Freehand Anatomic Transtibial Single-Bundle Anterior Cruciate Ligament Reconstruction.

Creation of the femoral tunnel for single-bundle anterior cruciate ligament (ACL) reconstruction has a high rate of nonanatomic placement with the transtibial (TT) technique but yields better restoration with the anteromedial portal technique and close restoration of the anatomic femoral footprint with the outside-in technique. Modifications of the traditional (TT) technique have been described to restore the native femoral ACL footprint and to simulate double-bundle reconstruction. Modified TT techniques try to capture the anatomic femoral footprint through an anatomic tibial tunnel. In the technique described in this article, the anatomic femoral footprint is drilled first by the use of a 2.5-mm Kirschner wire through the parapatellar anteromedial portal, making an angle 30° to the sagittal plane and 20° to the horizontal plane. The wire is drilled while the knee is hyperflexed and then withdrawn from outside until its distal end reaches the intercondylar notch. The wire is then advanced in an antegrade manner while the knee is flexed 90° until it reaches the center of the marked tibial footprint. The angle of knee flexion may be slightly increased or decreased around 90° with or without slight internal rotation to capture the anatomic tibial footprint. The procedure is completed as a TT single-bundle ACL reconstruction.

Consider Long Head of Biceps Tendon for Reconstruction of Massive, Irreparable Rotator Cuff Tear.

Despite the different treatment options for irreparable and massive rotator cuff tears (RCTs), there is no optimal treatment. Thirty percent of total RCTs can be classified as irreparable because of the massive tear size and severe muscle atrophy. The reported treatment failure rate is approximately 40% for massive RCTs. RCTs may be treated conservatively or surgically depending on pain, disability, and functional demands. The surgical treatment options are many, but decision making is a challenge; the real challenge is to apply the correct procedure for the correct indication in each patient. The long head of the biceps tendon (LHBT) was used for augmentation to bridge the gap in immobile, massive RCTs. An arthroscopic biceps-incorporating technique was used for repair of large and massive RCTs, avoiding undue tension on the rotator cuff (RC). Recently, the LHBT was used for superior capsular reconstruction. This article describes the use of the LHBT for reconstruction of massive and irreparable RCTs through the following steps: (1) open exposure of the RCT, (2) debridement and subacromial decompression, (3) biceps tenotomy at the LHBT's origin on the glenoid, (4) LHBT and RC cuff mobilization, (5) passage of the LHBT through the mobilized RC and reflection onto itself, (6) tuberoplasty, and (7) fixation of the RC complex at the RC footprint.

Incidence of silent venous thromboembolism after total hip arthroplasty: A comparison of rivaroxaban and enoxaparin.

PROPOSE: Total hip arthroplasty (THA) is associated with a significant risk of venous thromboembolism (VTE). Different thromboprophylaxis strategies have been used to prevent VTE. The primary aim of this study was to report the incidence of VTE and compare the efficacy and safety of rivaroxaban to enoxaparin. The secondary outcome was to report the incidence of silent deep venous thrombosis (DVT) using computed tomography venography. METHODS: One hundred sixty patients who underwent THA were enrolled in a prospective study. Patients were randomized into two groups as follows: those who received rivaroxaban 10 mg oral daily (group RXE) and those who received enoxaparin 40 IU/day subcutaneously for 14 days (group ENO). RESULTS: Both groups were matched for age, sex, comorbidities, special habits and preoperative laboratory investigations. The overall incidence of DVT was 5% (n = 8), which included four patients clinically diagnosed as having DVT and four with silent DVT. All the DVT cases occurred in veins below the knee and in the group RXE; none of the cases occurred in group ENO (p = 0.04). The incidence of DVT was significantly higher in patients with high body mass indexes (p < 0.001), older age (p = 0.024) and medical comorbidities (p = 0.14). No mortality, pulmonary embolism, stroke, wound infection or major bleeding occurred in either group. CONCLUSIONS: Among the patients who underwent hip arthroplasty, rivaroxaban prophylaxis was found to be associated with lower efficacy and similar safety outcomes as compared with enoxaparin anticoagulants.

Combined Anterior Cruciate Ligament, Medial Collateral Ligament, and Posterior Oblique Ligament Reconstruction Through Single Tibial Tunnel Using Hamstring Tendon Autografts.

Combined anterior cruciate ligament (ACL) and medial collateral ligament (MCL) injuries are the most common type of combined ligamentous injury of the knee. The optimal treatment for these combined injuries is controversial. Combined ACL and MCL-posterior oblique ligament (POL) reconstruction avoids late anteromedial rotatory instability and chronic valgus instability of the knee and decreases the increased stress on the ACL graft. Graft choice (hamstring tendon autograft, quadriceps bone-patellar tendon-bone autograft, or Achilles tendon allograft) and anatomic restoration of the medial and posteromedial corner of the knee are challenges of this combined reconstruction. This article describes a technique that allows combined ACL and MCL-POL reconstruction. The hamstring tendons from the contralateral limb are tripled and used as the ACL graft. The gracilis tendon from the ipsilateral limb is doubled and used as the MCL-POL graft. The semitendinosus tendon of the ipsilateral limb is preserved. After ACL reconstruction, the MCL-POL graft is suspended on the ACL graft at the distal end of the tibial tunnel and the graft limbs are used for open reconstruction of the MCL and POL. Three interference screws (Arthrex, Naples, FL) and 1 metal staple are used for graft fixation of this combined reconstruction.

Open Anatomic Coracoclavicular Ligament Reconstruction by Modified Conjoint Tendon Transfer for Treatment of Acute High-Grade Acromioclavicular Dislocation.

There is no ideal surgical technique for the treatment of acromioclavicular (AC) dislocations. Reconstruction of the coracoclavicular ligaments (CCLs) for the treatment of AC dislocations is evolving. Many techniques for CCL reconstruction have been described. They differ mainly in the method of fixation, number of tunnels, and graft used. The surgeon should select among hamstring autograft reconstruction, coracoacromial ligament transfer, and conjoint tendon transfer for CCL reconstruction. Early on, conjoint tendon transfer to the lateral clavicle was described for the treatment of high-grade AC dislocation. Dynamic instability occurred with poor long-term outcomes. The procedure was abandoned. Recently, proximally based conjoint tendon transfer for CCL reconstruction was described, but the technique is nonanatomic and leads to anterior displacement of the clavicle and malreduction. This article describes modified conjoint tendon transfer. The technique may yield stable, anatomic, biological reconstruction of the CCL for the treatment of acute high-grade AC dislocation. It consists of the following steps: (1) creation of clavicular holes, (2) coracoid osteotomy, (3) conjoint tendon mobilization, (4) conjoint tendon transfer and fixation to the CCL footprint on the undersurface of the clavicle, and (5) AC reduction and conjoint tendon tenodesis to the bed of the retained coracoid process.

Combined Anterior Cruciate Ligament and Posterolateral Corner Reconstruction by Hamstring Tendon Autografts Through a Single Femoral Tunnel by Graft-to-Graft Suspension and Fixation.

An untreated posterolateral corner (PLC) injury in patients with a torn anterior cruciate ligament (ACL) may be a leading cause of ACL reconstruction failure. Combined ACL and PLC reconstruction is discussed in few studies in the literature. Femoral tunnel intersection in combined reconstruction has been reported to be high. Short grafts may render combined reconstruction undoable. This Technical Note describes a technique that allows a combined ACL and PLC reconstruction. The ACL graft is a 4-stranded hamstring tendon graft from 1 limb. The PLC graft is a doubled semitendinosus tendon graft from the contralateral side. One femoral tunnel is used connecting the femoral attachment of the PLC on the lateral wall of the lateral femoral condyle to the anatomic femoral ACL footprint on the medial wall of the lateral femoral condyle. The PLC graft is suspended on the ACL graft to be anchored on the cortex of the lateral femoral condyle with added fixation by an interference screw (Arthrex, Naples, FL). The PLC graft limbs are used for open reconstruction of the fibular collateral ligament, popliteus tendon, and popliteofibular ligament. This Technical Note describes a technique of combined ACL and PLC reconstruction with hamstring tendon autografts through a single femoral tunnel using graft-to-graft suspension and fixation.

Ilizarov trifocal lengthening followed by intramedullary nailing for massive posttraumatic tibial bone defects.

The treatment of massive tibial bone defects takes a very long time. An Ilizarov trifocal approach decreases the lengthening time. Subsequent intramedullary fixation decreases the complications of the conventional Ilizarov method. This technique was applied between June 2010 and June 2011 in 10 male patients with a mean age of 30 years. All had grade III open tibial fractures. The patients were treated at Mansoura University Hospital and a private hospital. The sequence of treatment included trifocal lengthening using the Ilizarov method, followed by removal of the fixator, temporary plaster cast immobilisation and subsequent intramedullary fixation until complete union was achieved. The length of the tibial bone defect ranged between 6-12 cm; the lengthening time ranged between 45-75 days and the consolidation time ranged between 90-160 days. The results were evaluated according to Paley's bone and functional assessment scores. The bone results were excellent in 7 patients and good in 3. Two patients had non union and one patient had pin tract infection. The functional results were excellent in 7 patients and good in 3. Two patients had equinus deformity and one patient had limited range of knee motion. There were no deep infections, DVTs or leg length discrepancies greater than 2.5 cm. Ilizarov trifocal lengthening followed by delayed intramedullary fixation appeared in this study as a good method of treatment for massive posttraumatic tibial bone defects. It reduced fixator time and minimized the complications associated with the Ilizarov fixation.

Trapezius tendon transfer according to Saha after neglected complete axillary nerve injury.

Traumatic axillary nerve injury represents less than 1% of all nerve injuries.It is often subclinical because it is masked by the pain due to a shoulder fracture or dislocation, so that treatment is neglected for a long period. When nerve repair and physiotherapy are unsuccessful, trapezius tendon transfer may be considered. Between March 2008 and May 2009, 10 patients with neglected deltoid paralysis were treated by trapezius tendon transfer at Mansoura University hospital and in a private hospital. All patients were males. Their mean age was 27.8 years (range: 17-35). The mean follow-up period was 30 months (range: 24 to 36 months). The operations were performed according to the method described by Saha in 1967, involving transfer of the lateral extremity of the clavicle, the acromioclavicular joint and the acromion, with the insertion of the trapezius, to the proximal humerus. The authors retrospectively assessed the results according to the 5 items (a-e) of the Rowe and Zarins score: all 10 patients had (a) improved shoulder function with (e) a more stable shoulder. The mean active abduction (b) was 76 degrees (range: 50-100 degrees) and the mean active flexion (c) 78 degrees (range: 45-110 degrees). However, most authors report lower values: from 34 to 76 degrees of abduction, and from 30 to 78 degrees of flexion. Arthrodesis results in 59 to 71.43 degrees of abduction. The abduction power (d) was improved: it reached grade 3 in 7 cases and grade 4 in 3 cases. In this study, trapezius tendon transfer provided satisfactory functional improvement for paralysis of shoulder abduction after neglected complete axillary nerve injury, with improvement in shoulder stability, power and range of motion.