tendon-to-bone fi xation using hamstring tendon graft s allows for less fixation strength when compared to bone-to-bone fixation using bone-patellar tendon-bone grafts and is not conducive to early rehabilitation as revealed by an animal study, where complete union was obtained ≥24 weeks aft er ACL 5-7). Th erefore, cure graft fi xation appears to be crucial for early weight-bearing and aggressive rehabilitation after ACL reconstruction using hamstring tendon graft s.
Currently, a variety of methods for femoral fi xation of tendon grafts have been introduced and employed in clinical ttings. Biomechanical advantages and disadvantages of individual methods have been well documented in previous studies and new fixation methods are continuously being suggested. Expansion fixation that is bad on press-fit fixation of a graft into the femoral tunnel by employing ≥1 cross pin has been reported to render satisfying results in biomechanical and clinical studies 8). Cancellous suspension fixation allows the least elongation and accordingly provides the greatest fixation strength and stability amongst various available methods and has the lowest cyclic amplitude 9).
In this study, we compared ≥1-year short-term clinical results of
ACL Reconstruction with Autologous Hamstring Tendon: Comparison of Short Term Clinical Results between Rigid-fi x and PINN-ACL Cross Pin糖醋鱼块的家常做法
Seung-Suk Seo, MD 1, Chang-Wan Kim, MD 1, Tae-Seok Nam, MD 2 and Sang-Y eong Choi, MD 1
Department of Orthopedic Surgery, 1Busan Paik Hospital, University of Inje College of Medicine, Busan; 2Nanoori Hospital, Seoul, Korea
Th is is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial Licen (creativecommons/licens/by-nc/3.0/) which permits unrestricted non-commercial u, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright © 2011. KOREAN KNEE SOCIETY
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Original Article
Knee Surg Relat Res 2011;23(4):208-212dx.doi/10.5792/ksrr.2011.23.4.208pISSN 2234-0726 · eISSN 2234-2451
Knee Surgery & Related Rearch
Purpo: To compare the short term clinical results of anterior cruciate ligament (ACL) reconstruction with autologous hamstring tendon between Rigid-fi x and PINN-ACL Cross Pin for femoral side fi xation.
Materials and Methods: 127 patients who underwent arthroscopic ACL reconstruction using autologous hamstring tendon and had been followed-up for over than one year were enrolled for the prent study. Rigid-fi x was ud in 71 cas (group 1), and PINN-ACL Cross Pin was ud in 56 cas (group 2). Clinical and radiological results, operation time, and perioperative complications were compared amongst the two groups.Results: Th e International Knee Documentation Committee subjective score and Lysholm score were 94 and 95 in group 1 and 87 and 91 in group 2, with no statistical difference (p=0.892, p=0.833), respectively. However, significant difference was obrved in one-leg hop test between the two groups (p=0.032). Five cas in group 1 and 40 cas in group 2 were found to be associated with perioperative complications with statistical diff erence (p<0.0001).Conclusions: Th ere was no resultant diff erence between the employment of PINN-ACL Cross Pin and Rigid-fi x as femoral graft fi xation for ACL reconstruction with hamstring tendon. However, PINN-ACL Cross Pin led to complications with extensive operation times. Hence, it needs further improvement of tools for minimization of complications.
Key words: Anterior cruciate ligament reconstruction, Hamstring tendon, Rigid-fi x, PINN-ACL Cross Pin.
Received May 3, 2011; Revid (1st) June 9, 2011; (2nd) July 15, 2011; Accepted July 27, 2011.
Correspondence to: Chang-Wan Kim, MD.
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Department of Orthopedic Surgery, Busan Paik Hospital, University of Inje College of Medicine,
qq注销空间Gaegeum-dong, Busanjin-gu, Busan 633-165, Korea .Tel: +82-51-890-6257, Fax: +82-51-892-6619Email:
Introduction
In anterior cruciate ligament (ACL) reconstruction, hamstring tendon grafts are replacing the popular bone-patellar tendon-bone grafts that have been associated with femorotibial joint pain, loss of extension, and patellar tendon rupture 1-4). However,
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Knee Surg Relat Res, Vol. 23, No. 4, Dec. 2011209
ACL reconstructions using an expansion fi xation device, Rigid-fix (Mitek, Norwood, MA, USA) and a cancellous suspension device, PINN-ACL Cross Pin (CondMed Linvatec, Largo, FL, USA).
Materials and Methods
1. Materials
Arthroscopic ACL reconstruction using an autologous quadrup-led hamstring tendon graft was performed with Rigid-fi x in 87 patients between January 2006 and December 2007 and with PINN ACL Cross Pin in 64 patients between January 2008 and February 2010 at our institution. Of them, 71 patients in whom Rigid-fi x was ud (group I) and 56 patients in whom PINN ACL Cross Pin was ud (group II) were enrolled in this study. The minimum follow-up period was 1 year.
2. Combined Injury
The most common combined injury was a meniscus tear (37 cas in group I and 36 cas in group II) followed by medial collateral ligament injury (21 cas in group I and 23 cas in group II) and chondromalacia (36 cas in group I and 29 cas in group II). For the meniscus tears, suture repair and partial menictomy were performed in 24 cas and 13 cas, respectively, in group I and in 2
沉默术士
1 cas and 15 cas, respectively, in group II. For the medial collateral ligament injuries, full range of motion was obtained with conrvative treatment before ACL reconstruction. Regarding the chondral lesions, patients with minor chondromalacia that could be treated with debridement were included in this study and vere cas that required surgical treatment were excluded.
3. Surgical T echnique
Transtibial single-bundle ACL reconstruction was performed in all the patients. For the Rigid-fi x system, a 3.3-mm cross-pin was pasd through the tendon graft in the femoral tunnel and fi xed to the femur. For tibial fi xation, the graft was fi xed by employing Intrafix (Mitek, Norwood, MA, USA) within the tibial tunnel under a tension of 9.07 kg (20 pounds) with the knee at 20o of flexion. Subquently, post-tie fixation was additionally done using a 4.0 mm Arbeitsgemeinschaft für Osteosynthefragen (AO) cortical screw in the cortical bone of the anteromedial aspect of the proximal tibia.
For the PINN-ACL Cross Pin system, the quadrupled tendon graft was pasd through the graft harness and the terminals were tied together. The graft harness was inrted into the femoral tunnel and an arthroscope was advanced through the transver tunnel to make sure that the eyelet of the
graft harness was at the center of the transver tunnel. Next, a cross-pin was laterally inrted to pass through the eyelet of the graft harness and the head of the cross-pin was fi xed to the surface of the cortical bone of the lateral condyle of the femur. For tibial fi xation, tension of 80 N was maintained on the graft using SE graft tensioner with the knee at 20o of flexion. Intrafix and a 4.0 mm AO cortical screw were ud to complete the fi xation in the tibial tunnel.
4. Rehabilitation
From the fi rst postoperative day, patients began 0o-30o of fl exion exercis using a continuous passive motion machine and partial weight-bearing with a crutch and a knee brace was permitted. The range of motion was gradually incread from the 3rd postoperative week to ≥90o of flexion at the 6th postoperative week and ambulation without an assistive device was permitted. From the 12th postoperative week, patients were allowed to resume light activities of daily living. From the 6th postoperative month, light sports activities including jogging, swimming, and cycling were permitted. Return to previous sport activities or contact sports were allowed after 10 months of surgery when the muscle strength and proprioception were restored. The rehabilitation program was identical for all the patients with meniscal repair.
5. Clinical and Radiological Asssments
Th e operation time was measured bad on the tourniquet time. For clinical asssment, the International Knee Documentation Committee (IKDC) subjective scores and Lysholm scores, pivot shift test results, and one-leg hop test results were obtained preoperatively and compared with the ones obtained at the last follow-up. Laxity was evaluated with a KT-1000 arthrometer (Medmetric Corp., San Diego, CA, USA) and anterior displacement was measured with a Telos arthometer (Telos stress device; Austin & Associate, Inc., Polston, MD, USA) both, before and after the surgery. The pivot shift test results were classified into 4 grades: grade 0, no side-to-side diff erence; grade I, slight subluxation or slippage; grade II, definite subluxation; and grade III, subluxation and locking. Regarding the one-leg hop test, the longest distance in 3 concutive trials was registered and classified into 4 grades bad on the comparison with the contralateral side: grade A, 100-75% of the unaff ected side; grade B, 75-50%; grade C, 50-25%; and grade D, ≤25%.
210 Seo et al. ACL Reconstruction with Autologous Hamstring Tendon
6. Statistical Analysis
Statistical analysis was performed using SPSS soft ware (ver. 13.0, SPSS Inc., Chicago, IL, USA). One-leg hop test results and pivot shift test results were analyzed with the chi square test and other
variables were analyzed with analysis of variance test and the t-test. A value of p≤0.05 was considered statistically signifi cant.
Results
The mean age of the patients was 31.7 years (range, 18 to 46 years) in group I and 32.5 years (range, 19 to 44 years) in group II. Th e male-to-female ratio was 57/14 in group I and 39/17 in group II. The mean follow-up period was 22.7 months (range, 12 to 37 months) in group I and 14.5 months (range, 12 to 25 months) in group II. Th e cau of injury was sports injury in 58, traffi c accident in 9, and activities of daily living in 4 patients in group I and sports injury in 41, traffi c accident in 10, and other caus in 5 patients in group II (Table 1). The mean operation time was significantly different between the two groups with 58 minutes in group I (Rigid-fi x group) and 69 minutes in group II (PINN ACL Cross Pin group) (p=0.038). The mean IKDC subjective score incread from 72.2±11.9 preoperatively to 94.1±6.8 at the last follow-up in group I (p=0.036) and from 69.3±8.9 preoperatively to 87±12.3 at the last follow-up in group II (p=0.028), showing no statistically significant difference between the two groups. There was an improvement in the mean Lysholm score from 56.2±7.9 preoperatively to 95.4±6.8 at the last follow-up in group I (p=0.0231) and from 64.6±11.9 preoperatively to 91.2±12.1 at the last follow-up in group II, but no signifi cant diff erence
was noted between the two groups. The mean laxity assd using a KT-1000 arthrometer improved from 6.39±2.9 mm preoperatively to 3.03±1.6 mm at the last follow-up in group I (p=0.025) and from 6.68±3.3 mm preoperatively to 2.39±1.9 mm at the last follow-up, but no statistically signifi cant diff erence between the two groups was obrved. Also, improvement was obrved in the mean side-to-side diff erence in anterior translation measured by Telos stress radiography from 7.65±2.0 mm preoperatively to 3.09±1.3 mm at the last follow-up in group I (p=0.015) and from 8.03±3.1 mm preoperatively to 2.55±1.9 mm at the last follow-up in group II (p=0.031); but no signifi cant diff erence between the two groups was obrved. Regarding the pivot shift test, there was an improvement in the integrity of the ACL in both the groups, but no signifi cant diff erence was noted between the groups: there were 5 cas of grade I, 45 cas of grade II, and 21 cas of grade III preoperatively and 49 cas of grade 0, 16 cas of grade I, and 6 cas of grade II at the last follow-up in group I (p=0.013); whereas there were 6 cas of grade I, 37 cas of grade II, and 13 cas of grade III preoperatively and 38 cas of grade 0, 12 cas of grade I, and 6 cas of grade II at the last follow-up in group II. A statistically significant difference between the groups was obrved in the one-leg hop test with group I showing greater improvements than group II: there were 7 cas
Table 1. Th e Patient Demographics
Group 1 (Rigid-fi x)
Group 2 (PINN-ACL)
Mean age (y) 31.7 32.5
Sex (male/female)57/1439/17
Cau of injury
Sports5841
Traffi c accident 910
ADL or others 4 5
Associated lesion in same knee
Chondral lesion3629
Meniscal tear3736
MCL tear2123
Mean duration of follow-up (mo) 22.7 14.5
ADL: activities of daily living, MCL: medial collateral ligament.
Table 2. Th e Clinical and Radiologic Results of Rigid-fi x and PINN-ACL Cross Pin for ACL Reconstruction using Hamstring Tendon
Group 1 pre-op Group 1 post-op Group 2 pre-op Group 2 post-op IKDC score72.294.169.387.3 Lysholm' score56.295.464.691.2
KT-1000 arthrometer a) 6.39 3.03 6.68 2.39 Telos stress arthrometer b) 7.65 3.09 8.03 2.55 Pivot shift test (grade 0/I/II/III)0/5/45/2149/16/6/00/6/37/1338/12/6/0 One-leg hop test (grade 0/I/II/III)7/28/27/935/28/6/24/18/28/619/26/7/4 IKDC score: International Knee Documentation Committee subjective score, ACL: anterior cruciate ligament.
a)Anterior displacement using KT-1000 arthrometer, b)Anterior displacement using Telos (Telos stress device).
Knee Surg Relat Res, Vol. 23, No. 4, Dec. 2011211
of grade 0, 28 cas of grade I, 27 cas of grade II, and 9 cas of grade III preoperatively and 35 cas of grade 0, 28 cas of grade I, 6 cas of grade II, and 2 cas of grade III at the last follow-up in group I (p=0.032); whereas there were 4 cas of grade 0, 18 cas of grade I, 28 cas of grade II, and 6 cas of grade III preoperatively and 19 cas of grade 0, 26 cas of grade I, 7 cas of grade II, and 4 cas of grade III at the last follow-up in group II (p=0.032) (Table 2).
Regarding the complications, the incidence of cross pin-femoral tunnel mismatch was higher in group II, with 4 cas in group I and 36 cas in group II (p=0.017). Soft tissue irritation from cross pin head prominence was obrved in 1 ca in group I and 4 cas in group II, which further improved 2 months later in all the cas. No other complications including infection, fixation device failure, and fracture of the lateral femoral condyle were obrved.
Discussion
显卡性能图Th e fi xation mechanisms for femoral fi xation of tendon graft s were classified by Milano et al.8) into compression, expansion, and suspension and the last one was subdivided into cortical suspension, cancellous suspension, and cortico-cancellous suspension. Cortical suspension fixation has been associated with biomechanical instability including bungee cord effect10) and Windshield wiper eff e
ct11). Compression fi xation mechanism has a relatively low failure load and stability12,13). Expansion fixation mechanism can be advantageous in obtaining cure fixation becau two cross pins inrted transverly through a graft provides a centrifugal pressure on the femoral tunnel, but treatment results depend on the press-fit of the graft, bone density around the femoral tunnel, and correct placement of the cross pins through the graft tendon13-15). In contrast, cancellous suspension off ers cure fi xation, stability, and stiff ness becau the length of the graft in the femoral tunnel is short with u of transver fi xation pins that can be inrted into the femoral metaphysis. Speirs et al.9) reported the biomechanical superiority of the cancellous suspension fi xation mechanism with respect to total creep, stability, and failure load. Accordingly, we attempted to asss the advantages and disadvantages of the PINN-ACL Cross Pin device, one of the devices ud for cancellous suspension fixation by comparing it with the conventional Rigid-fix device. The clinical and radiological results of ACL reconstructions including early weight-bearing and rehabilitation were satisfying in both, group I (Rigid-fix group) and group II (PINN-ACL Cross Pin group). No significant difference could be obrved between the groups except for the one-leg hop test. However, considering that greater clinical improvements were en in group I, where the mean follow-up period was longer (group I: 22.7 months and group II: 14.5 months), a long-term follow-up study should be carried out for the better asssment of the effi cacy of PINN-ACL Cross Pin device.
Th e incidence of cross pin-femoral tunnel mismatch was higher in group II with 36 cas. In our opinion, this was becau the cross pin did not pasd through the eyelet of the graft harness sliding in the femoral tunnel during cross pin drilling (Fig. 1). To prevent this, we tried to firmly fix the drill guide sheath to the femur or created a short femoral tunnel (30-35 mm) to perform drilling at almost perpendicular direction to the cortical bone. Soft tissue irritation from cross pin head prominence was obrved in 4 cas. We hypothesize that this can be prevented by inrting cross pin heads more deeply or developing a smaller cross pin head.
Conclusions
In ACL reconstruction, Rigid-fi x, a conventional fi xation device, and PINN ACL Cross Pin, a recently introduced device, did not produce significantly different clinical and radiological results. However, the latter resulted in higher incidence of complications
Fig. 1. Femoral tunnel-Cross pin and Graft
Harness tunnel mismatch. When Graft
Harness is positioned at ‘b’, Cross pin tends
to slide at the drilling site becau it has a
lower drill angle (β<α).
212 Seo et al. ACL Reconstruction with Autologous Hamstring Tendon
including, cross pin-tunnel mismatch and required longer operation time. Th erefore, we consider that further improvements in the device or surgical technique should be carried out. The limitations of this study include the short-term follow-up period and u of different tibial fixation methods between the two groups.
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