DE2823215A1 - Implanted artificial hip joint - has leaf spring forming damper between shank boss and socket in ball head - Google Patents

Abstract

The implanted artificial hip joint is for human bodies and it has a socket fixed in the recess of the hip bone and accommodating a ball head. The ball head is joined to a shank fixed in the upper thigh bone via a damping member absorbing shock and allowing relative movement. The member is a bent leaf spring(18) between a boss(14) on the shank(9) and a recess(16) in the ball head(8) enclosing the boss at least partly in the main load direction. The spring has inner and outer supporting sections(23, 19, 21) bearing against boss or ball head, and joined to each other by bending spring sections (24, 26).

Description

Stw .: hip joint prosthesis spiral spring

Hip joint prosthesis The invention relates to a hip joint prosthesis for implantation in the human body, with one in the acetabular cavity of the hipbone fixable joint socket, one received by the joint socket Ball head and a shaft that can be fastened in the thigh bone, with shaft and ball head via a shock-absorbing one that enables a relative movement between the two Attenuators are connected to each other.

In practice, hip joint prostheses of the type mentioned at the beginning have proven to be useful Type enforced, the thigh part of which is formed by a metallic ball head while the hip gel socket part is made of plastic such as polyethylene.

This metal / plastic combination was found to be an acceptable compromise in terms of a relatively low coefficient of friction and a less favorable, but still considered acceptable wear resistance.

The material polyethylene also comes in its elastic Properties very close to human bones, so that they are also shock-absorbing Effect is present. Nevertheless, there are always loosening of the means common bone cements in the pelvis attached to the joint socket, being the causative factor Vibration movements in the micro range are considered that when loading and moving of the joint from the socket through the bone Stw .: hip joint prosthesis spiral spring cement can be transferred through to the bone.

The loosening of the pan is favored by the well-known bad Bondability of polyethylene.

The fact that the anchoring also has a disadvantageous effect Polyethylene flows and has a relatively large coefficient of expansion. By anchoring with bone cement, reaction temperatures between 800 and 120 ° C occur on.

To absorb the impact energy and destructive forces at the interfaces between the artificial joint and the bone structure, it has already been suggested that in a cohesive connection, e.g. by vulcanizing, intermediate layers made of rubber-elastic To attach material either to the socket or between the shaft and the ball head, i.e. to give the ball head an elastic evasion possibility on all sides.

Such possible solutions, on the other hand, are more theoretical in nature and problematic in many ways in their implementation.

Other prior art paper proposals remained in shape of pumping devices for pumping tissue fluid under shock loads between the bearing surfaces of the joint are far too expensive, complicated and prone to failure and therefore risky for the wearer of the prosthesis.

The invention is based on the object of a simple structure, to create safe and possibly replaceable attenuator that is in the Is capable of shock loads from different directions both axially and to absorb radially elastic and the joint is still sufficient Gives stability.

Stw .: Hip joint prosthesis spiral spring This object is achieved according to the invention solved in that the attenuator as one in a free space between a The spiral spring is arranged on the pin of the shaft and a recess in the ball head is formed, which the pin at least partially or in the area of the main load direction of the hip joint encloses in such a way that the spiral spring with at least one inner Sttltzabschnitt and an outer support portion is provided, each on a of the parts (pin or ball head) are in contact and through a resilient bending section are connected to each other.

The inner support section is located on the pin and the outer support section on the ball head.

In itself it would be sufficient to place the spiral spring in the area of the main load direction of the hip joint, i.e. to be arranged over an angle of approx. 1200. In this sense the spiral spring could, for example, be designed as a partial ring or also from individual ones Be composed of ring segments, which are on corresponding flat support surfaces of the pin or on an annular surface of the pin could support abz.

In contrast, a particularly advantageous development of the invention is characterized in that the spiral spring as a completely enclosing the pin closed ring is formed, wherein the pin has a cylindrical shape having.

Versatile shock absorption is achieved according to one of the present invention Further development achieved in that the spiral spring has two outer support sections and has an inner support section arranged between the two.

This training serves at the same time a safe guidance or centric Storage of the pin in the ball head. Stw .: hip joint prosthesis spiral spring An additional suggestion, according to which the spiral spring has a plate spring section on the end face is provided, which is supported on an annular flange of the shaft, aims at it towards, in particular and predominantly impact loads acting in the axial direction to be elastically yielding and rendered ineffective.

To absorb the axial forces, the cup spring section also has opposite end face of the spiral spring has a support ring section resting on the ball head on. To avoid a relative rotation of the ball head with respect to the Za> in, it is proposed according to a further development that the outer and the inner support section the spiral spring are provided with a nose-like projection, which in corresponding Engage the locking grooves of the ball head or the pin. To increase elasticity or the targeted local deflection option, the spiral spring is as proposed provided with axially extending weakening slots, which alternate from the opposite end faces are introduced or break through.

Stw .: Hip-joint prosthesis-bending feather The invention is described below explained in more detail using an exemplary embodiment shown in the drawing.

The figures show: FIG. 1 schematically, partially in section, an inventive device Hip joint prosthesis in the position of use and FIG. 2 the spiral spring according to the invention in side view.

Stw .: Half-joint prosthesis spiral spring In the case of the one shown in FIG The arrangement is the acetabulum 1 of the auxiliary leg 2 in its lower lateral section Milled out approximately hemispherical. Inside this hemispherical chamber is a Joint socket 3 cemented in, the high in a known manner made of a polyethylene Density is shaped. To better anchor the joint socket 3 with the hat In the 2 connecting bone cement, the joint socket is on its outer surface provided with grooves 4, in which the bone cement when attaching the joint socket can penetrate.

The wall of the socket 3 is of different thickness, and although the overhead wall section is via which the pressure forces from the hat leg 2 are transferred to the thigh 6, more strongly formed than the one below Wall section. This is achieved in that the approximately hemispherical inner chamber 7 of the joint socket 3 eccentric to the likewise hemispherical outer surface the joint socket 3 is arranged.

A metallic one rests rotatably in the inner chamber 7 of the joint socket 3 Ball head 8, e.g. made of Vitallium, which is provided with a shaft 9, which is in the marrow of the femur 6 is hammered in or cemented in.

For this purpose the upper part of the femur 6 is along the connecting line between the large rolling mound 11 and the small rolling mound 12 cut off and hollowed out.

The hip joint mounted according to Figure 1 allows movements of the ball head 8 in the joint socket 3 both in the pivoting direction according to arrow F1 and in FIG the direction of rotation F2, whereby in each position of the thigh bone 6 Stw .: Hip joint prosthesis bending spring is essential when standing or walking normally Supporting forces marked by the arrows F3 from the hip bone 2 on the thigh bone 6 are transmitted over that portion of the joint socket 3 which is relatively is strongly trained.

The shaft 9 fastened in the thigh bone 6 is released an annular flange 13 with a centrally arranged, cylindrical pin 14 provided, which in a likewise cylindrical recess 16 of the ball head 8 protrudes. The internal dimensions of the recess t are larger than the external dimensions of the pin 14, so that a free space in the form of a gap 17 is formed on all sides will. In the gap 17 extends a metallic spiral spring 18, which is pretensioned is inserted and the pin 14 is centered with respect to the ball head 8. To this end the spiral spring is designed as a closed one-piece ring and with two outer, on the inner wall of the ball head 8 abutting support sections 19 and 21 and with an inner support section supported in an annular groove 22 of the pin 14 23, the outer support sections 19 and 21 with the inner support section 23 are connected by a resilient bending section 24 and 26, respectively.

To prevent the pin 14 from rotating with respect to the ball head 8, it points the spiral spring on one of its outer support sections 19 and on its inner one Support section 23 Stw .: hip joint prosthesis spiral spring, nose-like Projections 27 and 28, which in corresponding locking grooves of the ball head 8 and of the pin 14 engage and the pin 14 against both axial displacement also secure against twisting.

An additional, in particular axial deflection option of the Spiral spring 18 is given by the fact that it has a plate spring section on the end face 29 is provided, which is supported on the annular flange 13 of the shaft 9.

In addition, the plate spring section 29 opposite has The end face of the spiral spring 18 has a support ring section resting on the ball head 8 31 on.

According to Figure 2, the spiral spring 18 is also axially extending Weakening slots t2 provided, which alternate from the opposite end faces are introduced or either the plate spring section 29 or the support ring section Break through 31.

The ball head 8 is also provided with a through hole 33, which connects the gap 17 with the inner chamber 7 of the joint socket 3, so that for Lubrication of the joint surfaces when the pin 14 is compressed into the recess 16 of the Ball head 8 tissue fluid is pressed between the joint surfaces.

The advantage achieved by the invention is that such formed spiral spring on the one hand a secure, stable connection between the shaft and ball head forms and is easily exchangeable and on the other hand from all directions Can absorb shock forces elastically. This spiral spring also makes it possible to known, extremely shock-sensitive, but almost ideal material pairings for the joint socket and ball head in the form of ceramic.

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Claims (8)

Stw .: Hip joint prosthesis spiral spring Claims 1. Hip joint pro thesis for implantation in the human body, with one in the acetabular cavity of the hipbone fixable joint socket, one received by the joint socket Ball head and a shaft that can be fastened in the thigh bone, with shaft and ball head via a shock-absorbing one that enables a relative movement between the two Attenuators are connected to one another, characterized in that the attenuator as one in a free space (17) between a pin (14) of the shaft (9) and A spiral spring (18) arranged in a recess (16) of the ball head (8) is formed is, which the pin at least partially or in the area of the main load direction of the hip joint encloses in such a way that the spiral spring with at least one inner Support section (23) and an outer support section (19 or 21) is provided, which each rest on one of the parts (pin or ball head) and through a resilient bending section (24 or 26) are connected to one another. 2. Hip joint prosthesis according to claim 1, characterized in that the inner support section (23) on the pin (14) and the outer support section (19 or 21) rests on the ball head (8). Stw .: Hip joint prosthesis-flexural 3. Hip joint prosthesis according to the requirements 1 and / or 2, characterized in that the spiral spring (18) as a pin (14) is formed completely enclosing closed ring. 4. Hip joint prosthesis according to one or more of claims 1 to 3, characterized in that the spiral spring (18) has two outer style sections (19, 21) and an inner support section (23) arranged between the two. 5. r hip joint prosthesis according to one or more of claims 1 to 4, characterized in that the spiral spring (18) has a plate spring section on the end face (29) is provided, which is supported on an annular flange (13) of the shaft (9). 6. Hip joint prosthesis according to one or more of claims 1 to 5, characterized in that the plate spring section (29) opposite The end face of the spiral spring (18) has a support ring section resting on the ball head (8) (31). 7. Hip joint prosthesis according to one or more of claims 1 to 6, characterized in that the outer and the inner support section (19 or 23) of the spiral spring (18) are provided with a nose-like projection (27 or 28), which engage in corresponding locking grooves of the ball head (8) or the pin (14). Stw .: hip joint prosthesis-flexural leg 8. Hip joint prosthesis after a or more of Claims 1 to 7, characterized in that the spiral spring (18) is provided with axially extending weakening slots (32) which alternately are introduced from the opposite end faces or break through this.