The present invention relates to a knee prosthesis comprising a femoral component, a tibial plateau and an intermediate meniscal plate.
It has an important application mainly, but not exclusively, in the field of so-called total knee prostheses.
It is known that knee prostheses are generally of the three-compartment type.
In other words, they are prostheses comprising, on the one hand, two elements for replacing the femoral part and tibial part of the joint between the femur and the tibia, and, on the other hand, an element for forming the intermediate friction surface of the patella.
The complete or total prosthetic structure thus has a femoral component or plane, a tibial plateau or plane, and a meniscal plate often called the tibial insert. It is completed by a patellar implant which, since it has no role in the context of the present invention, will not be mentioned again hereinafter.
In a manner known per se, the tibial plateau cooperates with the femoral component via the meniscal plate, so as to thereby produce the different movements of the knee joint.
It should he noted at this point that, in order to permit adaptation to the different morphologies of patients, all of these implants have to be provided in several sizes and thicknesses. Regarding the use of these prostheses, there are essentially two techniques for reconstructing the knee joint.
The first technique involves using a meniscal plate that is fixed with respect to she tibial plateau.
The second technique involves using what are called mobile meniscal plates, as opposed to the fixed meniscal plates.
These mobile plates are designed to better reproduce the Kinematics of the joint by reducing the paradoxical movements due to the femoral component.
To permit the implementation of these two techniques, the surgeon must therefore have access to meniscal plates for each size and for each possible technique, and also in several thicknesses.
Moreover, regardless of the meniscal plates used, whether fixed or mobile, some surgeons consider it important to preserve the posterior cruciate ligament, when possible, in order to limit the anterior displacements of the femur with respect to the tibia.
By contrast, other surgeons favor removing this ligament, preferring to achieve limitation of the anterior displacement of the femur on the basis of the particular design of the meniscal plate.
It is therefore necessary to have fixed plates with cruciate, fixed plates without cruciate, mobile plates with cruciate and mobile plates without cruciate, which further increases the number of plates. It will be noted that “without cruciate” is equivalent to “postero-stabilised”.
The surgeon then has to choose the meniscal plate that will permit optimal reconstruction of the patient's joint in terms of the stability and amplitude of the movements wanted for the patient in question.
The prostheses of the prior art have a considerable disadvantage in particular in this respect. They require the provision of a very large number of femoral components, tibial plateaus and meniscal plates, in order to cover all eventualities.
In other words, a range of knee implants which includes the two types of meniscal plates, namely the mobile plates and the fixed plates, while permitting a choice between preserving the posterior ligament or removing it, is necessarily composed of a large number of components.
For example, a range of prostheses in the prior art consisting of eight sizes of femoral components for each side and for each type, i.e. thirty-two femoral components in total, three thicknesses of meniscal plates for each size and each type, and, finally, sixteen sizes of tibial plates, requires the provision of one hundred and forty-four different elements.
Prostheses are known (US 2006/0161259) that comprise a central fixation component and are intended to function after removal of the ligament.
Prostheses are also known (EP 0 732 091) that are designed to function without removal and with antero-posterior play and the possibility of rotation.
Such prostheses give rise to paradoxical movements leading to dislocations of the joint and to abnormal attrition of the meniscal component.
Moreover, none of these prostheses allows control of both clinical cases simultaneously.
One of the objects of the present invention is to make available a knee prosthesis which meets the practical requirements better than those that are already known, especially one which permits the same physical possibilities as the prostheses of the prior art, but which requires a much smaller number of elements.
Thus, practically all of the component parts of a prosthesis according to the invention will be able to function in one case with removal of the ligament and in the other case without removal of the ligament.
By virtue of one of the aspects of she invention, it will thus be possible to reduce the stock and therefore the investments of the implant manufacturer, while at the same time increasing patient safety by eliminating potential sources of error.
Moreover, the invention reduces the operating time and allows surgeons and operating theater personnel to be trained quickly in the use of the range of implants.
To this end, the invention essentially proposes a knee prosthesis comprising a femoral component connected to a tibial plateau by an intermediate meniscal plate provided with an upper face, said femoral component having a trochlear shield provided with an outer face cooperating under gentle friction with at least one guide area of complementary shape formed in said upper face,
Thus, by virtue of this particular design of the meniscal plate, the same meniscal plate, which can also be designated as a so-called mixed meniscal plate, can be used equally as a fixed plate or as a mobile plate, depending on the tibial plateau chosen by the surgeon, and this will reduce the stock of meniscal plates by half.
In the embodiment more particularly described here, the tibial joining face is larger than the meniscal joining face in all of its dimensions parallel to its antero-posterior axis of symmetry, and also perpendicularly with respect to this axis (medio-lateral dimensions).
In other words, when the meniscal plate is centered, and in its median position on the tibial plateau, all of the meniscal joining surface is inscribed entirely within the tibial joining surface, which has an edge always protruding, for example by 1 mm, beyond the periphery of the meniscal joining surface, this periphery never being coincident at any point with said edge in this position.
This arrangement will, on the one hand, surprisingly permit the standardization of the components leading to the invention and will, on the other hand, permit protection of the ligaments and/or soft tissue parts belonging to and/or adjacent to the joint.
Advantageously, the surfaces of the planar joining faces are in the shape of an ellipse or substantially in the shape of an ellipse, truncated on an edge, for example over 1/10th or even 1/20th of their surface, parallel to the main axis of the ellipse.
The surfaces are designed to permit rotary pivoting of one with respect to the other, such that the curved outer periphery of the meniscal joining face in the shape of a portion of an ellipse, or substantially in the shape of a portion of an ellipse, remains inscribed within the joining face of the tibial plate, for an angle of rotation between the faces of between −12° and +12°, or even −8° and +8° and/or −4° and +4°, with respect to the medio-lateral axis of the meniscal plate, or main axis of the ellipse.
In practice, with the movements of the knee being physiologically limited in terms of rotation of the order of ±4 to 5°, or ±7 to 8°, such arrangements make it possible to preserve the soft tissue parts without the need to provide specific limit stops.
Unexpectedly, therefore, there is natural protection of the soft tissue parts.
Moreover, the fact that the (potentially aggressive) outer periphery of the meniscal plate, thus always inscribed within the surface of the tibial plate, is able to pivot in rotation about a pin joined integrally to the tibial plateau or tibial component, without any possibility of the meniscal plate sliding with respect to the tibial plateau, or by contrast can be rigidly fixed to said tibial component by fingers, avoids the protuberances that occur in the position of equilibrium and that create micro-stresses leading to more rapid wear and/or to pain.
In particular embodiments, use is also made of one and/or more of the following arrangements:
Such an arrangement avoids anterior dislocation of the prosthetic joint;
The invention also proposes a set of several prostheses as have been described above, characterized in that it has at least one tibial plateau for a fixed meniscal plate and at least one tibial plateau for a mobile meniscal plate, and a range of corresponding meniscal plates of several thicknesses.
The invention will be better understood on reading the following description of embodiments given as non-limiting examples.
In the description, reference is made to the accompanying FIGS. where:
In the description below, the same reference numbers will be used to designate identical elements.
The intermediate meniscal plate 4 and the tibial plateau 3 are connected to each other by way of two planar joining faces, namely a tibial joining face 11 and a meniscal joining face 12, the tibial joining face 11 being larger than the meniscal joining face 12 in its antero-posterior dimension d and medio-lateral dimension D.
The pin 6 is shaped like a Phrygian cap or the upper phalanx of a thumb, having an upper lip 13 forming a slight projection 14 designed to generate a retreating movement of the femoral component in the event of the latter shifting (arrow 15) by more than 1 mm with respect to the meniscal plate.
More precisely, the femoral component 2 comprises a first tongue-shaped part 16 ending at a point 16′, defining the concave surface of revolution of the outer sliding face 9, which has a variable radius of curvature between said first tongue-shape part and its lateral parts 17, symmetrical with respect to a central axis 18.
The femoral component terminates on the other side with end parts 19, opposite the pointed part of the trochlear surface, said parts 19 being curved inward.
In this embodiment, these two parts 19 are connected by way of a central joining beam 20, closing the guide slit 8 for the pin.
The slit 8 has, for example, a substantially rectangular shape with a curvature corresponding to that of the femoral component.
In the embodiment more particularly described here, the slit 8, with a width slightly greater than that of the pin 6, for example of 2 mm, has a length which, for example, is equal to two thirds of the deployed length of the surface of cooperation of the femoral component 2 wish the meniscal plate 4.
The meniscal plate 4 itself has a first part 21 anterior to the pin 6 and rising toward the outside, and a second part 22 posterior to the central pin of the meniscal plate, provided with a rounded reinforcement zone 23 and connecting the two postero-lateral zones 10 of complementary shape to the two lateral zones of the outer face 9 of the trochlear shield of the femoral component.
This reinforcement zone 23 can itself be provided with a recess 24 toward the outside, situated on its outer surface, permitting a better grip of the meniscal plate.
The meniscal plate 4 will be described in more detail below with reference to
However, for the time being, it will be noted that this meniscal plate comprises, in combination, a cylindrical central orifice 25 (cf.
With reference to
Thus, in
The pin 26 is cylindrical and has, for example, an end forming a slight projection that engages with a snap fit in a complementary groove internal to the blind hole 25.
The tibial plateau 3 moreover has a bone-anchoring foot 30 of a form known per se, for example composed of a central plug 31 provided with two fluted lateral wings 32 forming a V shape, permitting good fixation and indexing in the bone once the latter has been resected by the surgeon in order to implant said tibial plateau therein.
In the embodiment in
However, the clipping can advantageously be effected about the entire periphery of the plateau, in which case the whole periphery 36 clips into an opposite recess 37 of the edge of the meniscal face.
Two tongue-shaped recesses 39 are also provided at an angle to the periphery of the meniscal joining face 12.
A tongue-shaped recess is, for example, of substantially oval or rectangular shape, with a length corresponding to a fifth or a seventh of the distance d of the meniscal face. When an instrument is slid into them, these recesses permit leverage and allow the meniscal plate to be disconnected from the tibial plateau when they have been fitted by clipping.
Advantageously, the peripheral edge 36 of the plateau is recessed slightly at 38 in the area of the “tongues” in order to facilitate the introduction of the tool forming the lever arm.
This plate 4 thus has an upper face 5 provided with a pin 6, which has the shape of a Phrygian cap or the end of a thumb and which is provided with an inwardly curved part 40 ending with an upper lip 41 forming a slight projection. embodiment, to be without pin 10, especially But the plate 4 can of course, in another when the antero-posterior ligament is preserved by the surgeon.
The upper face 5 comprises, on each side of the anterior area 42 and posterior area 43 of the surface, raised parts 44 and 45, for example raised by 1 to 2 mm with respect to the adjacent surface. The face 5 also comprises, on each side of the pin, concave surfaces of development forming the guide parts 10.
The meniscal face 12 cooperating with the tibial face 11 has (cf.
The face 12 also has (cf.
The recesses are formed, for example, by grooves with protuberances 46′, 47′ in the plane of the joining face 12.
The two embodiments of tibial plateaus described with reference to
In
It is therefore a rotary plateau. The tibial joining face 11 has an antero-posterior dimension d and medio-lateral dimension D slightly greater than the meniscal face 12, so as not to protrude past the latter during the rotation, which can be done by a few degrees.
By virtue of the relative dimensions between meniscal joining face and tibial joining face, it will be possible to permit a rotation without external protrusion, even in the case of mixing sizes as necessitated by anatomical constraints.
For example, if one takes a femoral component of size 5, a meniscal plate of size 5 and a smaller tibial plateau, of size 4, the soft tissue parts of the knee still remain protected, even in the event of rotation by a few degrees.
This important feature in the embodiment of the invention more particularly described here will be explained in detail with reference to
The embodiment in
Here, the meniscal place is clipped rigidly into the base formed by the tibial plateau 29, which is here once again of a slightly greater size.
When, in the prior art, the sizes were organized to meet anatomical constraints, the differentiation was obtained especially with the femur.
According to the invention, with which it is possible to reduce by half the number of meniscal plates, the insert is always of a smaller size, allowing it to fit on a fixed base as well as a mobile base. It is therefore the fixed base or tibial plateau which, by virtue of its special configuration, adapts to the insert or meniscal plate.
Finally, the tibial joining face advantageously comprises an opened peripheral part 50 for passage of a finger under the meniscal joining face, allowing is to be disconnected from the plateau. This recess 50 is, for example, substantially rectangular, with a width of between 1/10th and ⅓rd, for example ¼th, of the dimension d, and with a length of between 1/10th and ⅓rd of D, for example ⅕th.
When the meniscal plate pivots slightly about the axis 51 during the movements of the patient, it is observed that the outer peripheral edge 52 of the meniscal plane, having a cross section in the shape of a truncated ellipse, remains within the joining face 11, that is to say doss not protrude outward from the peripheral edge 53, of the tibial plateau for an angle α of the order of 12° when, normally, the components are of the same size (
The implantation of a prosthesis according to the invention by a surgeon is now described with reference to
When the surgeon begins an operation, he first of all determines, from the physiology of the patient, what will best correspond to the bone configuration of the latter.
On this basis, he decides to fit either a fixed prosthesis or a mobile prosthesis.
He then chooses the tibial plateau corresponding to either the fixed or mobile solution.
This solution having been adopted, all he has to do is implant, according to the size of the patient, the femoral component that is standard regardless of whether the fixed type or mobile type has been chosen. Finally, it only remains for him to determine the size of the meniscal plate according to the tibial plateau and the patient's configuration.
Whereas in the prior art he had to choose, for example, from among ninety-six different meniscal plates depending on the tibial plateau, he now only has to choose from among forty-eight meniscal plates, by virtue of the invention.
As has been indicated, the savings both in time and in costs, especially storage costs, are considerable.
It goes without saying, and it is also obvious from the above, that the present invention is not limited to the embodiments that have been more particularly described. On the contrary, it encompasses ail variants thereof, especially those in which the meniscal plates are made of plastic and those in which the surfaces of cooperation between the trochlear shield of the femoral component and the meniscal plate are of different configurations, and those in which the meniscal plate does not have a pin on its upper face, especially in the case of surgery where the cruciate ligament is not removed.
Number | Date | Country | Kind |
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10/01056 | Mar 2010 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR2011/000148 | 3/16/2011 | WO | 00 | 9/10/2012 |