1. Field of the Invention
This invention relates to surgical devices for the repair and reconstruction of soft tissue injuries. In particular, this invention relates to devices and methods for the surgical implantation of artificial ligament grafts. Still more particularly, the invention relates to the surgical repair of torn anterior cruciate ligament grafts.
2. Description of the Prior Art
The repair and reconstruction of torn or damaged soft tissues is a common surgical procedure. For example, replacement graft ligaments may be secured at the site of the original ligament. The procedure generally involves drilling bone tunnels into adjacent bones at the site of the original ligament and securing a graft ligament within these bone tunnels. In many applications, such as in the knee joint, such procedures may be performed arthroscopically. The graft ligament may be an autograft, an allograft, a xenograft, and/or it may be totally artificial and synthetic. The most common types of anterior cruciate ligament (ACL) grafts, for example, include ones which may be bone-patellar-tendon-bone or soft tissue (such as semitendinosus and gracilis tendons), both types harvested by techniques well known to those skilled in the art.
The graft ligaments are secured within the bone tunnels in a variety of ways. Of prime importance is the degree to which they can withstand pullout forces prior to complete healing. For example, it is known to use interference screws inserted parallel to the tunnel axis to compress the ends of the graft ligament against the walls of the bone tunnel to secure the graft ligament and promote tissue in-growth.
Suspensory graft fixation devices have been developed to secure a graft ligament in a bone tunnel. One such device is described in U.S. patent application Ser. No. 11/804,195, filed May 17, 2007, entitled Graft Fixation Implant, assigned to the assignee hereof and incorporated by reference herein. Suspensory graft fixation devices work with a bone tunnel and generally take the form of an elongated member having an axis and a pair of suture receiving apertures symmetrically situated on the axis on opposite sides of the longitudinal center of the elongated member. In ACL procedures the elongated member, often called a button, is adapted to be situated transversely to the exit opening of the bone tunnel on the lateral cortex so that a suture loop suspended from the button can extend into the bone tunnel from the suture receiving apertures and support one end of a graft ligament passed through the loop. In arthroscopic procedures such as ACL reconstruction the elongated member supports a graft ligament and is rotated into alignment with the previously formed bone tunnel in order to enable it to be inserted into the proximal opening of the bone tunnel and to exit at the distal end on the lateral femur. For such suspensory graft fixation devices to be able to support a graft ligament and to be properly transversely situated at the exit of the bone tunnel, the suture loop and the bone tunnel must both be long enough to enable the elongated member to “flip” from an axially aligned orientation to a transverse orientation when it exits the bone tunnel.
Since the supporting loop of such a suspensory device is most often of a fixed length, graft fixation requires preparation of a graft ligament of predetermined length. Furthermore, because prior art suspensory graft fixation devices have fixed loop lengths they are produced in multiple sizes (ranging, for example, from loop lengths of 15 mm to 60 mm in 5 mm increments in the case of XO Button™ implants made by ConMed Linvatec, Largo, Fla.) in order to accommodate various graft and tunnel lengths that may be encountered during a surgical procedure. The fixed graft length and variation in tunnel and loop lengths makes prior art suspensory ligament fixation challenging.
Recently, suspensory devices have been made with adjustable loop lengths as taught by U.S. patent application 2010/0256677, (Albertorio et al.) published Oct. 7, 2010 and entitled Integrated Adjustable Button-Suture-Graft Construct with Two Fixation Devices. It has been found that the adjustability of the loop length of a suspensory graft fixation device may be achieved in a manner considerably less complex than that described in the aforementioned publication.
At times surgeons may encounter situations where they cannot produce a bone tunnel of adequate length to receive a ligament graft suitable for suspensory fixation. A predetermined length of graft ligament is required to engage the bone tunnel for proper healing. For example, a so-called short tunnel ACL reconstruction may present a relatively small (narrow) femur which does not enable formation of an adequately long bone tunnel which means, in turn, the suspensory anchor member cannot be advanced far enough out of the tunnel to flip. Use of an adjustable loop in such situations could nevertheless enable the surgeon to proceed with a suspensory-type repair. Accordingly it is an object of this invention to produce a suspensory graft ligament repair system suitable for short tunnel repairs.
These and other objects of this invention are achieved by a suspensory graft fixation device for securing a ligament graft in a bone tunnel comprising an elongated anchor member adapted to be situated transversely adjacent the exit of the bone tunnel, a graft supporting element adapted to support the ligament graft a predetermined variable distance away from the exit, and a pulley-type means for adjusting the distance.
In one aspect of the invention the graft supporting element comprises a plurality of loops formed from a single wound strand of filamentous material having two ends movable relative to each other.
Another aspect of the invention is the method comprising the steps of providing a suspensory graft fixation device as described above and pulling at least one end of the filamentous material in order to shorten the loop length.
A suspensory graft fixation device 10 constructed in accordance with the principles of this invention is shown in
Unique features of device 10 are its pulley-type characteristics, one of which is its ability to enable the adjustability of loop length 50 by simply pulling distally on one or both ends of suture 34. This is done by a system which operates in a way analogous to a plurality of pulleys. Not only does the system enable adjustable loop lengths, it also provides a mechanical advantage so that less force is needed to pull the graft into the tunnel than is used to hold the graft in place. This structure serves to shorten the loop length L while simultaneously presenting a large graft fixation force due to another pulley-type characteristic. By way of explanation, the theoretical mechanical advantage of the system shown here is the ratio of the force delivered by the system to the force put into it (ignoring friction). In the case of the suspensory device described herein the force delivered is the holding force FG supporting the graft during use (the force exerted by the graft proximally on the interior side of loop member 30). That is, the holding force FG pulling proximally on the saddle end of the suture loop. The force input into the system is FG/4 (in the preferred embodiment with two complete loops and four strands passing between the ends of the loop member), the force required to pull distally to shorten the loop length L. The number of loops passing over bridge 24 is analogous to the number of pulleys. As a result of the pulley analogy there is a mechanical advantage created whereby the pulling force FG/4 exerted on the suture ends 36, 38 at the distal end of the loop is multiplied at the proximal end of the loop where the graft ligament is situated.
In the preferred embodiment as best seen in
An additional advantage of this invention is its ability to provide graft fixation in bone tunnels shorter than those required for prior art suspensory graft repairs. This invention is particularly useful for suspensory type repairs of the ACL or PCL in situations where the bone tunnel length is relatively short. For example, to perform an ACL surgery using a conventional transverse button on the lateral femoral surface, the surgeon must drill a trans-femoral tunnel comprising a proximal graft receiving portion and a smaller distal portion opening at the bone tunnel exit onto the lateral femoral cortex. The surgeon must then precisely measure the overall tunnel length and determine the graft tunnel-contact length desired as well as the loop length required to achieve the desired contact between the tunnel and the graft. The surgeon then calculates the drilling length of the graft tunnel socket by selecting the length of graft desired to remain in the tunnel and, in the case of a button with a continuous (i.e., endless) loop, adding the distance needed to deploy (i.e., flip) the button. The reason the added distance is necessary is because the button must completely exit the aperture prior to toggling perpendicular to the exit hole. A typical example of this would be an overall trans-femoral tunnel length of 45 mm where 20 mm of graft is desired to remain in the tunnel and 15 mm is needed to deploy the device. In this case the surgeon would drill the femoral socket 35 mm deep. Once the procedure is completed there will be excess space present between the femoral socket floor and the distal end of the graft. At this point, if one were using conventional techniques and devices the graft is in its final position. On the other hand, as will be understood below, use of the subject invention enables the advantageous elimination of this excess space and the maximization of graft contact with the bone tunnel wall where short trans-femoral tunnels are desired or encountered.
In particular, the method of ACL repair using the subject invention does not require extra tunnel length to allow the button to turn. The invention allows the loop to be sufficiently long so that the button may be passed through the femoral tunnel and deployed on the surface of the bone. The loop length can be made long enough to enable it to be accessible from inside the joint but outside the femoral tunnel so that the graft retaining loop 31 may be engaged by the graft ligament (folded about loop 31) even after the button has been flipped. The graft ligament, thus supported directly by the plurality of loops 32, is then pulled into the bone tunnel by pulling the suture ends 36 and 38 distally and with relatively little effort as loop length 50 is shortened. The graft may be pulled into the tunnel until it contacts the socket floor. The optional flexible sleeve 40 could be used to protect the graft from abrasion as well as to keep the individual loops 31 together. Once the graft is in the correct position an optional knot may be tied over the button to complete the repair to ensure fixation.
While anchor member 12 is shown as a single, unitary member with apertures 20 and 22 having unbroken perimeters, alternate structures could be utilized. For example, anchor 12 could have any shape and apertures 20, 22 could each have a passage through their perimeters. While the preferred embodiment described herein was formed with two complete turns of suture through apertures 20 and 22, it will be understood that any number of individual loops 31 could be used between zero and any greater number. If one chose not to have any loop at all, the device would have no mechanical advantage but would still function in a short tunnel situation (although the suture ends would clearly need to be tied to complete the procedure). If one chose too many loops, friction between the adjacent suture strands might limit the mechanical advantage.
It will be understood by those skilled in the art that numerous improvements and modifications may be made to the preferred embodiment of the invention disclosed herein without departing from the spirit and scope thereof.
This application claims the benefit of pending prior U.S. Provisional Patent Application Ser. No. 61/455,897, filed Oct. 28, 2010 by Peter C. Miller et al. for Adjustable Loop for Short Tunnel ACL.
Number | Date | Country | |
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61455897 | Oct 2010 | US |