CN211271418U - Bionic artificial interphalangeal joint - Google Patents

Abstract

The utility model discloses a bionic artificial interphalangeal joint, which comprises three groups of near-end prostheses and far-end prostheses matched with the near-end prostheses; the method is characterized in that three joints between a metacarpal bone and a distal phalanx are respectively corresponding, and corresponding artificial interphalangeal joints can be selected for replacement according to the specific positions of joints to be replaced, wherein the bionic artificial interphalangeal joint which can be arranged between the metacarpal bone and a proximal phalanx has a plurality of degrees of freedom, the proximal phalanx can be allowed to bend in any direction as a real finger, and the bending angle of the proximal phalanx when bending towards the inner side of the finger can be about 90 degrees; the bionic artificial interphalangeal joint capable of being installed between the middle phalanx and the proximal phalanx enables the bending angle of the middle phalanx when the middle phalanx is bent towards the inner side of a finger to be slightly larger than 90 degrees, the performance of the human finger is completely simulated in the bending process of each finger, the connection strength of each joint can be guaranteed, and dislocation is prevented.

Description

Bionic artificial interphalangeal joint

Technical Field

The utility model relates to a medical artificial joint prosthesis, in particular to a bionic artificial interphalangeal joint.

Background

The human hand bones comprise carpal bones, metacarpal bones and phalanges, wherein the phalanges are 14 in total, the thumb is two joints, 2-5 fingers are three joints, and proximal phalanges, middle phalanges and distal phalanges are sequentially arranged from the proximal side to the distal side. The proximal end of the phalanx is the bottom, the middle part is the body, and the distal end is the pulley. The distal end of the distal phalanx is provided with no pulley, the palm surface of the distal phalanx is provided with rough bulges called as distal phalanx tuberosity, and the proximal phalanx is connected with the metacarpal bone;

the joint function disorder on the fingers of the patient can be caused by hereditary degenerative diseases, arthritis and other diseases, and the local pain and even the joint function loss can be further caused; in addition, joint dislocation or joint fracture and other injuries can also cause functional disorder of joints on fingers, and with the further development of injuries, after the joints lose functions, a more common treatment method is replacement surgery of interphalangeal joints, and the joint losing functions in a human body is replaced by the bionic artificial interphalangeal joint, so that the fingers recover basic functions.

The application of the finger-to-finger joint replacement operation in clinic has been already in history for decades, and the artificial finger-to-finger joint used for replacing the human finger-to-finger joint in the process is updated for several times, but the artificial finger-to-finger joint in the prior art still has many defects, and needs to be improved. For example, the conventional artificial interphalangeal joint tends to involve musculotendinous tissue into a rotating structure, causing pain and discomfort; the degree of freedom of the connecting part is insufficient, so that the fingers after the operation can not make common actions, and the bionic performance is poor; furthermore, due to the fact that the degree of freedom is not enough, muscle tissues of the human body still apply corresponding acting force to the artificial joint, and therefore the risk of fracture of the artificial joint is increased; the requirement on ligament and muscle tissues is high, many old patients cannot replace the artificial joint prosthesis by operation, and a large dislocation risk exists;

in addition, the 2-5 fingers of the human body have 3 joints, the thumb has two joints, the freedom degree, the strength and the like of each joint are different, and no specific bionic artificial prosthesis aiming at different joints exists at present;

for the above reasons, the present inventors have made intensive studies on the existing artificial interphalangeal joint in order to design a new bionic artificial interphalangeal joint capable of solving the above problems.

SUMMERY OF THE UTILITY MODEL

In order to overcome the problems, the inventor of the invention carries out intensive research and designs a bionic artificial interphalangeal joint which comprises three groups of near-end prostheses and far-end prostheses matched with the near-end prostheses; the method is characterized in that three joints between a metacarpal bone and a distal phalanx are respectively corresponding, and corresponding artificial interphalangeal joints can be selected for replacement according to the specific positions of joints to be replaced, wherein the bionic artificial interphalangeal joint which can be arranged between the metacarpal bone and a proximal phalanx has a plurality of degrees of freedom, the proximal phalanx can be allowed to bend in any direction as a real finger, and the bending angle of the proximal phalanx when bending towards the inner side of the finger can be about 90 degrees; the bionic artificial interphalangeal joint which can be arranged between the middle phalanx and the proximal phalanx ensures that the bending angle of the middle phalanx when being bent towards the inner side of a finger can be slightly larger than 90 degrees, the performance of the human finger can be completely simulated in the bending process of each finger, the connection strength of each joint can be ensured, dislocation is prevented, and the utility model is completed;

particularly, the utility model aims to provide a bionic artificial interphalangeal joint, which comprises a near-end prosthesis 1 and a far-end prosthesis 2 matched with the near-end prosthesis 1;

wherein the near end of the near end prosthesis 1 is fixed on the metacarpal bone or the phalanx, the far end of the near end prosthesis 1 is provided with a receiving groove 3,

the far end of the far-end prosthesis 2 is fixed on the phalanx, a revolving body tip 4 is arranged on the near end of the far-end prosthesis 2,

a bowl-shaped gasket 5 is arranged between the storage groove 3 and the rotation body end 4, the rotation body end 4 is rotatably fixed in the bowl-shaped gasket 5, and the bowl-shaped gasket 5 is fixed in the storage groove 3.

Wherein the bionic artificial interphalangeal joint includes:

a first proximal prosthesis 11 fixed proximally to the middle phalanx and a first distal prosthesis 21 fixed distally to the distal phalanx,

a first housing groove 31 is opened on the distal end of the first proximal prosthesis 11,

on the proximal end of said first distal prosthesis 21 a first swivel end 41 is provided,

a first bowl-shaped spacer 51 is provided between the first housing groove 31 and the first swivel body end 41, the first swivel body end 41 being rotatably fixed in the first bowl-shaped spacer 51, the first bowl-shaped spacer 51 being rotatably fixed in the first housing groove 31;

wherein, the first revolving body tip 41 and the first bowl-shaped gasket 51 can only rotate reciprocally in the same direction,

when the first distal prosthesis 21 is bent inward with respect to the first proximal prosthesis 11 by an external force, the first rotating body end 41 and the first bowl-shaped spacer 51 are first rotated relatively, and after the first distal prosthesis 21 is rotated to an extreme position, the first bowl-shaped spacer 51 and the first receiving groove 31 can be rotated relatively when the first distal prosthesis 21 is subjected to a larger force.

Wherein, a first bending limit baffle sheet 61 is arranged on the first far-end prosthesis 21,

when the first distal prosthesis 21 is bent by a predetermined angle relative to the first proximal prosthesis 11 under the action of an external force, the first bending limiting baffle 61 abuts against the first proximal prosthesis 11, so as to limit the first distal prosthesis 21 from being bent continuously.

Wherein, the bionic artificial interphalangeal joint further comprises:

a second proximal prosthesis 12 proximally fixed to the proximal phalanx and a second distal prosthesis 22 distally fixed to the middle phalanx,

a second receiving groove 32 is opened on the distal end of the second proximal prosthesis 12,

a second solid of revolution tip 42 is provided on the proximal end of the second distal prosthesis 22,

a second bowl-shaped spacer 52 is disposed between the second receiving groove 32 and the second rotator tip 42, the second rotator tip 42 is rotatably fixed in the second bowl-shaped spacer 52, and the second bowl-shaped spacer 52 is rotatably fixed in the second receiving groove 32;

wherein, the second revolving body head 42 and the second bowl-shaped gasket 52 can only rotate reciprocally in the same direction;

when the second distal prosthesis 22 is bent inward with respect to the second proximal prosthesis 12 under an external force, the second rotator tip 42 and the second bowl-shaped spacer 52 rotate relative to each other first, and after the second distal prosthesis 22 is rotated to the extreme position, the second bowl-shaped spacer 51 and the second receiving groove 32 can rotate relative to each other when the second distal prosthesis 22 is subjected to a larger force.

Wherein, a second bending limit baffle plate 62 is arranged on the second far-end prosthesis 22,

when the second distal prosthesis 22 is bent at a predetermined angle relative to the second proximal prosthesis 12 under the action of an external force, the second bending limiting baffle plate 62 abuts against the second proximal prosthesis 12, thereby limiting the second distal prosthesis 22 from further bending.

Wherein a second knee 72 is provided at the proximal end of the second distal prosthesis 22, and the second distal prosthesis 22 is connected to the second body of revolution end 42 through the second knee 72;

preferably, the second bending rod 72 is bent towards the inner side of the finger;

more preferably, the bending angle of the second bending rod 72 is 30-45 degrees.

Wherein, a first notch 81 is arranged on the wall of the second accommodating groove 32 in the direction close to the inner side of the finger,

a second notch 82 is arranged on the second bowl-shaped gasket 52 in the direction close to the inner side of the finger,

and when the second distal prosthesis 22 is bent, the second bent rod 72 can be embedded into the first notch 81 and the second notch 82, so that the bending angle of the second distal prosthesis 22 is more than 90 degrees.

Wherein, the bionic artificial interphalangeal joint further comprises:

a third proximal prosthesis 13 fixed proximally to the metacarpal bone and a third distal prosthesis 23 fixed distally to the proximal phalanx,

a third receiving groove 33 is opened on the distal end of the third proximal prosthesis 13,

a third body of revolution tip 43 is provided on the proximal end of the third distal prosthesis 23,

a third bowl-shaped spacer 53 is provided between the third housing groove 33 and the third rotor tip 43, the third rotor tip 43 is rotatably fixed to the third bowl-shaped spacer 53, and the third bowl-shaped spacer 53 is fixed to the third housing groove 33;

wherein the third rotator tip 43 is rotatable in any direction,

preferably, at the proximal end of said third distal prosthesis 23, a bent rod three 73 is provided, by means of which said third distal prosthesis 23 is connected to said third body of revolution head 43;

more preferably, the three bent rods 73 are bent toward the inner side of the finger;

the bending angle of the third bent rod 73 is 30-45 degrees.

Wherein, the wall of the third accommodating groove 33 is provided with a third notch 83 in the direction close to the inner side of the finger,

a fourth notch 84 is arranged on the third bowl-shaped gasket 53 in the direction close to the inner side of the finger,

when the third distal prosthesis 23 is bent inward, the bent rod three 73 can be inserted into the notch three 83 and the notch four 84, so that the angle of bending the third distal prosthesis 23 inward is more than 90 degrees.

Wherein a third bending limit stop sheet 63 is arranged on the third far-end prosthesis 23,

when the third distal prosthesis 23 is bent relative to the third proximal prosthesis 13 by a predetermined angle under the action of external force, the third bending limit stop piece 63 abuts against the third proximal prosthesis 13, so as to limit the third distal prosthesis 23 from being bent continuously.

The utility model discloses the beneficial effect who has includes:

(1) according to the bionic artificial interphalangeal joint provided by the utility model, the bionic artificial interphalangeal joint comprises a plurality of groups of joint structures, and corresponding artificial interphalangeal joints can be selected for replacement according to different joint positions, so that the adaptability of the bionic artificial interphalangeal joint is greatly improved;

(2) according to the utility model provides a be provided with bowl form gasket in the joint between bionical artifical finger, can enough weaken wearing and tearing speed, can also improve the flexibility and the adaptability of postoperative finger.

(3) The bowl-mounted gasket can reduce impact and avoid static electricity.

Drawings

Fig. 1 is a schematic view showing an overall structure of a bionic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 2 is a schematic view of a first distal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 3 is a schematic structural view of a first bowl-shaped spacer in a bionic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 4 is a schematic view of a first proximal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 5 is a partial enlarged view of a first proximal prosthesis at a junction with a first distal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 6 is a schematic diagram illustrating the construction of a second distal prosthesis in a biomimetic artificial interphalangeal joint in accordance with a preferred embodiment of the present invention;

fig. 7 is a schematic structural view illustrating a second bowl-shaped spacer in a bionic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 8 is a schematic structural view of a second proximal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 9 is a partial enlarged view of a joint between a second proximal prosthesis and a second distal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 10 is a partial enlarged view of the joint between the third proximal prosthesis and the third distal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 11 is a schematic view of a third distal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention;

FIG. 12 is a schematic view showing a third bowl-shaped spacer in a bionic artificial interphalangeal joint according to a preferred embodiment of the present invention;

fig. 13 is a schematic structural view illustrating a third proximal prosthesis in a biomimetic artificial interphalangeal joint according to a preferred embodiment of the present invention.

The reference numbers illustrate:

1-proximal prosthesis

11-first proximal prosthesis

12-second proximal prosthesis

13-third proximal prosthesis

2-distal prosthesis

21-first distal prosthesis

22-second distal prosthesis

23-third distal prosthesis

3-storage tank

31-first receiving groove

32-second receiving groove

33-third storage tank

4-revolved body end

41-first swivel end

42-second body of revolution end

43-third body of revolution end

5-bowl-shaped gasket

51-first bowl-shaped gasket

52-second bowl spacer

53-third bowl-shaped spacer

61-first bending limit baffle

62-second bending limit baffle

63-third bending limit baffle

72-bent rod II

73-bent rod III

81-groove one

82-groove two

83-groove III

84-four notches

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. The features and advantages of the present invention will become more apparent from the description.

The word "exemplary" is used exclusively herein to mean "serving as an example, embodiment, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments. While the various aspects of the embodiments are presented in drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

In this application, the far end refers to the end near the tip of a finger, and the near end refers to the end near the arm.

The proximal prosthesis and the distal prosthesis are a pair of prostheses which are matched with each other and are respectively fixed on the bones of two adjacent finger parts, and the contact part of the proximal prosthesis and the distal prosthesis is an interphalangeal joint.

According to the utility model, as shown in fig. 1, fig. 5, fig. 9 and fig. 10, the bionic artificial interphalangeal joint comprises a proximal prosthesis 1 and a distal prosthesis 2 matched with the proximal prosthesis 1; the contact part between the adjacent proximal prosthesis 1 and the distal prosthesis 2 is a joint;

wherein the near end of the near end prosthesis 1 is fixed on the metacarpal bone or the phalanx, the far end of the near end prosthesis 1 is provided with a receiving groove 3,

the far end of the far-end prosthesis 2 is fixed on the phalanx, a revolving body tip 4 is arranged on the near end of the far-end prosthesis 2,

preferably, the proximal prosthesis and the distal prosthesis are fixed to the metacarpal bone or the phalange in various ways, and in the present application, the insertion and fixation method is preferably selected, that is, the proximal prosthesis and the distal prosthesis are configured into a thin rod, the thin rod is inserted into the metacarpal bone or the phalange without phalange pulley, phalange bottom and other parts, and is fixed by spraying bone cement or biological material, and a structure such as a thread can be engraved on the thin rod to increase friction and improve stability; phalanges as referred to in this application include proximal, middle and distal phalanges.

A bowl-shaped gasket 5 is arranged between the storage groove 3 and the rotation body end 4, the rotation body end 4 is rotatably fixed in the bowl-shaped gasket 5, and the bowl-shaped gasket 5 is fixed in the storage groove 3. The bowl-shaped spacer 5 and the receiving groove 3 may be optionally provided to be relatively rotatable or non-rotatable.

The size and shape of the inner part of the accommodating groove 3 are basically consistent with the size and shape of the outer surface of the bowl-shaped gasket 5, and the size and shape of the inner part of the bowl-shaped gasket 5 are basically consistent with the size and shape of the outer surface of the rotary body end 4; preferably, the wall thickness is equal throughout the bowl-shaped gasket 5.

In a preferred embodiment, as shown in fig. 1, 2, 3, 4 and 5, the biomimetic artificial interphalangeal joint comprises:

a first proximal prosthesis 11 fixed proximally to the middle phalanx and a first distal prosthesis 21 fixed distally to the distal phalanx,

a first housing groove 31 is opened on the distal end of the first proximal prosthesis 11,

on the proximal end of said first distal prosthesis 21 a first swivel end 41 is provided,

a first bowl-shaped spacer 51 is provided between the first receiving groove 31 and the first swivel body end 41, the first swivel body end 41 being rotatably fixed in the first bowl-shaped spacer 51; the first bowl-shaped spacer 51 is rotatably fixed in the first receiving groove 31;

the first revolving body tip 41 and the first bowl-shaped spacer 51 can only rotate back and forth in the same direction, that is, can only rotate towards the palm or rotate in the opposite direction;

when the first distal prosthesis 21 or the distal phalanx is bent in the direction of the inner side of the finger/toward the palm of the hand with respect to the first proximal prosthesis 11 by an external force, the first rotating body end 41 and the first bowl-shaped spacer 51 are first rotated relatively, and after the first distal prosthesis 21 is rotated to the extreme position, the first bowl-shaped spacer 51 and the first receiving groove 31 can be rotated relatively when the first distal prosthesis 21 is subjected to a larger force. Preferably, when the rotating part rotates to the limit position, the rotating angle is 70-80 degrees.

The first bowl-shaped gasket 51 and the first revolving body end 41 are provided with a rotation limiting structure which can allow the first bowl-shaped gasket and the first revolving body end 41 to rotate relatively for a certain angle, such as about 10 degrees, and can be locked in a mechanical limiting mode after the maximum allowable angle is reached;

the tightness between the first rotating body end 41 and the first bowl-shaped spacer 51 is less than the tightness between the first bowl-shaped spacer 51 and the first receiving groove 31.

Preferably, said first rotor head 41 is similar to a drum as shown in FIG. 2; specifically, on the basis of a sphere, two ends of the sphere are symmetrically cut off to obtain two planes parallel to each other, so that the shape of the end 41 of the first rotating body of the present application can be obtained;

the inner dimension and shape of the first receiving groove 31 substantially correspond to the outer dimension and shape of the first bowl-shaped spacer 51, and the inner dimension and shape of the first bowl-shaped spacer 51 substantially correspond to the outer dimension and shape of the first rotating body end 41.

In a preferred embodiment, as shown in figures 1, 2 and 5, on said first distal prosthesis 21 a first fold limiting flap 61 is provided,

when the first distal prosthesis 21 is bent by a predetermined angle relative to the first proximal prosthesis 11 under the action of an external force, the first bending limiting baffle 61 abuts against the first proximal prosthesis 11, so as to limit the first distal prosthesis 21 from being bent continuously. Preferably, the predetermined angle is 80 to 90 degrees.

In a preferred embodiment, as shown in fig. 1, 6, 7, 8 and 9, the biomimetic artificial interphalangeal joint comprises:

a second proximal prosthesis 12 proximally fixed to the proximal phalanx and a second distal prosthesis 22 distally fixed to the middle phalanx,

a second receiving groove 32 is opened on the distal end of the second proximal prosthesis 12,

a second solid of revolution tip 42 is provided on the proximal end of the second distal prosthesis 22,

a second bowl-shaped spacer 52 is disposed between the second receiving groove 32 and the second rotator tip 42, the second rotator tip 42 is rotatably fixed in the second bowl-shaped spacer 52, and the second bowl-shaped spacer 52 is rotatably fixed in the second receiving groove 32;

wherein, the second revolving body head 42 and the second bowl-shaped gasket 52 can only rotate reciprocally in the same direction; i.e. can only rotate towards the palm or reversely

When the second distal prosthesis 22 is bent toward the inner side of the finger/toward the palm with respect to the second proximal prosthesis 12 under an external force, the second rotator tip 42 and the second bowl-shaped spacer 52 first rotate relatively, after the second distal prosthesis 22 is rotated to the extreme position, the second bowl-shaped spacer 51 and the second receiving groove 32 can rotate relatively when the second distal prosthesis 22 is subjected to a larger force, and preferably, the rotation angle is 80 to 90 degrees when the second distal prosthesis is rotated to the extreme position.

The tightness between the second rotator tip 42 and the second bowl-shaped spacer 52 is less than the tightness between the second bowl-shaped spacer 52 and the second receiving groove 32.

The second bowl-shaped gasket 52 and the second rotator head 42 are provided with a rotation limiting structure, which can allow the two to rotate relatively by a certain angle, for example, about 10 degrees, and after the maximum allowable angle is reached, the two can be locked by a mechanical limiting manner.

Preferably, said second solid of revolution end 42 is like a round bar as shown in fig. 6; specifically, the second revolving body end 42 includes a round bar located in the middle, hemispherical ends are provided at both ends of the round bar, and the radius size of the hemisphere is consistent with that of the round bar; the second rotator tip 42 can only rotate reciprocally in one direction within the second bowl-shaped spacer 52.

In addition, the provision of the second rotator tip 42 in the shape of a circular rod improves the stability of the second rotator tip 42 against lateral rotation/deflection, so that the second distal prosthesis 22 connected to the second rotator tip 42 can only bend towards the inside of the finger.

In a preferred embodiment, a second bend limiting stop 62 is provided on the second distal prosthesis 22,

when the second distal prosthesis 22 is bent at a predetermined angle relative to the second proximal prosthesis 12 under the action of an external force, the second bending limiting baffle plate 62 abuts against the second proximal prosthesis 12, thereby limiting the second distal prosthesis 22 from further bending. Preferably, the predetermined angle is 100 to 110 degrees.

In a preferred embodiment, a bent rod two 72 is provided at the proximal end of the second distal prosthesis 22, and the second distal prosthesis 22 is connected with the second rotator tip 42 through the bent rod two 72;

preferably, the second bending rod 72 is bent towards the inner side of the finger/palm direction;

more preferably, the bending angle of the second bent rod 72 is 30-45 degrees; the second bent rod 72 is short in length, and the bionic performance of the artificial interphalangeal joint in the application can be further enhanced by the second bent rod 72, so that the connection strength of the bionic artificial interphalangeal joint is improved, and the dislocation risk is reduced;

specifically, the joint between the middle phalanx and the proximal phalanx is stressed greatly, and in order to ensure the connection strength of the joint, the second bowl-shaped spacer 52 needs to be made larger to cover a larger area of the second revolving body end 42, as shown in fig. 9, 60% -70% of the second revolving body end 42 is covered by the second bowl-shaped spacer 52, so that the two are difficult to dislocate, under the condition of large covering amount, the relative maximum rotation amplitude between the two is limited, if the straight rod is used for replacing the bent rod II 72, the maximum rotation angle of the second revolving body end 42 in the second bowl-shaped spacer 52 is limited greatly, and the maximum rotation angle in a single direction is only about 50 degrees; after the second revolving body end 42 is connected through the second bent rod 72, the maximum rotation angle of the second revolving body end 42 in the second bowl-shaped gasket 52 can reach more than 90 degrees through the matching of the second bent rod 72 and the notch.

In a preferred embodiment, a first notch 81 is formed on the wall of the second receiving groove 32 in the direction close to the inner side of the finger,

a second notch 82 is formed in the second bowl-shaped gasket 52 in the direction close to the inner side of the finger, and the width of the first notch 81 and the width of the second notch 82 are slightly larger than the diameter of the second bent rod 72.

And when the second distal prosthesis 22 is bent, the second bent rod 72 can be embedded into the first notch 81 and the second notch 82, so that the bending angle of the second distal prosthesis 22 is more than 90 degrees.

More preferably, a second notch is further formed in the second bowl-shaped gasket 52 in a direction opposite to the second notch 82, and the second notch is used for placing the second bent rod 72, so that the second bent rod 72 does not interfere with the second bowl-shaped gasket 52 when the finger is in the straightened state.

In a preferred embodiment, as shown in fig. 10, 11, 12 and 13, the biomimetic artificial interphalangeal joint further comprises:

a third proximal prosthesis 13 fixed proximally to the metacarpal bone and a third distal prosthesis 23 fixed distally to the proximal phalanx,

a third receiving groove 33 is opened on the distal end of the third proximal prosthesis 13,

a third body of revolution tip 43 is provided on the proximal end of the third distal prosthesis 23,

a third bowl-shaped spacer 53 is provided between the third housing groove 33 and the third rotor tip 43, the third rotor tip 43 is rotatably fixed to the third bowl-shaped spacer 53, and the third bowl-shaped spacer 53 is fixed to the third housing groove 33;

wherein the third rotator tip 43 is rotatable in any direction,

said third body tip 43 is spherical, as shown in fig. 10, 11;

preferably, at the proximal end of said third distal prosthesis 23, a bent rod three 73 is provided, by means of which said third distal prosthesis 23 is connected to said third body of revolution head 43;

the bending angle of the third bent rod 73 is 30-45 degrees. The length of the third bent rod 73 is short, and the third bent rod 73 can further enhance the bionic performance of the artificial interphalangeal joint in the application, improve the connection strength of the bionic artificial interphalangeal joint and reduce the dislocation risk;

specifically, the joint between the metacarpal bone and the proximal phalanx is stressed greatly, and in order to ensure the connection strength of the metacarpal bone and the proximal phalanx, the third bowl-shaped spacer 53 needs to be made larger to cover a larger area of the third rotation body tip 43, as shown in fig. 10, 50% -60% of the third rotation body tip 43 is covered by the third bowl-shaped spacer 53, so that the third rotation body tip and the third bowl-shaped spacer are difficult to dislocate, the maximum amplitude of the relative rotation between the third rotation body tip and the third bowl-shaped spacer is limited under the condition of large covering amount, if the bent rod III 73 is replaced by a straight rod, the maximum rotation angle of the third rotation body tip 43 in the third bowl-shaped spacer 53 is limited greatly, and the third rotation body tip can rotate only about 50; after the third revolving body end 43 is connected through the third bent rod 73, the third revolving body end 43 is matched with the notch through the third bent rod 73, and the maximum rotation angle of the third revolving body end 43 in the third bowl-shaped gasket 53 can reach about 90 degrees.

In a preferred embodiment, a third notch 83 is formed in the wall of the third receiving groove 33 in the direction toward the inner side of the finger,

a fourth notch 84 is formed in the third bowl-shaped gasket 53 in a direction close to the inner side of the finger, and the width of each of the third notch 83 and the fourth notch 84 is slightly larger than the diameter of the third bent rod 73.

When the third distal prosthesis 23 is bent inward, the bent rod three 73 can be inserted into the notch three 83 and the notch four 84, so that the angle of bending the third distal prosthesis 23 inward is more than 90 degrees.

When the third distal prosthesis 23 is bent in a direction other than the inner side of the finger, the bent rod three 73 can only rotate by an angle of about 50 degrees under the obstruction of the third bowl-shaped gasket 53, and the function is basically consistent with the function of the normal human finger.

In a preferred embodiment, the third accommodating groove 33 and the third bowl-shaped gasket 53 cannot rotate relatively, a downward convex boss is arranged at the bottom of the third bowl-shaped gasket 53, and a groove is arranged at the bottom of the third accommodating groove 33, the groove and the boss are basically consistent in size and shape, and just can accommodate the boss; preferably, the boss has an edge, such as a cube or a hexagonal prism, so that the third bowl-shaped gasket 53 cannot rotate/roll with respect to the third receiving groove 33 after the third bowl-shaped gasket 53 is placed in the third receiving groove 33.

In a preferred embodiment, a third bend limiting stop 63 is provided on the third distal prosthesis 23,

when the third distal prosthesis 23 is bent relative to the third proximal prosthesis 13 by a predetermined angle under the action of an external force, the third bending limit baffle 63 abuts against the third proximal prosthesis 13, so that the third distal prosthesis 23 is limited to be bent continuously; in the actual use process, the third bending limiting blocking piece 63 is mainly used for limiting the bending of the third distal prosthesis 23 towards the inner side of the finger, and the third bowl-shaped gasket 53 can play a specific limiting role when the third distal prosthesis 23 is bent towards other directions.

As shown in fig. 1, the bionic artificial interphalangeal joint provided by the present application includes three proximal prostheses and three distal prostheses, which constitute three groups of joints, respectively: a biomimetic joint consisting of a first proximal prosthesis 11 and a first distal prosthesis 21 for use in the joint between the middle and distal phalanges; a biomimetic joint consisting of a second proximal prosthesis 12 and a second distal prosthesis 22 for use in the joint between the proximal phalanx and the middle phalanx; and a biomimetic joint consisting of a third proximal prosthesis 13 and a third distal prosthesis 23 for use in the joint between the metacarpal bone and the proximal phalanx; in the actual use process, any one group or multiple groups can be selected, and as each group corresponds to a specific finger position, the adaptability is stronger, and the postoperative recovery effect is more ideal.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front", "rear", and the like indicate the directions or positional relationships based on the operating states of the present invention, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element indicated must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

The present invention has been described above in connection with preferred embodiments, which are merely exemplary and illustrative. On this basis, can be right the utility model discloses carry out multiple replacement and improvement, these all fall into the utility model discloses a protection scope.

Claims (10)

1. A bionic artificial interphalangeal joint is characterized by comprising a near-end prosthesis (1) and a far-end prosthesis (2) matched with the near-end prosthesis;

wherein the near end of the near end prosthesis (1) is fixed on the metacarpal bone or the phalanx, the far end of the near end prosthesis (1) is provided with a receiving groove (3),

the far end of the far-end prosthesis (2) is fixed on the phalanx, a revolving body tip (4) is arranged on the near end of the far-end prosthesis (2),

a bowl-shaped gasket (5) is arranged between the accommodating groove (3) and the revolving body end socket (4), the revolving body end socket (4) is rotatably fixed in the bowl-shaped gasket (5), and the bowl-shaped gasket (5) is fixed in the accommodating groove (3).

2. The biomimetic artificial interphalangeal joint according to claim 1,

the bionic artificial interphalangeal joint includes:

a first proximal prosthesis (11) fixed proximally to the middle phalanx and a first distal prosthesis (21) fixed distally to the distal phalanx,

a first receiving groove (31) is arranged on the far end of the first near-end prosthesis (11),

a first revolved body tip (41) is arranged on the proximal end of the first distal prosthesis (21),

a first bowl-shaped gasket (51) is arranged between the first accommodating groove (31) and the first rotating body head (41), the first rotating body head (41) is rotatably fixed in the first bowl-shaped gasket (51), and the first bowl-shaped gasket (51) is rotatably fixed in the first accommodating groove (31);

wherein the first revolving body tip (41) and the first bowl-shaped gasket (51) can only rotate in a reciprocating way in the same direction,

when the first far-end prosthesis (21) is bent towards the inner side of a finger relative to the first near-end prosthesis (11) under the action of an external force, the first revolving body tip (41) and the first bowl-shaped gasket (51) firstly rotate relatively, and after the first far-end prosthesis (21) rotates to the extreme position, the first bowl-shaped gasket (51) and the first accommodating groove (31) can rotate relatively when the first far-end prosthesis (21) is subjected to a larger action force.

3. The biomimetic artificial interphalangeal joint according to claim 2,

a first bending limit baffle sheet (61) is arranged on the first far-end prosthesis (21),

when the first far-end prosthesis (21) is bent relative to the first near-end prosthesis (11) by a preset angle under the action of external force, the first bending limit stop sheet (61) is abutted with the first near-end prosthesis (11), so that the first far-end prosthesis (21) is limited to be bent continuously.

4. The biomimetic artificial interphalangeal joint according to claim 1,

the bionic artificial interphalangeal joint further comprises:

a second proximal prosthesis (12) fixed proximally to the proximal phalanx and a second distal prosthesis (22) fixed distally to the middle phalanx,

a second receiving groove (32) is arranged on the far end of the second near-end prosthesis (12),

a second revolved body tip (42) is arranged on the proximal end of the second distal prosthesis (22),

a second bowl-shaped gasket (52) is arranged between the second accommodating groove (32) and a second rotating body end (42), the second rotating body end (42) is rotatably fixed in the second bowl-shaped gasket (52), and the second bowl-shaped gasket (52) is rotatably fixed in the second accommodating groove (32);

wherein, the second revolving body head (42) and the second bowl-shaped gasket (52) can only rotate in the same direction in a reciprocating way;

when the second far-end prosthesis (22) is bent towards the inner side of a finger relative to the second near-end prosthesis (12) under the action of an external force, the second revolving body end (42) and the second bowl-shaped gasket (52) firstly rotate relatively, and after the second far-end prosthesis (22) rotates to the extreme position, the second bowl-shaped gasket (52) and the second accommodating groove (32) can rotate relatively when the second far-end prosthesis (22) is subjected to a larger action force.

5. The biomimetic artificial interphalangeal joint according to claim 4,

a second bending limit baffle plate (62) is arranged on the second far-end prosthesis (22),

when the second far-end prosthesis (22) is bent relative to the second near-end prosthesis (12) by a preset angle under the action of external force, the second bending limit stop sheet (62) is abutted with the second near-end prosthesis (12), so that the second far-end prosthesis (22) is limited to be bent continuously.

6. The biomimetic artificial interphalangeal joint according to claim 4,

a second bent rod (72) is arranged at the proximal end of the second far-end prosthesis (22), and the second far-end prosthesis (22) is connected with the second revolution body end (42) through the second bent rod (72);

the second bent rod (72) is bent towards the inner side of the finger;

the bending angle of the second bent rod (72) is 30-45 degrees.

7. The biomimetic artificial interphalangeal joint according to claim 6,

a first notch (81) is arranged on the wall of the second accommodating groove (32) in the direction close to the inner side of the finger,

a second notch (82) is arranged on the second bowl-shaped gasket (52) in the direction close to the inner side of the finger,

and when the second far-end prosthesis (22) is bent, the bent rod II (72) can be embedded into the first notch (81) and the second notch (82), so that the bending angle of the second far-end prosthesis (22) is more than 90 degrees.

8. The biomimetic artificial interphalangeal joint according to claim 1,

the bionic artificial interphalangeal joint further comprises:

a third proximal prosthesis (13) fixed at the proximal end on the metacarpal bone and a third distal prosthesis (23) fixed at the distal end on the proximal phalanx,

a third accommodating groove (33) is arranged on the far end of the third near-end prosthesis (13),

a third revolution body end (43) is arranged on the near end of the third far-end prosthesis (23),

a third bowl-shaped gasket (53) is arranged between the third accommodating groove (33) and a third rotating body end (43), the third rotating body end (43) is rotatably fixed in the third bowl-shaped gasket (53), and the third bowl-shaped gasket (53) is fixed in the third accommodating groove (33);

wherein the third rotator tip (43) is rotatable in an arbitrary direction,

a bent rod III (73) is arranged at the proximal end of the third distal prosthesis (23), and the third distal prosthesis (23) is connected with the third revolution body head (43) through the bent rod III (73);

the bent rod III (73) is bent towards the inner side of the finger;

the bending angle of the bent rod III (73) is 30-45 degrees.

9. The biomimetic artificial interphalangeal joint according to claim 8,

a third notch (83) is arranged on the wall of the third accommodating groove (33) in the direction close to the inner side of the finger,

a fourth notch (84) is arranged on the third bowl-shaped gasket (53) in the direction close to the inner side of the finger,

when the third distal prosthesis (23) is bent towards the inner side of the finger, the bent rod III (73) can be embedded into the notch III (83) and the notch IV (84), so that the angle of bending the third distal prosthesis (23) towards the inner side of the finger is more than 90 degrees.

10. The biomimetic artificial interphalangeal joint according to claim 8,

a third bending limit baffle (63) is arranged on the third far-end prosthesis (23),

when the third far-end prosthesis (23) is bent relative to the third near-end prosthesis (13) by a preset angle under the action of external force, the third bending limit stop sheet (63) is abutted with the third near-end prosthesis (13), so that the third far-end prosthesis (23) is limited to be bent continuously.

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