastened to the stem using a suture.

Another object of the present invention is to provide a suture tying hole that penetrates from one side of the tying insertion portion into the front and rear sides of the body portion, thereby shortening the length of the region through which a curved suture needle passes, thereby making it easy to pass the suture needle through the suture tying hole during surgery, thereby promoting convenience of the procedure and shortening the surgery time.

Another object of the present invention is to solve the problem of making it difficult to insert the stem into a bone when the stem axis is bent by forming the stem axis straight.

Another object of the present invention is to improve the workability of the stem and to exhibit an anti-rotation effect by making the cross-sectional shape of the body portion perpendicular to the straight stem axis non-circular.

Another object of the present invention is to prevent situations in which the bone is broken by a sharp stem edge when impacting the stem into the intramedullary canal of the humerus of a patient with a small body size and small bones, such as a child, the elderly, or a woman, by forming a round edge at the edge of a cross-section perpendicular to the stem axis.

In order to achieve the above-mentioned purpose, the present invention is implemented by an embodiment having the following configuration.

According to one embodiment of the present invention, the present invention is characterized by including a body portion inserted into a humeral shaft, and a connecting portion forming a hole through which a suture passes on an outer side of the body portion instead of forming a hole through which a suture passes in the humeral shaft to connect a separated bone portion to the humeral shaft.

According to another embodiment of the present invention, the present invention is characterized in that the connecting portion includes a connecting insertion portion that inserts the front and rear sides of the body portion.

According to another embodiment of the present invention, the present invention is characterized in that the connecting insertion portion includes a front inclined surface, which is an inclined surface formed on a front surface of the body portion, and a rear inclined surface, which is an inclined surface formed on a rear surface of the body portion, such that the insertion depth increases from the inside to the outside of the stem.

According to another embodiment of the present invention, the present invention is characterized in that the connecting portion includes a suture connecting hole formed to penetrate from the front inclined surface to the rear inclined surface.

According to another embodiment of the present invention, the suture connecting hole is characterized in that the central axis of the suture connecting hole is parallel to the front-rear axis of the stem.

According to another embodiment of the present invention, the present invention is characterized in that the connecting insertion portion includes a front reinforcing surface formed to extend from an end of the front inclined surface so that the insertion depth becomes shallower as it goes from the inside to the outside of the stem, and a rear reinforcing surface formed to extend from an end of the rear inclined surface so that the insertion depth becomes shallower as it goes from the inside to the outside of the stem.

According to another embodiment of the present invention, the fracture humerus stem of the present invention is characterized in that it includes a pin portion formed protruding on the outside of the body portion in a shape that receives a suture for connecting the separated bone portion to the stem.

According to another embodiment of the present invention, the present invention is characterized in that the pin portion is formed so that the protruding direction faces the biceps groove.

According to another embodiment of the present invention, the present invention is characterized in that the pin portion includes a first pin portion positioned in the forward direction at a predetermined angle based on the inner and outer axes of the stem, and a second pin portion positioned in the rearward direction at a predetermined angle based on the inner and outer axes of the stem.

According to another embodiment of the present invention, the present invention is characterized in that the first pin portion and the second pin portion are symmetrical to each other with respect to the inner and outer axes of the stem.

According to another embodiment of the present invention, the present invention is characterized in that the fin portion includes a wing portion forming a body, and a suture penetration hole formed to penetrate one surface of the wing portion and the other surface.

According to another embodiment of the present invention, the fracture humerus stem of the present invention is characterized in that it includes a fastening portion formed on the inside of the body portion in a shape that receives a suture to connect the separated bone portion to the stem.

According to another embodiment of the present invention, the present invention is characterized in that the fastening member includes a fastening insertion member that inserts the front and rear sides of the body member.

According to another embodiment of the present invention, the present invention is characterized in that the fastening member includes a suture fastening hole penetrating from one surface of the fastening insertion member to the other surface.

According to another embodiment of the present invention, the present invention is characterized in that the body portion has a non-circular cross-section perpendicular to the stem axis.

According to another embodiment of the present invention, the present invention is characterized in that the body portion forms a round edge at a corner of a cross-section perpendicular to the stem axis.

The present invention can obtain the following effects by combining the configuration and use relationship described below with the previously described embodiment.

The present invention has the effect of enabling rapid and accurate shoulder joint replacement surgery by providing a fracture humerus stem applied to the shoulder of a fracture patient.

The present invention reduces the surgical risk for patients by shortening the surgical time since there is no need to form a hole for passing a suture through the humerus shaft.

The present invention enables the omission of a drilling process for inserting a suture into the humerus during an artificial shoulder joint replacement surgery for a fracture patient, thereby preventing unnecessary bone loss caused by damage such as bone around the hole being crushed or broken together by the drilling impact.

The present invention has the effect of enabling patients with low bone density or low bone strength, such as the elderly, to easily undergo artificial shoulder joint replacement surgery even if they have suffered a shoulder fracture, since there is no need to directly drill a suture hole in the patient's humerus.

The present invention creates a hole by inserting the front and rear sides of the body into the outside of the body, and then penetrating the other side from one side, thereby making the thickness of the connecting portion through which the suture needle will pass relatively thin, thereby producing the effect of allowing a suture needle of a curved shape to easily pass through the connecting portion.

The present invention has the effect of configuring a connecting insertion portion including a front inclined surface and a rear inclined surface so that the insertion depth increases from the inside to the outside of the stem, thereby facilitating the passage of a suture needle, thereby shortening the surgical time.

The present invention prevents the problem of the strength of the stem being greatly reduced due to the formation of a recessed portion by forming a suture connection hole that penetrates the anterior and posterior inclined surfaces in a parallel direction of the anterior and posterior axial direction of the stem, while shortening the length of the suture connection hole through which the suture needle passes, thereby enabling the surgeon to easily insert and remove the suture needle into and out of the suture connection hole during the procedure.

The present invention provides an effect of reinforcing the reduced strength of a stem by forming a front-rear side reinforcement surface that is formed to extend from an end of a front-rear side slope so that the depth of penetration becomes shallower, thereby forming a front-rear side slope.

The present invention has the effect of forming a pin portion protruding on the outside of the body portion so that a separated bone portion can be easily connected to the stem through a suture, and while preventing rotation of the stem, the direction in which the pin portion protrudes is in the direction in which the biceps groove is located, thereby forming a reference that can confirm the exact insertion position during the procedure.

The present invention has the effect of enabling a retroversion to be referred to during the stem insertion process by configuring a pin portion facing the biceps groove direction.

The present invention provides a first pin portion positioned anteriorly at a predetermined angle relative to the medial-lateral axis of the stem, and a second pin portion positioned posteriorly at a predetermined angle relative to the medial-lateral axis of the stem, so that when the same stem is implanted into the humerus of the right arm, one of the pin portions points to the biceps groove of the right humerus, and when the same stem is implanted into the humerus of the left arm, the other of the pin portions points to the biceps groove of the left humerus.

The present invention has the effect of facilitating inventory management and preventing unnecessary waste of costs by configuring the first pin portion and the second pin portion to be symmetrical to each other with respect to the inner and outer axes of the stem, thereby enabling the same stem to be used on both the right humerus and the left humerus.

The present invention has the effect of preventing rotation of the stem by the pin by forming a suture penetration hole on the wing portion of the pin portion, and also of allowing the separated bones to be gathered together around the stem inserted into the humerus shaft, thereby restoring the original anatomical shape of the humerus.

The present invention provides the effect of enabling a separated bone portion to be easily joined to the stem using a suture by forming a fastening portion on the inside of the body portion of the stem.

The present invention provides a suture tying hole that penetrates from one side of the tying insertion portion into the front and rear sides of the body portion, thereby shortening the length of the region through which a curved suture needle will pass, thereby making it easy to pass the suture needle through the suture tying hole during surgery, thereby promoting convenience of the procedure and shortening the surgery time.

The present invention has the effect of solving the problem of making it difficult to insert the stem into the bone when the stem axis is bent by forming the stem axis straight.

The present invention achieves the effect of enhancing the workability of the stem while also exhibiting an anti-rotation effect by making the cross-sectional shape of the body portion perpendicular to the straight stem axis non-circular.

The present invention has the effect of preventing situations in which the bone is broken by a sharp stem edge when impacting the stem into the intramedullary canal of the humerus of a patient with a small body size and small bones, such as a child, the elderly, or a woman, by forming a round edge in the cross-section perpendicular to the stem axis.

Figure 1 is a drawing showing the anatomical shape of a typical humerus.
Figure 2 is a drawing illustrating a surgical procedure using a conventional humeral stem for fractures.
FIG. 3 is a perspective view showing a fracture humerus stem according to one embodiment of the present invention at one point in time.
Figure 4 is a perspective view showing the humeral stem for fracture at different points.
Figure 5 is a drawing showing the outer side of a humeral stem for fracture.
Figure 6 is a drawing showing the inner side of a humeral stem for fracture.
Figure 7 is a drawing showing the anterior side of the humeral stem for fracture.
Figure 8 is a cross-sectional view taken along line AA' of Figure 7.
Fig. 9 is a cross-sectional view taken along line BB' of Fig. 7.
Fig. 10 is a cross-sectional view taken along line CC' of Fig. 7.
Figure 11 is a drawing showing the upper side of a humeral stem for fracture.
Fig. 12 is a cross-sectional view taken along line DD' of Fig. 7.
Figure 13 is a drawing showing the lower side of the humeral stem for fracture.
Fig. 14 is a cross-sectional view taken along line EE' of Fig. 7.
Figure 15 is a diagram showing the state of use of a fracture humerus stem according to one embodiment of the present invention.

Hereinafter, preferred embodiments of the humerus stem for fracture according to the present invention will be described in detail with reference to the attached drawings. In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Unless otherwise defined, all terms in this specification have the same general meaning as that understood by a person skilled in the art to which the present invention pertains, and if there is a conflict with the meaning of a term used in this specification, the definition used in this specification shall apply. This specification and drawings were written assuming that the humerus stem (1) for fracture of the present invention is applied to the right shoulder.

The fracture humerus stem (1) of the present invention is one of the prosthetic devices used when performing artificial shoulder joint replacement surgery on a patient who has suffered a shoulder fracture. It refers to an implant that restores the original anatomical shape of the proximal humerus by inserting a certain portion of the stem (1) into the humerus shaft, and then using a suture to connect the separated bone to the portion of the stem (1) exposed on the outside of the humerus shaft.

According to the above-mentioned humerus stem (1) for fracture, since there is no need to form a hole for passing a suture through the patient's humerus shaft, the surgical time is shortened, thereby lowering the surgical risk of the patient, and unnecessary bone loss problems due to damage such as the bone around the hole being crushed or broken together by drilling impact during the process of performing artificial shoulder joint replacement surgery on a fracture patient can be prevented.

FIG. 3 is a perspective view showing a fracture humerus stem (1) according to one embodiment of the present invention at one point in time, and FIG. 4 is a perspective view showing the fracture humerus stem (1) at another point in time. Referring to FIGS. 3 and 4, the fracture humerus stem (1) includes a body portion (10), a connecting portion (30), a pin portion (50), and a fastening portion (70).

The above body part (10) is configured to be inserted into the humerus shaft, and preferably, a part of the body part (10) is positioned inside the intramedullary canal of the humerus shaft, and the remaining part is positioned outside the humerus shaft and can be connected to the separated bone and suture. The body part (10) has an overall long shape in the superior and inferior directions, but as shown in FIGS. 5 and 6, can be configured to have a tapered shape in which the cross-sectional width becomes smaller from the superior to the inferior side. This tapered shape facilitates insertion of the stem (1) into the intramedullary canal of the humerus, and ensures stronger fixing force after insertion.

FIG. 7 is a drawing showing the front side of a humeral stem (1) for fracture. Referring to FIG. 7, the body (10) can be configured to have a shape in which a certain portion of the proximal end close to the torso extends medially. When the central axis of the stem extending in the superior and inferior directions from the body (10) is referred to as the stem axis ( _AS ), and the central axis of the stem extending in the medial direction from the proximal end of the body ( ₁₀ ) is referred to as the metaphyseal axis (AM), the stem angle (Stem Angle) formed by the stem axis ( _AS ) and the metaphyseal axis ( _AM ) can be approximately 135 degrees to suit the anatomical shape.

If the above stem axis (A _S ) is configured as a curve rather than a straight line, it is inevitable that the surgeon will have difficulty inserting the stem into the bone while striking it with an impacting surgical instrument, and as a result, the positioning may become inaccurate. Therefore, it is preferable that the stem axis (A _S ) be configured as a straight line.

FIG. 8 is a cross-sectional view taken along line AA' of FIG. 7. Referring to FIG. 8, it may be preferable for the body part (10) to be configured in a non-circular shape in a cross-section perpendicular to the stem axis (A _S ). If the cross-section perpendicular to the stem axis (A _S ) is configured in a circular shape, the body part (10) can easily rotate by an external force, so by configuring it in a non-circular shape, the workability of the stem (1) is increased, while the effect of preventing rotation is realized.

In this process, if the edges are not processed and sharp square faces are formed, problems such as the bones being broken or the surrounding tissues being damaged by the sharp edges may occur, so it is more preferable that the edges of the cross-section perpendicular to the stem axis (A _S ) be configured to form round edges.

The above body part (10) includes a proximal body part (11) and a distal body part (13).

The above proximal body portion (11) is a configuration that forms the proximal portion of the body portion (10), and refers to a portion that is positioned close to the patient's torso when the body portion (10) is transplanted into the patient's body. As described above, a portion extending in the direction of the metaphyseal axis ( _AM ) may be formed in the proximal body portion (11). When the stem (1) is transplanted into the patient's bone, a groove may be formed on the upper surface of the proximal body portion (11) so that a surgical instrument inserted to a predetermined depth can be gripped so that stable impacting is possible. A pin portion (50), which will be described later, may be formed on the proximal body portion (11), and by forming the pin portion (50) on the proximal body portion (11) that is inserted shallower into the bone than the distal body portion (13), which is inserted deeply into the bone, more reliable prevention of stem rotation can be achieved.

A porous layer having a number of pores is formed on the surface of the proximal body part (11), so that when the proximal body part (11) is implanted into a bone and comes into contact with the bone, bone growth through the pores can be promoted. Preferably, the porous layer can be formed through TPS coating. The proximal body part (11) includes a connecting portion (111).

The above-mentioned connecting portion (111) is formed at the proximal end of the body portion (10), and if the proximal end refers to a certain area located close to the torso, the proximal end refers to the very end of the proximal end located closest to the torso. The connecting portion (111) is formed at this portion so that when the stem (1) is used as a total-type implant, the humerus head is connected to the connecting portion (111), and when the stem (1) is used as a reverse-type implant, the humerus tray is connected to the connecting portion (111).

The above-mentioned connecting portion (11) may be configured to have a non-circular cross-section perpendicular to the metaphyseal axis (A _M ), and the lower edge of the cross-section perpendicular to the metaphyseal axis (A _M ) may be configured to form a round edge. This is to form a non-circular cross-section so as to have greater resistance to rotation, while at the same time preventing the formation of sharp edges, so as to prevent situations such as bone breakage due to sharp stem edges when impacting the stem (1) into the intramedullary canal of the humerus of patients with small stature and small bones, such as children, the elderly, and women.

The above distal body portion (13) is configured to form the distal portion of the body portion (10), and may be formed in a tapered shape in which the width of the cross-section becomes narrower as it goes in the inferior direction. Since the distal body portion (13) is a portion that penetrates between bones before the proximal body portion (11), it is preferable that the cross-section be configured to be smaller than that of the proximal body portion (11), and a step may be formed at the boundary between the distal body portion (13) and the proximal body portion (11) by the proximal body portion (11) on which the porous coating layer is formed.

The cross-section of the distal body part (13) may be configured as non-circular, thereby preventing rotation, and the cross-section of the distal body part (13) may also have a round edge at its corner, thereby preventing problems such as bone damage caused by sharp edges in advance. The surface treatment method of the distal body part (13) is not limited to a specific method, but may preferably be performed by a grit blasting method. The distal body part (13) may have an anti-rotation groove (131) formed as a groove that is recessed to a predetermined depth along the longitudinal direction of the distal body part (13). A plurality of such anti-rotation grooves (131) are configured around the distal body part (13), thereby preventing unwanted rotation of the distal body part (13) embedded in the marrow cavity.

The above connecting portion (30) refers to a configuration in which, instead of forming a hole through which a suture passes in the humerus shaft in order to connect the separated bone portion to the humerus shaft, a hole through which a suture passes is formed on the outside of the body portion (10). Since there is no need to directly drill a suture hole in the patient's humerus, even patients with low bone density or low bone strength, such as the elderly, can easily undergo artificial shoulder joint replacement surgery even if they suffer a shoulder fracture.

Referring to Fig. 7, the above-mentioned connecting portion (30) includes a connecting insertion portion (31) and a suture connecting hole (33).

The above-described connecting insertion part (31) is configured to insert the front and rear sides of the body part (10), and preferably, as illustrated in FIG. 5, can be configured by inserting the front side of the proximal body part (11) in the rearward direction and inserting the rear side of the proximal body part (11) in the frontward direction. The present invention configures the connecting insertion part (31) so that the thickness of the connecting part through which the suture needle will pass is relatively thin, thereby allowing the suture needle, which has a curved shape, to easily pass through the connecting part. A suture connection hole (33), which will be described later, is formed on the connecting insertion part (31). Although an embodiment in which the insertion depth of the connecting insertion part (31) is constant is not excluded from the present invention, it is preferable to make the inserted depth different so as to facilitate the connection of the suture needle while preventing the strength from being reduced.

FIG. 9 is a cross-sectional view taken along line B-B' of FIG. 7. Referring to FIG. 9, the connecting insert (31) includes a front inclined surface (311), a rear inclined surface (313), a front reinforcing surface (315), and a rear reinforcing surface (317).

The above-described front inclined surface (311) refers to an inclined surface formed on the front surface of the body portion (10) so that the depth of recessing increases from the inner side to the outer side of the stem (1). As illustrated in FIG. 9, by configuring the front inclined surface (311), the thickness of the connecting portion (30) through which the suture needle must pass during surgery can be gradually reduced. As illustrated in FIG. 9, the front inclined surface (311) is configured in an approximately straight shape, but the front inclined surface (311) is not limited to such a straight shape and may also be configured in a curved shape.

The rear inclined surface (313) above refers to an inclined surface formed on the rear surface of the body portion (10) such that the depth of recessing increases from the inner side to the outer side of the stem (1). Preferably, the inclined angle of the rear inclined surface (313) may be configured to be the same as the inclined angle of the front inclined surface (311). In addition, the rear inclined surface (313), like the front inclined surface (311), may be configured in an approximately straight shape, but may also be configured in a curved shape. More preferably, the rear inclined surface (313) may be symmetrical with respect to the inner and outer axes of the front inclined surface (311). By configuring the connecting insertion portion (31) including the front inclined surface (311) and the rear inclined surface (313) so that the insertion depth increases from the inside to the outside of the stem (1), the passage of the suture needle is facilitated, and the surgical time can be significantly shortened.

The above-described front reinforcing surface (315) is formed so that the depth of the recess becomes shallower from the inner side to the outer side of the stem (1) from the end of the front inclined surface (311). As illustrated in FIG. 9, when the front inclined surface (311) is formed to the outer end of the connecting portion (30), the thickness of the connecting portion (30) becomes significantly smaller at the outer end. In this case, there is a concern that the outer side of the connecting portion (30) may be easily damaged by an external force, and the connecting portion (30) may not be sufficient to withstand the load transmitted along the stem axis. In order to prevent such problems, the front reinforcing surface (315) is formed so that the thickness of the connecting portion (30) increases from the inner side to the outer side from a certain point, thereby reinforcing the strength of the stem (1). The above front reinforcement surface (315) may be configured in the form of a straight line or may be configured in the form of a curve as shown in Fig. 9.

The rear reinforcing surface (317) above refers to a configuration in which the depth of recess becomes shallower as it extends from the end of the rear inclined surface (313) toward the outside of the stem (1). The rear reinforcing surface (317) may be formed not only in a straight line shape like the front reinforcing surface (315) described above, but also in a curved shape, and preferably, may be formed in a shape symmetrical to the front reinforcing surface (315) based on the inner and outer axes of the stem.

The above suture connection hole (33) refers to a hole formed so as to penetrate the rear inclined surface (313) in the front inclined surface (311). Referring to FIG. 10, the central axis (331) of the suture connection hole (33) may be configured to be parallel to the anteroposterior axis (A _AP ) of the stem (1). By configuring the suture connection hole (33) to penetrate the front inclined surface (311) and the rear inclined surface (313) parallel to the anteroposterior axis direction of the stem (1), the problem of a significant decrease in the strength of the stem due to the formation of a recessed portion is prevented, while the length of the suture connection hole (33) through which the suture needle passes is shortened so that the surgeon can easily insert and remove the suture needle into the suture connection hole (33) during the procedure. More preferably, as shown in Fig. 10, the suture connection hole (33) is formed in front of the point where the front reinforcing surface (315) and the rear reinforcing surface (317) begin, thereby preventing the effect of strength reinforcement by the front reinforcing surface (315) and the rear reinforcing surface (317) from being reduced, and the suture connection hole (33) can be formed at the point where the thickness of the cross-sectional width of the connecting insert (31) is minimum.

The pin (50) is a configuration that is formed protrudingly on the outside of the body (10) in a shape that accommodates a suture in order to connect the separated bone portion to the stem (1). Preferably, the pin (50) may be formed so that the protruding direction faces the biceps groove. By configuring the pin (50) to be formed protrudingly on the outside of the body (10), the separated bone portion can be easily connected to the stem through a suture, and while preventing rotation of the stem (1), the protruding direction of the pin (50) can be in the direction where the biceps groove is located, thereby forming a reference that can confirm the exact insertion position during the procedure.

FIG. 11 is a drawing showing the upper side of a humerus stem (1) for fracture. Referring to FIG. 11, the pin portion (50) includes a first pin portion (50a) positioned in the anterior direction at a predetermined angle (θ) based on the medial-lateral axis (A _ML ) of the stem (1), and a second pin portion (50b) positioned in the posterior direction at a predetermined angle (θ) based on the medial-lateral axis (A _ML ) of the stem (1). More preferably, the first pin portion (50a) and the second pin portion (50b) may be symmetrical with respect to the medial-lateral axis (A _ML ) of the stem (1).

By configuring the first pin portion (50a) and the second pin portion (50b), when the same stem is transplanted into the humerus of the right arm, one of the pin portions points to the biceps groove of the right humerus, and when the same stem is transplanted into the humerus of the left arm, the other of the pin portions points to the biceps groove of the left humerus. Accordingly, one stem (1) can be used for both the right humerus and the left humerus, facilitating inventory management, etc., and preventing unnecessary waste of costs.

Referring to Fig. 12, the pin portion (50) includes a wing portion (51) and a suture penetration hole (53).

The wing portion (51) is configured to form the body of the pin portion (50), and its shape is not limited to a specific shape. However, in order to facilitate insertion into the bone, easily point to the biceps groove, and shorten the passage length of the suture needle, it may preferably have a plate-like shape with a width smaller than its length, as shown in FIG. 5. More preferably, the lower end of the wing portion (51) may be configured to have a tapered shape with a width that becomes narrower toward the lower end, so as to facilitate penetration into the bone marrow cavity. As described above, the pin portion (50) may be composed of a first pin portion (50a) and a second pin portion (50b), and the wing portion (51) of the first pin portion (50a) may be deflected forward at a predetermined angle (θ) based on the inner and outer axes (A _ML ) as illustrated in FIG. 12, and the wing portion (51) of the second pin portion (50b) may also be deflected backward at the same angle (θ), so that the wing portions of the first pin portion (50a) and the second pin portion (50b) may be configured to be symmetrical based on the inner and outer axes (A _ML ).

The above suture penetration hole (53) refers to a hole formed so as to penetrate one surface of the wing portion (51) through the other surface. By forming the suture penetration hole (53) on the wing portion (51) of the pin portion (50), rotation of the stem (1) by the pin portion (50) is prevented, and by passing the suture connected to the separated bone through the suture penetration hole (53), the separated bones can be gathered together centered on the stem (1) inserted into the humerus shaft, thereby restoring the original anatomical shape of the humerus. Preferably, the suture penetration hole (53) is formed in multiple numbers, and can be formed at regular intervals along the longitudinal direction of the wing portion (51).

The above-mentioned fastening member (70) refers to a configuration formed on the inside of the body part (10) in a shape that accommodates a suture in order to connect the separated bone part to the stem (1). The present invention enables the separated bone part to be easily connected to the stem (1) using a suture through the above-mentioned fastening member (70).

Fig. 13 is a drawing showing the lower side of a humerus stem (1) for fracture, and Fig. 14 is a cross-sectional view taken along line E-E' of Fig. 7. Referring to Figs. 13 and 14, the fastening portion (70) includes a fastening insertion portion (71) and a suture fastening hole (73).

The above-described binding insertion portion (71) refers to a configuration in which the front and rear sides of the body portion (10) are inserted. When a hole for inserting a suture is to be formed on the inside of the body portion (10), the length of the hole penetrating from the front to the rear side of the body portion (10) may be excessively long, making it difficult to insert a hook-shaped suture needle into the hole. Therefore, by forming the above-described binding insertion portion (71) on a portion of the inside of the body portion (10) in which the hole is to be formed, the length of the area through which the curved suture needle will pass is shortened, thereby allowing the suture needle to be easily passed through the suture tying hole (73) described later during surgery.

The above suture tying hole (73) refers to a hole formed so as to penetrate one surface of the above tying insertion portion (71) to the other surface. As described above, the present invention forms the suture tying hole (73) on the above tying insertion portion (71) into which the body portion (10) is inserted to a certain depth, thereby enabling the surgeon to easily perform the suture surgery, and consequently, significantly shortens the surgery time and reduces the surgical risk of the patient. Referring to FIG. 14, the central axis (731) of the above suture tying hole (73) may be configured to be parallel to the anterior-posterior axis (A _AP ) of the stem (1).

FIG. 15 is a diagram showing a state of use of a fracture humerus stem (1) according to one embodiment of the present invention. Referring to FIG. 15, when a patient undergoing artificial shoulder joint surgery has suffered a shoulder fracture, the surgeon performs the surgery while connecting the bones separated from the humerus shaft (HS) with sutures. The surgeon inserts the fracture humerus stem (1) of the present invention into the intramedullary canal of the humerus shaft (HS) while connecting the separated bones (B1, B2) with sutures (SH).

In this process, a drilling process for inserting a suture (SL) into the proximal portion of the humerus shaft (HS) has been performed in the past, but since a suture connection hole (33) is formed on the stem (1) of the present invention, by passing the suture (SL) through the suture connection hole (33) and then inserting the stem (1) into the humerus shaft (HS), the suture (SL) is exposed outside the cut section of the humerus shaft (HS), and the exposed suture (SL) is lifted up to connect with the sutures (SH) connected to the separated bones (B1, B2), thereby facilitating suturing.

In addition, since the pin portion (50) is formed to protrude toward the biceps groove, it is possible to set the exact position of the stem (1) without having to do things like turning the patient's arm to check for retroversion. Since the pin portions (50) are formed on the front and back sides, it is possible to perform surgery on both the right and left arms with the same stem (1), and the effect of preventing rotation of the stem (1) by the multiple pin portions (50) can also be obtained.

The above detailed description is illustrative of the present invention. In addition, the above contents are described by showing a preferred embodiment of the present invention, and the present invention can be used in various other combinations, changes, and environments. That is, changes or modifications are possible within the scope of the inventive concept disclosed in this specification, the scope equivalent to the written disclosure, and/or the scope of technology or knowledge in the art. The written embodiment describes the best state for implementing the technical idea of the present invention, and various changes required for specific application fields and uses of the present invention are also possible. Therefore, the above detailed description of the invention is not intended to limit the present invention to the disclosed embodiments. In addition, the appended claims should be interpreted to include other embodiments.

1: Humeral stem for fracture
10: Body part
11: Guard body part
111: Joint
13: Distal body part
131: Anti-rotation groove
30: Connection
31: Connection port
311: Front slope
313: Rear slope
315: Front reinforcement surface
317: Rear reinforcement surface
33: Suture connection hole
331: Central axis
50: Pinbu
50a: 1st pin
50b: 2nd pin
51: Wings
53: Suture penetration hole
70: Binding
71: Binding insert
73: Suture fastening hole
731: Central axis
A _S : Stem axis
A _M : Simple axis
A _AP : Anteroposterior axis
A _ML : Medial and lateral axis

Claims (16)

A body portion inserted into the humerus shaft,
It includes a connecting portion in which a longitudinal suture is connected to connect a transverse suture that is formed on the lower side of the proximal body portion among the above body portions and connects the separated bone portions transversely, and a longitudinal suture for longitudinally connecting them.
A fracture humeral stem, characterized in that the connecting portion includes a suture connecting hole, which is a hole through which the longitudinal suture passes, instead of forming a hole in the humeral shaft for passing the longitudinal suture during the process of connecting the separated bone portion to the humeral shaft using a suture. In the first paragraph,
A fracture humerus stem, characterized in that the above connecting portion includes a connecting insert that inserts the front and rear sides of the body portion. In the second paragraph,
A fracture humerus stem, characterized in that the connecting insertion portion includes an anterior inclined surface, which is an inclined surface formed on the anterior side of the body portion, and a posterior inclined surface, which is an inclined surface formed on the posterior side of the body portion, such that the depth of insertion increases from the inner side to the outer side of the stem. In the third paragraph,
A fracture humerus stem, characterized in that the suture connection hole is formed to penetrate the posterior inclined surface from the anterior inclined surface. In paragraph 4,
A fracture humerus stem, characterized in that the central axis of the suture connection hole is parallel to the anteroposterior axis of the stem. In the third paragraph,
A fracture humeral stem, characterized in that the connecting insertion portion includes a front reinforcing surface that extends from an end of the front inclined surface so that the insertion depth becomes shallower as it goes from the inside to the outside of the stem, and a rear reinforcing surface that extends from an end of the rear inclined surface so that the insertion depth becomes shallower as it goes from the inside to the outside of the stem. In the first paragraph,
The above humerus stem for fracture is characterized in that it includes a pin portion formed protruding on the outside of the body portion in a shape that receives a suture to connect the separated bone portion to the stem. In Article 7,
A fracture humerus stem, characterized in that the pin portion is formed so that the protruding direction faces the biceps groove. In Article 8,
A humerus stem for fracture, characterized in that the pin portion includes a first pin portion positioned in the anterior direction at a certain angle based on the medial and lateral axes of the stem, and a second pin portion positioned in the posterior direction at a certain angle based on the medial and lateral axes of the stem. In Article 9,
A humerus stem for fracture, characterized in that the first pin portion and the second pin portion are symmetrical with respect to the inner and outer axes of the stem. In Article 7,
A fracture humerus stem, characterized in that the pin portion includes a wing portion forming a body and a suture penetration hole formed to penetrate from one surface of the wing portion to the other surface. In the first paragraph,
A fracture humerus stem, characterized in that it includes a fastening portion formed on the inside of the body portion in a shape that receives a suture to connect the separated bone portion to the stem. In Article 12,
A fracture humerus stem, characterized in that the above-mentioned fastening member includes a fastening insertion member that inserts the front and rear sides of the body member. In Article 13,
A fracture humerus stem, characterized in that the above-mentioned fastening member includes a suture fastening hole penetrating from one surface of the above-mentioned fastening insertion member to the other surface. In the first paragraph,
A humerus stem for fracture, characterized in that the above body part has a non-circular cross-section shape perpendicular to the stem axis. In Article 15,
A fracture humerus stem, characterized in that the body portion forms a round edge at a cross-section perpendicular to the stem axis.

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