DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0032] The terms “bone cement” and “bone glue” are used interchangeably herein when describing the surgical procedures of the present invention. The term “tendon” as used herein is defined to include both tendons and ligaments. The bone-tendon-bone ACL reconstruction surgical procedures of the present invention are initiated by first providing a bone-tendon-bone graft. Also, depending upon the particular circumstances surrounding an individual patient and the particular injury, a bone-tendon graft could also be used having a single bone plug. As seen in FIG. 1 , knee joint 10 consisting of a tibia 20 , femur 40 , and a patella 60 having patella tendon 80 is illustrated. An autologous bone-tendon-bone graft 100 useful in the procedure of the present invention is illustrated in FIGS. 1 and 2 . The graft 100 is harvested in a conventional manner. The graft 100 is seen to have tendon section 110 having proximal end 112 and distal end 114 . The femoral bone plug 120 is seen to be cut out from the patella 60 . The bone plug 120 is seen to have outer surface 125 , proximal end 130 connected to the distal end 114 of tendon section 110 and distal end 135 . The tibia bone plug 140 is seen to be cut from tibia 20 , and is seen to have distal end 145 connected to the proximal end 112 of tendon 110 . The bone plug 140 is also seen to have outer surface 150 and distal end 155 . Suture 160 is seen to be inserted through tunnel 165 .

[0033] After the bone-tendon-bone graft 100 has been harvested, as seen in FIG. 2 , it is maintained in a moist condition prior to implantation in a conventional manner. Next, the patient's knee is prepared to receive the graft 100 by drilling tunnels into the femur and tibia as seen in FIG. 3A . A substantially longitudinal bone tunnel 200 is drilled into the tibia 20 in a conventional manner using conventional surgical equipment. The bone tunnel 200 is seen to have longitudinal passage 205 and longitudinal axis 206 . Bone tunnel 200 is additionally seen to have first opening 210 and second opening 220 , both openings which are in communication with passage 205 . In addition, tibial bone tunnel 200 is seen to have interior surface 225 . The femoral bone tunnel 250 is also drilled into the femur using conventional surgical equipment and techniques. The femoral tunnel 250 is seen to have opening 260 , longitudinal passage 255 and longitudinal axis 256 . The femoral bone tunnel 250 is also seen to have distal end 270 and inner surface 265 . Longitudinal axis 256 is seen to be in substantial alignment with longitudinal axis 206 . Next, the suture tunnel 280 is drilled into the femur such that the suture tunnel 280 is substantially in longitudinal alignment with the longitudinal axis 256 of the femoral bore hole 250 . Suture tunnel 280 is seen to have interior passage 286 . In addition, tunnel 280 is seen to have first opening 282 and second opening 284 such that the inner passage of tunnel 280 is in communication with the inner passage 255 of femoral bore hole 250 through opening 282 and also in communication with the exterior of the femur 40 through opening 284 . The glue tunnel 300 is seen to be substantially transverse to longitudinal axis 256 of femoral tunnel 250 in a preferred embodiment, but may, if desired, be angulated. Glue tunnel 300 is seen to have interior passage 305 in communication with passage 255 through first opening 307 , and in communication with the exterior of femur 40 through second opening 308 .

[0034] The tunnels 200 , 250 , and 280 are drilled in a conventional manner using conventional surgical orthopedic drilling equipment. Initially, the surgeon aligns the tibia and femur into the desired position for the procedure. Next, the distal end 355 of pilot pin drill 350 is placed against the outer surface of the tibia and a pilot bone hole is drilled through the tibia and femur by rotating drill 350 with a conventional surgical drill apparatus, until the end 355 exits the femur from opening 284 thus creating tunnel 280 , and the pilot bone hole precursors for tunnels 200 and 250 . Tunnels 200 and 250 are further formed by drilling with a conventional concentric surgical drill 370 (not shown) having drilling end 375 and inner passage 372 , which is mounted over pilot pin drill 350 in a conventional manner. After the drilling of tunnels 200 , 250 and 280 has been successfully completed, the pilot pin drill 350 and concentric drill 370 are withdrawn from the tunnels.

[0035] Next, the transverse glue tunnel 300 is drilled into the femur. Specifically, as seen in FIGS. 3 B-E, the conventional L-shaped drill guide 400 is used to locate and align the transverse tunnel 300 . Drill guide 400 is seen to have first and second legs 410 and 430 . At the end 412 of leg 410 is located the base receiver 415 . Extending up from base receiver 415 is the locating leg 420 having proximal end 422 , and distal end 424 . If desired, although optional, drills and other instruments can be inserted through base receiver 415 into and through locating leg 420 by providing appropriate openings and passageways. Leg 430 is seen to have end 432 and drill receiver 435 mounted thereto, having first opening 436 , second opening 437 and internal passageway 439 in communication with both openings. Locating leg 420 is seen to be mounted in tibial bone hole 200 .

[0036] Then, cannula 450 having drill 390 with distal drilling end 395 located therein, is inserted into and through opening 432 of drill guide 400 , and the drill 390 is rotated by a conventional surgical drill to drill out glue tunnel 300 and place cannula 450 in tunnel 280 . Cannula 450 is seen to have internal passage 452 , proximal end opening 454 in communication with passage 452 and distal end opening 456 in communication with passage 452 . After the tunnel 300 is completely formed, drill 390 is removed and guide 400 is removed by removing retention bracket 490 secured by screw 492 and pulling out leg 420 from passage 200 , leaving cannula 450 in glue tunnel 280 . Although not preferred, the method of the present invention can be performed without the use of cannula 450 . Also, if desired, cannula 450 may be placed into the tunnel 280 subsequent to drilling.

[0037] Referring now to FIGS. 4 - 9 , after the bone tunnels 200 and 250 , the suture tunnel 280 , and glue tunnel 300 have been drilled, the longitudinal axes 206 and 256 , respectively, of the bone tunnel 200 and bone tunnel 250 are placed in alignment by the surgeon. Next, the conventional suture 160 mounted to the femoral bone plug 120 is threaded through the interior passages of 205 and 255 of the tibial tunnel 200 and the femoral tunnel 250 , respectively, and is further threaded through and out of the suture tunnel 280 . Next, the surgeon pulls the suture 160 such that the femoral plug passes into passage 255 of the femoral tunnel 250 and the tibia plug passes into passage 205 of the tibia tunnel 200 .

[0038] The surgeon is careful to locate the distal end 135 of the femoral bone plug 120 immediately below the opening 307 . At this time, the tibial bone plug 150 is either partially or completely located in bone tunnel 200 . Next, the surgeon injects a bone glue or bone cement into the cannula 450 using a conventional syringe 500 such that a bolus of the bone cement or bone glue 550 flows through the interior passage of cannula 450 , through the interior of glue tunnel 300 , and finally into the interior of bone tunnel 250 as seen in FIGS. 6, 7 and 8 . Syringe 500 is seen to have barrel 510 for receiving glue 550 plunger 520 and hollow needle 530 . The surgeon then removes the trocar 450 and syringe 500 from the glue tunnel 300 , next the surgeon pulls on the ends of suture 160 thereby pulling the bone plug 120 into position in the femoral bone tunnel 250 such that the distal end 135 or the bone plug 125 abuts the distal end 270 of the bone tunnel 250 . At the same time the glue 550 is spread in and about the inner surface 265 of the bone tunnel 250 and the outer surface 125 of the plug 120 thereby securing the bone plug in place upon the curing of bone glue or bone cement 550 . The suture 160 may then be removed from the femoral bone plug 120 , or the ends external to the femur may be cut. The tibial bone plug 140 can then be secured in the bone tunnel 200 in a conventional manner using, for example, bone screws or pins. Or, if desired, an additional transverse glue hole can also be drilled into the tibia in communication with tibial tunnel 200 , and bone glue or bone cement 550 may be similarly delivered by the surgeon into the bone tunnel 200 through the tibial glue tunnel. Although not preferred, the surgeon may inject a bolus of bone glue 550 into femoral bone tunnel 250 prior to locating the femoral bone plug 120 in tunnel 250 .

[0039] FIG. 10 illustrates and alternate embodiment of an ACL reconstruction method of the present invention. As seen in FIG. 10 , the method steps are similar to that of the previously described preferred method, except that the glue tunnel 300 is not drilled and utilized. Instead, the glue 550 is injected via syringe 500 through the suture tunnel 280 into the femoral bone tunnel 250 when the bone plug 120 is partially engaged in the bone tunnel 250 , or prior to inserting the bone plug 120 into femoral bone tunnel 250 .

[0040] Yet another embodiment of the ACL reconstruction method of the present invention is illustrated in FIGS. 11 A-B. In FIGS. 11 A-B, the method steps are similar to that of the method steps of the preferred embodiment of the present invention. However, rather than drilling a transverse bone tunnel or injecting bone glue or cement through the suture tunnel, a frangible capsule 600 containing bone glue or bone cement 550 is inserted into the femoral tunnel 250 prior to introducing the plug 120 into the tunnel 250 . Then the surgeon pulls the suture threads 60 upwardly such that the distal end of the bone plug engages the frangible capsule 600 thereby breaking open the shell 610 of capsule 600 and causing glue 550 contained in the interior 620 of capsule 600 to be spread about the inner surface 265 of the bone tunnel 250 and the outer surface 125 of the plug 120 .

[0041] The methods of the present invention preferably will utilize bone plugs and tendons and ligaments harvested from autologous tissue in the patient's knee or other areas of the body as illustrated in FIGS. 1 and 2 using conventional surgical techniques. However, if desired, artificial bone plugs and tendons may be utilized. The bone plugs may consist of conventional bone substitute materials including polylactic acid and polyglycolic acid as well as bioceramics such as tricalcium phosphate, calcium phosphate, tetracalcium phosphate and hydroxyapatite, and any copolymers, mixtures or blends thereof, and the like and equivalents thereof. The artificial tendons or ligaments can consist of conventional tendon replacement materials including carbon fibers, polyethylene terephthalate, polytetrafluoroethylene (PTFE), polypropylene, as well as biodegradable polymers including polylactic acid, polyglycolic acid, polydioxanone, polycarbonate, polycaprolactone, and copolymers thereof, and the like, and combinations thereof and equivalents thereof.

[0042] The amount of glue or cement used to secure the bone plugs in the bone tunnels in the method of the present invention will be sufficient to effectively maintain the bone plugs in place after curing and setting. The amount that is used will depend upon several factors including the characteristics and nature of the bone plug, the nature and characteristics of the bone cement or glue, the size and length of the bone tunnels, the nature and characteristics of the bone glue or cement and the individual characteristics of the patient.

[0043] The term “adhesive” is used collectively herein to include bone glues and bone cements. The bone glues which can be used in the practice of the present invention include conventional biocompatible bone glues including 2-octyl cyanoacrylate and the like and equivalent thereof. The bone cements which can be used in the practice of the present invention include conventional biocompatible bone cements such as polymethylmethacrylate and the like. The bone glues and bone cements may be absorbable or nonabsorbable.

[0044] The frangible capsules 600 useful in the practice of the embodiment of the method of the present invention will typically have a hollow body having a shell 610 and interior 620 . The interior 620 of the shell 610 will be filled with bone cement or bone glue 550 . The shell will typically be made out of biocompatible material which is frangible and will break or rupture when squeezed or compressed. Examples of such shell materials include gelatin, and conventional bioabsorbable and bioresorbable polymeric materials, and the like.

[0045] The following example is representative of the principles and practice of the present invention although not limited thereto.

EXAMPLE

[0046] A patient was anesthetized in accordance with conventional anesthesiology procedures. The patient's knee joint was prepared for an ACL reconstruction in a conventional manner. Incisions were made into the knee exposing the lower part of the femur, the upper part of the tibia, the tibial tendon and the patellar tendon. A bone-plug-tendon-bone-plug bone graft was harvested from the patellar bone, the tibial tendon and the tibia. Then, a conventional pilot pin wire drill was utilized to drill a bone tunnel through the tibia into and out of the femur thereby creating the suture tunnel and precursor tibial and femoral bone tunnels. Next, a conventional concentric drill was placed over the drill/guide wire and the drill was operated in a conventional manner to create the tibial tunnel and the femoral bone tunnel. The drills were then removed. Then, a conventional drill guide was mounted on the patient's tibia and femur. Next, a transverse glue tunnel was drilled into the femur utilizing the drill guide and a conventional trocar drill and cannula, the tunnel intersecting the femoral bone tunnel such that the interior passage of the femoral bone tunnel was in communication with the transverse glue tunnel. After removing the drill, the cannula was left in place in the glue tunnel. Next, the surgeon prepared the bone tendon, bone graft by drilling a transverse hole through the femoral plug and inserting a length of conventional Ethibond® surgical suture therethrough. Next, the surgical suture was threaded through the tibial tunnel, the femoral tunnel and through and out of the suture tunnel so that both ends of the suture were exterior to the femur. Next, the surgeon proceeded to pull the bone-tendon-bone graft through the tibial tunnel and further into the femoral tunnel such that the distal end face of the femoral bone plug was located just proximal to the opening into the glue tunnel. Next, the surgeon mounted a the needle of conventional syringe containing about 40 cc of 2-octyl cyanoacrylate bone glue into the trocar cannula, and a bolus of the bone cement was injected through the cannula into the femoral bone tunnel, and the cannula was removed. Next, the surgeon continued to pull on the ends of the suture such that the distal face of the bone plug was in contact with the distal end of the femoral tunnel, effectively spreading the bolus of bone glue about the interior surfaces of the femoral bone tunnel and also over the exterior surfaces of the femoral bone plug such that the bone plug was effectively bonded to the interior surfaces of the bone tunnel by the bone glue. After waiting a sufficient period of time for the bone glue to cure, the surgeon cut off the ends of the suture, and the incisions were then approximated in a conventional manner utilizing conventional surgical sutures. Next, the surgeon secured the tibial plug to the tibial bone hole in a conventional manner utilizing a conventional bone screw. The patient's knee was then immobilized, and the ACL reconstruction was completed.

[0047] The advantages of the improved ACL reconstruction methods of the present invention are numerous. It is now possible to perform an ACL reconstruction without having to use mechanical fasteners to maintain a femoral bone plug in place. In addition, the length of the surgical procedure can be reduced since it not necessary to drill additional bone tunnels to receive mechanical fasteners such as screws and pins.

[0048] Although this invention has been shown and described with respect to detailed embodiments thereof, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the spirit and scope of the claimed invention.