Quadriceps control device for prosthetics/orthotics

A quadriceps control device comprises an elongated, elastic member having a first end affixed at an anterior position above the knee and a second end affixed at an anterior position below the knee of the user. The quadriceps control device may be utilized with a prosthetic or orthotic leg assembly. The quadriceps control device mimics to some degree the quadriceps muscle group in human anatomy, to thereby enhance the ability of a user of a prosthetic or orthotic leg assembly to control knee extension and flexion.

BACKGROUND OF THE INVENTION

The invention relates to prosthetic devices and, in particular, to a quadriceps control device for a prosthetic leg assembly. The invention may also be adapted for use with orthotics.

The quadriceps muscles are the large powerful muscles that produce approximately 80% of the total extension power of the human knee. The quadriceps muscles unite to form a strong tendon that attaches under the patella or kneecap. This is one of the reasons why it is so difficult for amputees having amputations above the knee. The loss of the knee joint also results in the loss of the lower attachment of the quadriceps muscle group that is utilized to extend the knee. The hamstring muscles are the knee flexor group; that is, these muscles flex the human knee. However, the quadriceps muscles also control knee flexion by a lengthening or eccentric muscle contracture.

Many users of prosthetic leg assemblies, both above and below the knee, as well as many of those requiring the use of an orthotic leg assembly, encounter difficulties controlling knee extension and flexion due, for example, to muscle weakness, nerve damage, or debilitating disease. Thus, it would be advantageous to provide a device that could to some degree mimic the quadriceps muscle group in human anatomy, to thereby enhance the ability of a user of a prosthetic or orthotic leg assembly to control knee extension and flexion.

BRIEF SUMMARY OF THE INVENTION

The invention relates to prosthetic devices and, in particular, to a quadriceps control device for a prosthetic leg assembly. The quadriceps control device of the invention may be employed with an above the knee prosthetic leg assembly, used herein to refer to any above the knee prosthetic, including a knee disarticulation, above the knee amputation of any length, and hip disarticulation. The quadriceps control device of the invention may also be employed with a below the knee prosthetic leg assembly of any length. The term knee is used herein to refer to a prosthetic or anatomical knee, unless one or the other is specified. The invention may further be adapted for use with orthotics.

The prosthetic or orthotic leg assembly comprises a first support structure positioned above an axis of rotation of a knee, a second support structure positioned below the axis of rotation of the knee, and the quadriceps control device. The quadriceps control device comprises an elongated, elastic member extending along an anterior portion of the assembly, and having a first end affixed to the first support structure and a second end affixed to the second support structure.

The quadriceps control device mimics to some degree the quadriceps muscle group in human anatomy, to thereby enhance the ability of a user of a prosthetic or orthotic leg assembly to control knee extension and flexion. The quadriceps control device of the invention thus allows knee flexion by stretching out or lengthening like a muscle does through an eccentric or lengthening contracture. The device begins to store energy at the beginning of swing phase when the knee begins to flex. It continues to lengthen and gradually stores more energy until it peaks and then the energy is gradually released to extend the knee. The amount of energy released to extend the knee joint is controlled by factors such as how tight the band is, how thick the band is, how wide the band is, how long the band is and how tight the band is adjusted.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to the drawings,FIGS. 1 and 2illustrate a residual limb transfemoral socket10connected, typically via a lock mechanism, to a prosthetic knee joint12. Such a transfemoral prosthetic limb is conventionally secured to an amputee's residual limb stump by securing the prosthetic limb to the rigid socket10. This may be done using suction, harnesses, etc. or combinations thereof. It is commonly done through the use of a locking pin14. In this technique, the amputee first dons a sock-like liner (not shown) formed of an elastomer and may include fabric cover. The lower or distal end of the liner is formed of a rigid material, such as urethane, and the locking pin extends from this rigid bottom. These liners are well known in the art. The pin14is extended through the wall of the socket10and a distal adapter mounted within or outside of the socket, and can be locked onto a prosthetic lock mounted to the prosthetic limb to secure the prosthesis. Typically, the lock pin can be released only by moving a pinion gear in a direction parallel to its rotational axis until it disengages from the lock pin, e.g., via a manual release button16.

In the illustrated embodiment ofFIGS. 1 and 2, the prosthesis includes a pylon18secured to the knee joint12. The quadriceps control device of the invention may be used in conjunction with any of the conventional prosthetic knees. The pylon18would in turn be connected to an artificial foot17by means of an ankle assembly19, in the conventional manner.

In accordance with the invention, the prosthetic leg assembly is provided with a quadriceps control device, denoted generally by numeral20inFIGS. 1 and 2. The quadriceps control device20includes an elongated, elastic member22. As illustrated inFIGS. 1 and 2, the member22has a first end24affixed to the prosthetic leg assembly at an anterior position above the axis of rotation of the prosthetic knee12, preferably to the socket10. As an alternative, the first end24of the member22could be affixed to an upper portion of the knee12. The first end24of the member22could also be affixed to an adapter connected to or part of the socket above the knee frame. The first end24of the member22may be affixed to the socket10by any suitable means, such as mechanical fasteners of any type or adhesives.

As further illustrated inFIGS. 1 and 2, the member22has a second end26affixed to the prosthetic leg assembly at an anterior position below the axis of rotation of the prosthetic knee12, so that the member22extends over the knee cap cover. The second end26of the member22is preferably affixed to the pylon18. However, the second end26of the member22could also be affixed to a lower portion of the knee12or to another lower component of the leg assembly. The second end26of the member22may be affixed to the pylon18by any suitable means, such as mechanical fasteners of any type or adhesives. In the preferred embodiment illustrated inFIGS. 1 and 2, the second end26of the member22is affixed to the pylon18by a means28which provides for ready adjustment of the attachment point along the length of the member22, thereby providing adjustability for the amount of tension applied to the elastic member22. Adjustment means may also be provided for the point at which the first end24of the member22is affixed, or for both ends of the member22. Thus, as illustrated inFIGS. 1 and 2, the first end24of the member22is affixed to the socket10by an adjustable attachment means. Any known means of adjustment may be utilized, such as the belt-like attachment29illustrated inFIG. 1.

It may further be preferred to affix the first, second or both ends of the member20to the leg assembly in a manner such that the point of attachment is adjustable along the length of the leg assembly. As illustrated, the attachment means28may be secured at varying points along the length of the pylon18, thereby adjusting the length of the member20between the points of attachment of the first and second ends thereof.

The ability to adjust the tension in the elongate, elastic member can be advantageous. For example, patients requiring a prosthesis may be debilitated at first and often need to walk with a walker because they do not have the strength or endurance and control of the prosthetic knee. If the quadriceps control device of the invention is tighter (tension on the elastic member is increased), it will resist knee flexion and make the knee more stable. As the patient loosens the tension on the member, it will allow increased knee flexion. As the patient progresses in their rehabilitation, the patient, therapist or prosthetist may loosen the member to fit the patient's needs. It may also be advantageous for the patient to be able to continue to adjust the tension in the member for different activities. For example, if the patient is working in a standing position in one area for a long time, the member may be tightened to resist unwanted knee flexion. Each patient may adjust the elastic member for different vocations, hobbies and sports activities. The patient may adjust the elastic member for slow walking, fast walking, jogging, going up and down steps, ramps, ladders, running, golfing, bowling and other various activities and sports.

While not necessary, it is often useful to provide one or more guides for the member22, such as the guide30. During use, the guide30prevents undue lateral movement of the member22while permitting relative movement between the guide30and the member22in the direction of the length of the member22.

The elongate member22may be formed of any elastic material of sufficient elasticity and durability. The member22is preferably formed of a rubber-like material, such as neoprene. The member22may also be formed of various cross-sectional shapes, thicknesses and widths. The member22is preferably formed with a rectangular cross-sectional shape with a width significantly greater than its thickness, so that it lies relatively flat against the components of the prosthetic leg assembly. It has further been found to be advantageous to provide the member with a layer of material having reduced friction relative to the remainder of the material, the layer being provided at least in the area of, and facing, the knee. The layer is preferably formed of a strong, reduced friction fabric material. A sleeve of such material (not shown) could also be provided about the member in the area of the knee to reduce friction and wear.

In use, the quadriceps control device20generally simulates the quadriceps muscle of the user. The prosthetic knee12permits movement of the upper part of the prosthesis with respect to its lower part, about an axis of rotation, analogous to the movement of the femur with respect to the tibia about the articulation of the human knee. This movement is between a position of complete extension (where the leg is straight, as shown inFIG. 2) and a position of flexure (where the leg is bent, as shown inFIG. 1). As the prosthetic leg assembly is moved during locomotion from a position of complete extension to a position of flexure in the direction of the arrow A ofFIG. 1, the member22is stretched about the front of the knee12, increasing the tension on the member22.

When the leg assembly is then moved from a position of flexure back to a position of extension, in a direction opposite to the arrow A ofFIG. 1, the energy stored in the elastic member22is released. The farther the attachment points of the first and second ends24,26of the member22are from the knee12, the more energy is stored during flexure and then released during extension of the leg assembly.

The member22thereby aids the user with extension of the knee. As a result, the user can experience significant increases in ease of walking and running. The benefit is especially significant at higher speeds. The invention enhances knee stability by allowing tightening of the member22. An increase in tension in the member22creates more stability, while a decrease in tension creates less stability. The invention also enhances general control and timing of the knee throughout the swing phase by allowing adjustment of the tension in the member22.

Referring toFIG. 3, an alternate embodiment of the invention is illustrated.FIG. 3shows a prosthetic knee assembly50having a knee cap52adapted to be secured to a residual limb transfemoral socket (not shown). A knee frame member54extends downward from the knee cap52and supports a hydraulic cylinder56in the conventional manner. The hydraulic cylinder56helps to control the relative movement of the upper part of the prosthetic device (supporting the socket) with respect to its lower part (connected to the leg), as is known.

The prosthetic knee assembly50is provided with a quadriceps control device, denoted generally by numeral60inFIG. 3. The quadriceps control device60includes an elongated, elastic member62. The member62has a first end64affixed to an upper portion of the knee cap52at an anterior position. The first end64of the member62may be affixed to the knee cap52by any suitable means, such as mechanical fasteners of any type or adhesives.

As further illustrated inFIG. 3, the member62has a second end66affixed to the knee frame54at an anterior position below the axis of rotation of the knee. The second end66of the member62may be affixed to the knee frame54by any suitable means, such as mechanical fasteners of any type or adhesives. In the preferred embodiment illustrated, the second end66of the member62is affixed to the knee frame54by a means68which provides for ready adjustment of the attachment point along the length of the member62, thereby providing adjustability for the amount of tension applied to the elastic member62. Adjustment means may be provided for the point at which the first end64of the member62is affixed, or at both ends of the member62. Any known means of adjustment may be utilized, such as a belt-like attachment.

The member62may be formed of any elastic material of sufficient elasticity and durability. The member62is preferably formed of a rubber-like material, such as neoprene. The member62may also be formed of various cross-sectional shapes, thicknesses and widths. The member62is preferably formed with a rectangular cross-sectional shape with a width significantly greater than its thickness, so that it lies relatively flat against the components of the prosthetic knee assembly.

The extension aid60operates in a similar manner to the embodiment shown inFIGS. 1 and 2. When the leg assembly is then moved from a position of flexure back to a position of extension, the energy stored in the elastic member62is released. The member62thereby aids the user with extension of the knee.

Referring now toFIG. 4, a further embodiment of the quadriceps control device of the invention is illustrated. In this embodiment, the quadriceps control device70comprises a plurality of elongated, elastic members72,74,76and78. Each of these members is secured in the manner described above for the other embodiments. These members all have a first end affixed to the prosthetic leg assembly above the knee and second ends affixed below the knee. The members may all have their lateral movement restrained by guide79. The members are preferably adjustable, and it may be preferable to adjust members so that different levels of tension are provided in various ones of the members.

The members72,74,76and78may be formed of any elastic material of sufficient elasticity and durability. The members are preferably formed of a rubber-like material, such as neoprene, but it may be advantages to form the various members of different materials. The members may also be formed of various cross-sectional shapes, thicknesses and widths, and it may be advantageous to form different members with different cross-sectional shapes, thicknesses and widths. The members are preferably formed with a rectangular cross-sectional shape with a width significantly greater than its thickness, so that they lie relatively flat. The various members may be arranged one relative to the others in various ways, but are preferably arranged to lie one over top of the other.

In another embodiment, illustrated inFIG. 5, a quadriceps control device is used in connection with a below the knee prosthetic leg assembly. As illustrated, a residual limb transtibial socket80is connected to a pylon82that is in turn connected to an artificial foot84in the conventional manner. The transtibial socket80is connected to a thigh corset86by a metal frame structure88having a pair of hinges90intended to generally align with the axis of rotation of the user's anatomical knee.

In this application, a quadriceps control device92is provided that includes an elongated, elastic member94attached to the assembly; a first end96attached above the knee to the thigh corset86and a second end98attached below the knee. The member94is preferably adjustable as to the amount of tension applied thereto, for instance by the belt-type fastener100shown. A guide102affixed to the socket80operates as in the other embodiments to prevent undue lateral movement of the member94. The invention would thus enhance and facilitate the wearer of the below the knee prosthetic leg assembly with knee extension.

In a further embodiment, illustrated inFIG. 6, the invention is applied to an orthotic, such as the plastic and metal knee brace illustrated and denoted generally by the numeral110. As shown, the orthotic leg assembly110includes a thigh corset112and a rigid plastic lower limb brace114, typically interconnected by a metal frame structure116having a pair of hinges118intended to generally align with the axis of rotation of the user's anatomical knee.

In this application, the quadriceps control device120again includes an elongated, elastic member122attached to the orthotic; a first end124attached above the knee to the thigh corset112and a second end126attached below the knee. The member112is preferably be adjustable as to the amount of tension applied thereto, for instance by the belt-type fastener128shown. The invention would thus enhance and facilitate the wearer of the orthotic with knee extension in cases of, as examples, muscle weakness, nerve damage, or debilitating diseases.

In accordance with the provisions of the patent statutes, the invention has been described in what is considered to represent its preferred embodiments. However, it should be noted that the invention could be practiced otherwise than as specifically illustrated and described without departing from its spirit or scope.