A BLADE STRUCTURE, HIP SCREW, AND FEMUR FRACTURE TREATMENT DEVICE

Abstract

The present invention discloses a blade structure, a hip screw and a femur fracture treatment device. The blade structure's body has a centrally radially symmetrical cross section. The centrally radially symmetrical cross section has a plurality of centrally radially symmetrical sections, on each of the section at least a cutting slot and two blades formed at corresponding top ends of two sides of the cutting slot respectively are defined, and a projection of a top end of each blade is located on a bottom wall of an interior of the cutting slot.

Claims

1. A blade structure, comprising a body having a centrally radially symmetrical cross section, wherein the centrally radially symmetrical cross section includes a plurality of centrally radially symmetrical sections, on each of the symmetrical section at least a cutting slot and two blades formed at corresponding top ends of two sides of the cutting slot respectively are defined, and a projection of a top end of each blade is located on a bottom wall of an interior of the cutting slot.

2. The blade structure as recited in claim 1, wherein the cross section of the body is a circular cross section; a cross section of the cutting slot includes a pair of first circular arcs each of which runs from the blade to the bottom wall of the cutting slot and of each of which a circle center is located in a space defined together by the cutting slot and the pair of first circular arcs in the same cutting slot; and two first circular arcs of the pair of the first circular arcs are connected together through a second circular arc of which a circle center coincides with a circle center of the cross section of the body of the blade structure.

3. The blade structure as recited in claim 1, wherein the number of the cutting slots is three.

4. The blade structure as recited in claim 1, wherein the cutting slot is a straight cutting slot, and a lower portion of the cutting slot is connected smoothly with an outer surface of the blade structure.

5. The blade structure as recited in claim 1, wherein the cutting slot is a threaded cutting slot with a predefined lead angle.

6. A hip screw, comprising: a blade portion and a connecting portion, wherein the blade portion comprises a blade structure comprising a body having a centrally radially symmetrical cross section, wherein the centrally radially symmetrical cross section includes a plurality of centrally radially symmetrical sections, on each of the symmetrical sections at least a cutting slot and two blades formed at corresponding top ends of two sides of the cutting slot respectively are defined, and a projection of a top end of each blade is located on a bottom wall of an interior of the cutting slot.

7. The hip screw as recited in claim 6, wherein the hip screw is provided with the through hole running along its center line.

8. The hip screw as recited in claim 7, wherein a plurality of circular holes is defined in the blade of the blade structure.

9. The hip screw as recited in claim 8, wherein a plurality of circular holes is also defined in a lower portion of the cutting slot of the blade structure, and the circular holes communicate with the through hole.

10. A femur fracture treatment device, comprising: a hip screw comprising: a blade portion and a connecting portion, wherein the blade portion comprises a blade structure comprising a body having a centrally radially symmetrical cross section, the centrally radially symmetrical cross section includes a plurality of centrally radially symmetrical sections, on each of the symmetrical sections at least a cutting slot and two blades formed at corresponding top ends of two sides of the cutting slot respectively are defined, and a projection of a top end of each blade is located on a bottom wall of an interior of the cutting slot.

11. The femur fracture treatment device as recited in claim 10, wherein the connecting portion is provided with a positioning groove in a surface of the hip screw, and a length direction of the positioning groove is consistent with that of the hip screw.

12. The femur fracture treatment device as recited in claim 11, wherein a plane parallel to the positioning groove has a predefined inclination angle relative to an end surface of a top end of the connecting portion.

13. The femur fracture treatment device as recited in claim 11, wherein a bottom surface of the positioning slot is arc-shaped.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] FIG. 1 illustrates a cross sectional view of a blade structure according to one embodiment of the invention;

[0020] FIG. 2 illustrates a front view of a hip screw according to one embodiment of the invention;

[0021] FIG. 3 illustrates a cross sectional view of a hip screw according to one embodiment of the invention; and

[0022] FIG. 4 illustrates a front view of a hip screw according to another embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0023] Various exemplary embodiments of the present invention are further described below in conjunction with the accompanied drawings, wherein the same reference numerals refer to the same parts throughout the drawings. Further, if a detailed description of a known technique is unnecessary for showing the features of the present invention, it will be omitted.

[0024] The present invention provides a blade structure, and as shown in FIG. 1, the blade structure 10 has a body of which a cross section is centrally radially symmetrical. The cross section may have a shape of circular, square, equilateral triangle, oval, rectangle and so on. The blade structure 10 has a plurality of centrally radially symmetrical sections. Defined on each of the sections are at least a cutting slot 100 and two blades 200 formed at corresponding top ends of two sides of the cutting slot 100 respectively. That is to say, the blades 200 are located at two sides of the cutting slot 100 respectively, and formed at corresponding top ends of two sides of the cutting slot 100 respectively. The projection of a top end of each blade 200 should be located on a bottom wall of the interior of cutting slot. By this way, an opening defined between the two blades is narrower than an interior defined by the two blades and bottom wall. The blade structure 10 of the present invention is of an embedded cutter structure. The cutter structure is applied to the hip screw, and is able to meet the working requirement of the hip screw. In an ideal state the hip screw should be embedded in an object and kept stationary, at least in the radial direction of the blade structure 10. That is to say, the hip screw will not be rotated around an axis when external force applies thereto, and the blade structure has a small opening and a relatively large internal cavity, so that after the blade structure 10 is embedded in the object, the cutting slot 100 is filled with much material of the object, which can generate great resistance to the rotation of the cutter structure, and avoid the radial positional change easily.

[0025] There are many structures of the small opening and a relatively large internal cavity, and as a preferred embodiment, the body of the blade structure 10 has a circular cross section. The cross section contour of the cutting slot 100 is not a straight contour, meaning that the cross section contour is not completely constructed of straight edges which are angled relative to each other. In detail, a cross section of the blade structure 10 includes a pair of first circular arcs 110 each of which runs from the blade 200 to the bottom wall of the cutting slot and of each of which a circle center is located in a space defined together by the cutting slot 100, and the pair of first circular arcs 110 in the same cutting slot 100; and a second circular arc 120 of which a circle center coincides with a circle center of the cross section of a body of the blade structure 10 and which is connected to the pair of the first circular arcs 110. The cross section of the cutting slot 100 is constructed of said second circular arc 120 and the pair of the first circular arcs 110 that are connected with the second circular arc 120; that is to say, the cross section of the cutting slot 100 is constructed of the pair of the first circular arcs 110 and said second circular arc 120. The second circular arc 120 is connected to the two first circular arcs 110. The circle centers of the two first circular arcs 110 are at the same side of a line, and the circle center of the second circle arc 120 is at the other side of the line. The circle center of the second circle arc 120 coincides with the circle center of the cross section of the blade structure 10, and the radii of the two arcs are different from each other. Because the blade structure 10 has a circular contour, the first circular arcs 110 and the circular contour of the blade structure 10 can intersect directly, and an arc tip orientated towards the interior of the circular contour of the blade structure 10 is formed at the intersecting portion (alternatively intersection is unnecessary here and in this case, an arc tip may be constructed by defining an opening inside of the first circular arcs). As a result, the blade structure 10 forms a structure with a small opening and a relatively large internal cavity. The cross sectional arrangement of this kind can provide as many as possible hollow areas inside the cross section. The larger the hollow areas in the cross section are, the less interference resulted from the hip screw will be imposed on the intraosseous substance.

[0026] The hip screw 20 of the present invention, as shown in FIGS. 1 and 2, includes a blade portion 21 and a connecting portion 22, wherein the blade portion 21 adopts the blade structure 10 as mentioned above. The hip screw 20 is used for being inserted into the human bones, with a result that the hip screw 20 has the characteristic of stabilization and with less or even no rotation after being embedded into the bone, which makes sure that the healing of bone is less influenced by external factors. As a preferred embodiment, the number of the cutting slots 100 distributed on the blade structure 10 is three, and in detail, there could be three cutting slots 100 of identical shape and distributed uniformly along the center of the blade structure 10. The design as mentioned above can make the area of the internal cavity of each cutting slot 100 as large as possible, and can also make the amount of material of the blade structure 10 as less as possible.

[0027] As a preferred embodiment, the cutting slot 100 is a straight cutting slot, and a lower portion of the cutting slot 100 is connected smoothly with an outer surface of the blade structure 10. The blade structure 10 with the straight cutting slot 100 can be easily embedded into an object along a straight line direction because of special shape of the cross section. As a result, as shown in FIG. 2, the hip screw 20 using the blade structure 10 of the straight cutting slot 100 has characteristics of easy implantation into bones and post-implantation stability.

[0028] As another preferred embodiment, the cutting slot 100 is threaded cutting slot 100 with a predefined lead angle (not shown). If a threaded cutting slot 100 is adopted, the stability will be high when the cutting slot 100 is embedded into an object, and the cutting slot will not be easily loosened along a radial direction or an axial direction. Further, a threaded structure facilitates axial movement. As a result, a cutter with a threaded cutting slot can avoid using additional tool, and can be embedded into an object by rotation of itself.

[0029] In solution of the hip screw 20 of the present invention, preferably, as shown in FIGS. 1 and 3, a through hole 24 is defined in a center of the hip screw 20, that is to say, the hip screw 20 is provided with the through hole 24 running along its center line. A guide pin can pass through a central portion of the hip screw 20. The guide pin plays a guiding role in the process of implantation of the hip screw 20, and brings convenience for operation.

[0030] As a preferred embodiment, as shown in FIGS. 1 and 3, a plurality of circular holes 23 is defined in the blade 200 of the hip screw 20. On one hand, the circular holes 23 can reduce the weight of the hip screw 20 making it lighter while keeping the structure stable, and on the other hand, the intra-bone material separated by the blade 200 can be exchanged through the circular holes 23, thereby reducing disturbance of the device to substances in the bone.

[0031] As a further preferred embodiment, as shown in FIGS. 1 and 4, a plurality of circular holes 23 is also defined in a lower portion of the cutting slot 100 of the blade structure 10 of the hip screw 20. The circular holes 23 communicate with the through hole 24 in the center of the hip screw 20. The circular holes 23 serve as cement holes, which are mainly used in case of osteoporosis in the elderly, and through which the bone cement is injected into the femur to enhance the stability of the hip screw 20.

[0032] Accordingly, a femur treatment device of the present invention includes an intramedullary nail and a hip screw, and cooperative structure of the two components is well known by person of ordinary skill in the art. The hip screw of the femur treatment device of the present invention is the hip screw 20 as mentioned above. And in an embodiment, a connecting portion 22 of the hip screw 20 is provided with a positioning groove 25, which is disposed in a surface of the hip screw 20, and a length direction of the positioning groove 25 is consistent with that of the hip screw 20. Generally, the hip screw 20 passes through a lateral hole in the intramedullary nail and cooperates with the same to form main structure of the femur treatment device. Therefore, the intramedullary nail is provided with a plug matched with the positioning groove 25. The plug is pressed against the positioning groove 25 to achieve an effect of fixing the position of the hip screw 20 relative to the intramedullary nail. Description of specific structure of the intramedullary nail is omitted herefrom.

[0033] As the positioning groove 25 is a groove defined in a curved surface, there must be a plane defined together by a length direction and width direction of the positioning groove 25 and parallel to the positioning groove 25. As a preferred embodiment, the plane has a predefined inclination angle θ with an end surface 26 of a top end of the connecting portion 22.

[0034] That is to say, when the hip screw 20 is in the assembled position, the end surface 26 can be nearly parallel or completely parallel to the axis of the intramedullary nail. Such an arrangement makes the femur fracture treatment device more closely match the natural bone structure of the human body, and also makes the femur fracture treatment device more compact. In addition, the bottom surface of the positioning groove 25 may be provided in various shapes, for example, it may has a rectangular shape, a triangular shape or a circular arc shape, and preferably has a circular arc shape, as the circular arc-shaped bottom surface makes the contact area between a plug body provided on the intramedullary nail and the positioning groove 25 larger, so that the connection structure of the two is more stable. More preferably, suitably rounded corners are provided on each edge of the positioning slot 25 to make it easier to engage a mating structure such as a plug.

[0035] While some exemplary embodiment of the present invention have been shown in the foregoing, it will be understood by those skilled in the art that variations of the exemplary embodiment may be made without departing from the spirit and scope of the invention, and the scope of the invention is defined by the claims and their equivalents.