Arthroscopic Reconstruction of the Posterior Cruciate Ligament Using Tibial-Inlay and Double-Bundle Technique

Biomechanical research has suggested that the double-bundle and tibial inlay technique is superior to the single-bundle and the transtibial tunnel method for posterior cruciate ligament (PCL) reconstruction. A combination the posterior tibial inlay and femoral double-bundle technique is thought to be an ideal method for PCL reconstruction. Recently, we successfully performed arthroscopic PCL reconstruction using the tibial-inlay and double-bundle technique. Achilles tendon–bone allograft is used and the bone plug for the arthroscopic tibial inlay fixation is designed in a cylindrical shape and perpendicular to the fiber texture of the Achilles tendon. Achilles tendon is manually split into deep and superficial layers to reconstruct anterolateral and posteromedial bundles as the natural insertion of PCL. The intra-articular lengths of each bundle between tibial tunnel and 2 femoral tunnels are measured to achieve fixation of the graft to the original PCL attachment. After tibial bone plug fixation with an absorbable interference screw and additional suture anchoring, the anterolateral bundle is fixed in a reduction position with the knee in 90° of flexion and the posteromedial bundle is fixed nearly in extension. This procedure makes it possible not only to reproduce the original concept of PCL tibial inlay graft arthroscopically without posterior arthrotomy, but also to achieve a more anatomic PCL reconstruction of the 2 bundles.     

后交叉韧带胫骨止点与双束重建胫骨骨道定位的临床解剖学研究

目的 解剖研究后交叉韧带(PCL)胫骨止点情况,确定PCL前外侧束(ALB)与后内侧束(PMB)胫骨止点的位置、形状与面积,探讨PCL双束四骨道重建中胫骨骨道定位标志与定位方法.方法 30例成人膝关节标本,根据屈伸膝关节过程中纤维束紧张与松弛情况,将PCL分为ALB与PMB,并确定各束中的功能束,用多种指标测量ALB、PMB与功能束的胫骨止点,解剖寻找双束四骨道重建PCL中胫骨骨道定位标志与定位方法.结果 PCL胫骨止点位于后髁间窝内,其纵轴由近内斜向远外,与胫骨干夹角平均为(16.5±1.4)°.ALB与PMB胫骨止点基本呈远近排列,ALB胫骨止点接近于菱形,平均面积为(90±20)mm2,PMB胫骨止点近似长方形,平均面积(96±32)mm2,二者无显著差异(P>0.05).ALB与PMB中均存在功能束,分别止于ALB胫骨止点的远外侧部及PMB胫骨止点的远内侧部,均接近椭圆形,面积分别为(35±12)mm2与(36±6)mm2,二者无显著差异(P>0.05).ALB功能束胫骨止点中心与PMB功能束胫骨止点中心距离为(12.7 ±1.9)mm.胫骨内、外侧髁间棘及胫骨上端后方骨嵴为重要的解剖标志.结论 PCL胫骨止点可以容纳两个胫骨骨道,PCL的ALB与PMB中均存在功能束,提示临床双束四骨道重建PCL时,胫骨骨道应分别定位于ALB与PMB功能束胫骨止点处.     

Trantibial anterior cruciate ligament double bundle reconstruction technique: two tibial bundle in one tibial tunnel

The anterior cruciate ligament (ACL) consists of two functional bundles that behave independently throughout the range of knee motion. Many two-bundle reconstruction techniques have been introduced to restore the function of the two bundles of the ACL. Generally, two femoral and two tibial tunnels are made during the surgery for a two-bundle ACL reconstruction. However, the procedure is technically demanding and time consuming. This paper describes one-tibial-two-femoral ACL double bundle reconstruction technique with a sextuple-stranded hamstring autograft. The anteromedial femoral tunnel is made using transtibial drilling technique and posterolateral femoral tunnel is made using outside-in technique. The two bundles in a single tibial tunnel are separated using biodegradable interference screw. Stable and adequate femoral fixation of the two bundles with a transtibial fixation and bioabsorbable screw can be obtained. This technique is relatively simple, and replicates the anatomy and differential behavior of the two native bundles of ACL more effectively.     

股骨单隧道内分叉双束纤维重建后交叉韧带的实验研究

目的在人膝关节标本上行股骨单隧道分叉双束纤维重建后交叉韧带(posterior cruciate ligament,PCL),探讨其术式的优缺点。方法应用力学试验机对14侧捐赠新鲜冷冻人膝关节标本进行生物力学测试,男12侧,女2侧;年龄20～31岁。标本股骨段长20cm,胫骨段长20cm。首先测量PCL完整时胫骨后移距离和交叉韧带的应变(完整组,n=14);然后切断PCL(切断组,n=14),测量胫骨受力时的后移距离后,再将标本随机分为两组:单束重建组(n=7)和分叉双束重建组(n=7),分别测量屈膝0、30、60、90和120°5个角度时胫骨后移距离和移植韧带的应变。结果胫骨受到100N后向力量,完整组在不同屈膝角度下,胫骨向后移位1.97±0.29～2.60±0.23mm,前外束和后内束纤维交替紧张松弛。切断组膝关节明显松弛,胫骨向后移位达11.27±1.06～14.94±0.67mm,与完整组比较差异有统计学意义(P<0.05);单束纤维重建组,在不同屈膝角度下胫骨向后移位1.99±0.19～2.72±0.38mm,移植韧带持续紧张。双束纤维重建组在不同屈膝角度下胫骨向后移位2.27±0.32～3.05±0.44mm,移植的双束纤维交替紧张,协同作用。组内比较:双束重建组在不同屈膝角度时胫骨向后位移差异无统计学意义(P>0.05),而单束重建组在屈膝90°时与屈膝30、60和120°时相比,胫骨后移增大,差异有统计学意义(P<0.05)。结论股骨单隧道内分叉双束纤维重建PCL术在各屈膝角度均能有效防止胫骨后移,股骨单隧道单束重建术屈膝90°时后移较其他角度时增大。分叉双束重建PCL的两束纤维束交替紧张,生物力学特征更接近于正常PCL。     

Arthroscopic-assisted simultaneous reconstruction of the posterior cruciate ligament and the lateral collateral ligament using hamstrings and absorbable screws

Arthroscopic-assisted simultaneous reconstruction of the posterior cruciate ligament (PCL) and the lateral collateral ligament (LCL) using hamstring tendon grafts is described. The femoral tunnel is drilled through an incision over the medial femoral condyle and the tibial tunnel through the same skin incision used for harvesting the tendon graft. PCL reconstruction is performed using a 4-strand hamstring tendon graft and absorbable screw fixation. The tendon of the semitendinosus muscle of the uninvolved knee is used as a lateral loop for LCL reconstruction. After pulling the transplant through the fibular head, femoral fixation of the loop is made with an absorbable screw.Arthroscopy: The Journal of Arthroscopic and Related Surgery, Vol 17, No 8 (October), 2001: pp 892–897     

The effectiveness of skeletal imaging for quality assessment in posterior cruciate ligament reconstruction: reliability and validity of radiographs and computed tomography

Purpose

For intra- and postoperative evaluation of precise and anatomic graft tunnel position, radiographs (XR) and computed tomography (CT) scans have been suggested. The purpose of this study was to evaluate the reliability and validity of XR and CT for quality assessment following PCL reconstruction.

Methods

Postoperative radiographs and CT scans were obtained in 45 consecutive patients following a standard single-bundle PCL reconstruction. Femoral and tibial tunnel apertures were correlated to femoral and tibial measurement grid systems. To assess the reliability and validity of XR and CT scans three independent observers evaluated radiographic and CT images for the position of femoral and tibial tunnel apertures.

Results

Almost perfect inter- and intra observer agreement (0.79–0.99) was found for all CT measurements except for the distance of the tunnel position to the previous physis line. Almost perfect and strong inter- and intraobserver agreement (0.70–0.98) was found for all tibial measurements on XR which tended to increase with repeated interpretation and to decrease with low levels of observer qualification. Femoral measurements yielded only poor-to-moderate reliability (0.02–0.5) between raters on XR but strong intraagreement within experienced observers (0.45–0.86). Specificity for XR was calculated with 75.7 % for P2 and P3 and with 71 % for femoral tunnel depth and height.

Conclusion

XR and CT represent complementary imaging modalities and both offer considerable accuracy and precision for the determination of femoral and tibial tunnel apertures following PCL reconstruction and can be recommended for intra- and postoperative quality assessment.     

Anatomic Double Bundle: A New Concept in Anterior Cruciate Ligament Reconstruction Using the Quadriceps Tendon

Surgical procedures for double-bundle anterior cruciate ligament reconstruction, which currently use hamstring graft, have been described, but some concerns remain regarding graft fixation and the ability to obtain adequate bundle size. We report an original double-bundle anterior cruciate ligament reconstruction technique using a quadriceps tendon graft and a simplified outside-in femoral tunnel–drilling process. The graft consists of a patellar bone block with its attached tendon split into superior and inferior portions, which yields 2 bundles. The anteromedial tunnel is drilled from the outside through a small lateral incision by use of a guide. The posterolateral tunnel is made through the same incision with a specific guide engaged in the anteromedial tunnel. A single tibial tunnel is created. The graft is routed from the tibia to the femur with the bone block in the tibial tunnel and the 2 bundles in their respective femoral tunnels. After fixation of the bone block in the tibia, the 2 bundles are tensioned and secured separately in their femoral tunnels.     

异体胫前肌Y型双束双隧道移植重建后交叉韧带的临床研究

目的探讨异体胫前肌Y型双束双隧道重建后交叉韧带（PCL）的临床效果及手术技术改进的方法。方法自2001年3月至2008年1月，采用成人异体胫前肌编制成“Y”型双束，长度为130mm，A端为长束（A束），B端为两短束（B1、B2束）。韧带安装时两端均从膝前内侧工作通道的切口进入，即：外（膝前内侧工作通道）→内（股骨、胫骨隧道内口）→外（股骨、胫骨隧道外口）。可吸收界面钉先固定胫骨隧道侧，然后再固定股骨侧：固定前外侧束时屈膝90°，固定后内侧束时屈膝30°。术后予膝关节角度锁定助行器辅助锻炼8～10周，3个月后行走基本正常。结果本组47例患者均获得随访，平均随访49．5个月，平均手术时间（45±15）min。Lachmann后向试验术前均阳性，术后38例阴性、5例弱阳性、4例阳性。KT-1000试验术前（9．0±4．0）mm，术后（3．0±1．5）mm，差异有统计学意义（t=3．12，P〈0．01）；Lysholm评分术前（51．4±5．2）分，术后（93．3±4．1）分，差异有统计学意义（t=3．13，P〈0．01）；Tegner活动水平术后（6．9±1．3）分，术前（3．5±0．7）分，差异有统计学意义（t=3．12，P〈0．01）。结论异体胫前肌编制双束有足够的长度和直径重建PCL，其抗拉力强；改进后的韧带过隧道方法，韧带通过隧道时顺畅，简单易操作，省时；准确的隧道内口、正常的张力（角度）固定是效果的保证；动静结合的早期功能锻炼有利于早期功能恢复。     

Research into tibial tunnel location in reconstruction of posterior cruciate ligament北大核心CSCD

Posterior cruciate ligament (PCL) injury is common in sports medicine. Arthroscopic reconstruction of PCL has become a routine procedure to stabilize the knee joint after PCL injury. The location of tibial tunnel during operation is crucial to a successful surgery. This article reviews the current studies on transtibial PCL reconstruction from the aspects of the anatomy related to the tibial tunnel, the anteromedial and anterolateral tibial tunnels, the maximum angle and optimal angle of tibial tunnel, and the anatomical and non-anatomical tibial tunnels, hoping to provide helpful references for the treatment of PCL injury. © 2023 Chinese Journal of Orthopaedic Trauma. All rights reserved.     

Anatomically Oriented Anterior Cruciate Ligament Reconstruction with a Bone–Patellar Tendon–Bone Graft via Rectangular Socket and Tunnel: A Snug-fit and Impingement-Free Grafting Technique

An anterior cruciate ligament (ACL) reconstruction technique is described to place bone–patellar tendon–bone (BPTB) graft in an anatomically oriented fashion to mimic the 2 bundles of the normal ACL, based on the concept of twin tunnel ACL reconstruction, to maximize the graft-tunnel interface. In this technique, the attached bone plug is introduced into a rectangular femoral socket via a halfway rectangular tibial tunnel for the anterior portion of the graft to function as the anteromedial bundle and for its posterior portion to behave as the posterolateral bundle. A snug fitting of the graft is achieved not only at the femoral socket, but also in the tibial tunnel.     

Reducing the “killer turn” in posterior cruciate ligament reconstruction

Purpose: Graft abrasion caused by sharp graft angulation at the graft-tunnel margin of the proximal tibia (the “killer turn”) may cause graft failure after posterior cruciate ligament (PCL) reconstruction using the traditional anteromedial route tibial tunnel. One method to reduce the graft angulation is to use the anterolateral route tibial tunnel. However, less acute graft angulation may increase joint translation because of a decrease in graft compressive force. The purpose of this study was to compare the graft angulation and joint translation between anteromedial and anterolateral route tibial tunnels. Type of Study: Biomechanical study. Methods: Twelve above-the-knee amputation specimens were used in this study. Anteromedial and anterolateral tibial tunnels were made at the desired locations, and the same femoral tunnel was used. Graft angulation was measured by inserting a malleable pin into the tibial and femoral tunnels. Measurements of graft angulation were performed with the knee in extension and in 90° of flexion. The joint translation was measured by the posterior translation of the tibia on the femur at 90° of flexion with a 15-lb posterior force applied to the anterior proximal tibia after PCL reconstruction through the respective tunnels. Results: The difference in graft angulation between anterolateral and anteromedial route tibial tunnels was statistically significant (P < .001); however, the difference in joint translation showed no statistical significance between the 2 tunnel routes. Conclusions: The anterolateral route tibial tunnel significantly reduced the sharp graft angulation (“killer turn”) at the graft tunnel margin of the proximal tibia, but it did not increase the joint translation as compared with the traditional anteromedial route tibial tunnel. The anterolateral route tibial tunnel is thought to be a better choice when arthroscopic PCL reconstruction is performed with the tunnel technique.     

Technical Note: Double tibial tunnel using quadriceps tendon in anterior cruciate ligament reconstruction

Summary: To avoid complications related to the use of patellar tendon and hamstring (semitendinosus and gracilis) tendon and to create a more anatomic reconstruction, we present a new technique based on the use of quadriceps tendon placed in a single half femoral tunnel and double tibial tunnels. The graft, harvested by a central longitudinal incision, possesses the following characteristics: (1) a bone plug 20 mm long and 10 mm in diameter; (2) a tendon component 7 to 8 cm long, 10 mm wide, and 8 mm thick; and (3) division of the tendon longitudinally into 2 bundles while maintaining the patellar insertion. Every bundle has a width and thickness of approximately 5 mm and 8 mm, respectively. The total length of the graft is 9 to 10 cm. A 10-mm half femoral tunnel is drilled through a low anteromedial portal with the knee flexed at 120°. A suture loop is left in place in the half tunnel. A double tibial tunnel is drilled in a convergent manner (from outside to inside) obtaining an osseous bridge between the 2 tunnels. Two suture loops are passed trough the tibial tunnels and retrieved in a plastic cannula (10 mm) positioned in the anteromedial portal to allow the passage of the 2 bundles in the tibial tunnels. The suture loop left in the half tunnel permits the transportation of the bone plug in the femoral tunnel. Fixation is achieved by an interference screw at the femoral side and by 2 absorbable interference screws (1 for each tunnel). The advantages of this technique are a more cross-sectional area (80 mm²), greater bone-tendon interface, and a more anatomic reconstruction. Theoretically, easier bone incorporation, decreased windshield wiper and bungee effect, fewer donor site problems, and less tunnel enlargement can also be possible.     

Single–Achilles Allograft Posterior Cruciate Ligament and Medial Collateral Ligament Reconstruction: A Technique to Avoid Osseous Tunnel Intersection,Improve Construct Stiffness,and Save on Allograft Utilization

We present a method for single–Achilles allograft medial collateral ligament (MCL) and posterior cruciate ligament (PCL) reconstruction that eliminates the risk of tunnel intersection, stiffens the construct, and maximizes utilization of allograft tissue. An Achilles tendon allograft is prepared with an 11- to 12-mm bone plug with a gradual taper to 7 mm over approximately 15 cm. A transtibial PCL tunnel is created under fluoroscopic and arthroscopic guidance. The femoral tunnel is prepared in an “outside-in” fashion under direct arthroscopic visualization, originating at the anatomic origin of the MCL on the medial epicondyle and entering the joint at the anatomic origin of the anterolateral bundle of the PCL. The Achilles graft is pulled into the joint through the tibial tunnel and routed into the femoral tunnel so that the soft tissue exits at the medial epicondyle. The bone plug is fluoroscopically guided to the posterior aperture of the tibial tunnel and fixed with a bioabsorbable interference screw. The pretensioned graft is fixed in the femoral tunnel via interference screw fixation with the knee in 90° of flexion. The isometric position of the MCL insertion is identified with a K-wire isometer, and the graft is fixed in place at this point by use of an interference screw or screw and washer.     

Joint kinematics and in situ forces after single bundle PCL reconstruction: a graft placed at the center of the femoral attachment does not restore normal posterior laxity

Introduction: Femoral tunnel placement has a great influence on the clinical outcome after PCL reconstruction. Materials and methods: Using a robotic/universal force moment sensor (UFS) testing system, we examined joint kinematics and in situ forces of human knees following soft-tissue single bundle PCL reconstruction fixed at the center of the femoral attachment. Results: Posterior tibial translation significantly increased at all flexion angles after transsection of the posterior cruciate ligament (p<0.05). PCL reconstruction resulted in significantly less posterior tibial translation at all flexion angles when compared to the PCL deficient knee (p<0.05). The differences in the in situ force between the intact ligament and the reconstructed graft were statistical significant (p<0.05). Conclusion: Single bundle PCL reconstruction with a soft-tissue graft fixed at the center of the femoral attachment is able to reduce the posterior tibial translation significantly. However, it cannot restore kinematics of the intact knee and in situ forces of the intact PCL.     

Anatomic double-bundle posterior cruciate ligament reconstruction using hamstring tendons

Recent biomechanical studies have shown that an anatomic double-bundle posterior cruciate ligament (PCL) reconstruction is superior in restoring normal knee laxity compared with the conventional single-bundle isometric reconstruction. We describe a modification of an endoscopic PCL reconstruction technique using a double-bundle Y-shaped hamstring tendon graft. A double- or triple-bundle semitendinosus-gracilis tendon graft is used and directly fixed with soft threaded biodegradable interference screws. In the medial femoral condyle, 2 femoral tunnels are created inside-out through a low anterolateral arthroscopic portal. First, in 80° of flexion, the double-stranded gracilis graft is fixed with an interference screw inside the lower femoral socket, representing the insertion site of the posteromedial bundle. In full extension the combined semitendinosus-gracilis graft is pretensioned and fixed inside the posterior aspect of the single tibial tunnel. The double- or triple-stranded semitendinosus tendon is inserted in the higher femoral tunnel, presenting the insertion site of the anterolateral bundle. Finally, pretension is applied to the semitendinosus bundle in 70° of flexion and a third screw is inserted. Using this technique, the stronger semitendinosus part of the double-bundle graft, which mimics the anterolateral bundle of the PCL, is fixed in flexion, whereas the smaller gracilis tendon part (posteromedial bundle) is fixed in full extension. Thus, a fully arthroscopic anatomic PCL reconstruction technique is available that may better restore normal knee kinematics as compared to the single-stranded isometric reconstruction.Arthroscopy: The Journal of Arthroscopic and Related Surgery, Vol 17, No 1 (January), 2001: pp 88–97     

Reconstructive interventions of the posterior cruciate ligament--experimental studies of isometric aspects. Part II: Studies of the posterior cruciate ligament replacement model]

Isometric positioning of the posterior cruciate ligament (PCL) graft is important for successful reconstruction of the PCL-deficient knee. This study documents the relationship between graft placement and changes in intra-articular graft length during passive range of motion of the knee. In eight cadaveric knees the PCL was identified and cut. The specimens were mounted in a stabilizing rig. PCL reconstruction was performed using a 9-mm-thick synthetic cord that was passed through tunnels 10 mm in diameter. Three different femoral graft placement sites were evaluated: (1) in four specimens the tunnel was located around the femoral isometric point, (2) in two specimens the tunnel was positioned over the guide wire 5 mm anterior to the femoral isometric point, (3) in two specimens the tunnel was positioned over the guide wire 5 mm posterior to the isometric femoral point. In all knees only one tibial tunnel was created around the isometric tibial point. The location of the isometric points was described in part I of the study. The proximal end of the cord was fixed to the lateral aspect of the femur. Distally the cord was attached to a measuring unit. The knees were flexed from 0 degree to 110 degrees, and the changes in the graft distance between the femoral attachment sites were measured in 10 degrees steps. Over the entire range of motion measured the femoral tunnels positioned around the isometric point produced femorotibial distance changes of within 2 mm. The anteriorly placed tunnels produced considerable increases in femorotibial distance with knee flexion, e.g. about 8 mm at 110 degrees of flexion.(ABSTRACT TRUNCATED AT 250 WORDS)     

One-incision endoscopic technique for posterior cruciate ligament reconstruction with quadriceps tendon–patellar bone autograft

Quadriceps tendon–patellar bone autograft is an alternative graft choice for posterior cruciate ligament (PCL) reconstruction. A 2-incision technique with outside-in fixation at the femoral condyle is generally used. In this article, we describe a 1-incision endoscopic technique for PCL reconstruction with quadriceps tendon–patellar bone autograft. The graft consists of a proximal patellar bone plug and central quadriceps tendon. The bone plug is trapezoidal, 20 mm long, 10 mm wide, and 8 mm thick. The tendon portion is 80 mm long, 10 mm wide, and 6 mm thick, including the full-thickness of the rectus femoris and partial thickness of the vastus intermedius. Three arthroscopic portals, including anteromedial, anterolateral, and posteromedial, are used. All procedures are performed in an endoscopic manner with only 1 incision at the proximal tibia. At the femoral side, the bone plug is fixed by an interference screw. At the tibial side, the tendon portion is fixed by a suture to a screw on the anterior cortex and an interference bioscrew in the posterior tibial tunnel opening. Quadriceps tendon autograft has the advantages of being self-available, allowing for easier arthroscopic technique, and providing comparable graft size. The 1-incision technique provides a simple reconstruction method for PCL insufficiency without a second incision at the medial femoral condyle.Arthroscopy: The Journal of Arthroscopic and Related Surgery, Vol 17, No 3 (March), 2001: pp 329–332     

Aperture Fixation in Arthroscopic Anterior Cruciate Ligament Double-Bundle Reconstruction

The native anterior cruciate ligament (ACL) consists of 2 bundles, which have distinct biomechanical yet synergistic functions with respect to anterior tibial translation and combined rotatory loads. Traditionally, most ACL reconstruction techniques have primarily addressed the restoration of the anteromedial bundle, and less consideration was given to the posterolateral bundle. Recently, various ACL double-bundle reconstruction techniques have been described. With most of these techniques, however, an indirect extra-anatomic fixation far from the articular surface was performed. Because extra-anatomic fixation techniques, rather than aperture fixation techniques, are associated with graft tunnel motion, windshield wiper action, and suture stretch-out, concerns may arise regarding delayed biological incorporation, tunnel enlargement, and secondary rotational and anterior instability. We, therefore, present a novel arthroscopic technique that reapproximates the footprints of native ACL with the use of double-strand semitendinosus and gracilis autografts for reconstruction of the anteromedial and posterolateral bundles, respectively. A separate femoral and tibial tunnel is drilled for each double-strand autograft. The femoral tunnel for the anteromedial bundle is drilled primarily through a transtibial technique, and the femoral tunnel for the posterolateral bundle is drilled via an accessory anteromedial portal with the use of a 4-mm offset drill guide in the anteroinferior aspect of the femoral tunnel for the anteromedial bundle. Bioabsorbable interference screws are used in aperture fixation for anatomic fixation of each bundle. This technique attempts to reproduce closely the native ligament and its biomechanical function.     

四隧道保留残端后十字韧带重建术的近期疗效

目的 探讨关节镜下采用胫骨斜对角位点四隧道保留残端后十字韧带(posterior cruciate ligment,PCL)重建术的近期临床疗效.方法 2006年6月至2008年6月施行四隧道保留残端PCL重建术21例,男15例,女6例;年龄18～40岁,平均28岁.胫骨双隧道位点在PCL原不规则四边形止点的斜对角处,内下点为后内侧柬,外上点为前外侧束;股骨双隧道位于PCL附着足印区,前外侧束位点在10:30(左)或1:30(右),后内侧束在8:30(左)或3:30(右).术中保留后十字韧带残端纤维,并同时治疗合并损伤.移植物采用深低温冷冻同种异体胫前肌腱,对折双束两端缝合,使用可吸收界面螺钉固定.结果 全部病例随访12～18个月,平均14个月.后抽屉试验(posterior drawer test,PDT)术前(++)不稳15例,(+++)不稳6例;术后(-)15例,(+)不稳5例,(++)不稳1例.IKDC评分术前平均(62.14±4.9)分,术后(93.95±3.6)分,差异有统计学意义(t=10.3,P<0.05).其中正常17例,接近正常3例,不正常1例.Lysholm评分由术前(52.33±4.9)分提高到术后(91.19±3.6)分,差异有统计学意义(t=11.6,P<0.05).结论 采用胫骨双隧道斜对角位点四隧道保留残端PCL重建术能更多地保留残端纤维,保留隧道间骨桥,符合解剖重建,稳定性良好.     

异体胫前肌腱"Y"形双束双隧道重建后十字韧带的疗效分析

目的 探讨异体胫前肌腱"Y"形双柬双隧道移植重建后十字韧带(posterior cruciate ligament,PCL)的临床效果.方法 2001年3月至2008年1月,采用将异体胫前肌腱编织成"Y"形双束韧带的方法治疗PCL损伤患者,其中47例具有完整随访资料,男39例,女8例;年龄18～43岁,平均24.3岁."Y"形双束韧带长度约为130mm,A端为长束(A束),长约70mm,直径为10～12mm;B端为两短束(B1、B2束),B1束(前外侧束)长为55mm,直径6mm,B2束(后内侧束)长约50mm,直径6mm.韧带安装时两端均从膝前内侧工作通道的切口进入,即:外(膝前内侧工作通道)→内(股骨、胫骨隧道内口)→外(股骨、胫骨隧道外口).可吸收界面钉先固定胫骨隧道侧,然后再固定股骨侧;固定前外侧束时屈膝90°,固定后内侧束时屈膝30°.术后予膝关节角度锁定助行器辅助锻炼8～10周.结果 手术时间30～60 min,平均(45±15)min.随访时间9～82个月,平均49.5个月.Lachmann后向试验术前均阳性,术后38例阴性、5例弱阳性、4例阳性;KT-1000试验术前(9.0±4.0)mm,术后(3.0±1.5)mm,两者比较差异有统计学意义(t=3.12,P=0.003).Lysholm评分术前(51.4±5.2)分,术后(93.3±4.1)分,两者比较差异有统计学意义(t=2.93,P=0.005).Tegner活动水平术后(6.9±1.3)分较术前(3.5±0.7)分有显著改善(t=2.99,P=0.004).结论 成人异体胫前肌腱对折编织成双束有足够的长度和直径重建PCL,其抗拉力强;改进后的韧带通过隧道时顺畅,简单易操作,省时.