Biomechanical Evaluation of Different Tibial Fixation Methods in the Reconstruction of the Anterolateral Ligament in Swine Bones

Costa, Rogério Nascimento; Nadal, Rubens Rosso; Saggin, Paulo Renato Fernandes; Lopes, Osmar Valadão; Spinelli, Leandro de Freitas; Israel, Charles Leonardo

doi:10.1016/j.rbo.2017.09.001

Abstract

Objective

The present study aims to evaluate different methods of tibial fixation in the reconstruction of the anterolateral ligament (ALL). In addition, the present paper aims to compare the effectiveness of these methods and theirmechanisms of failure in swine knees.

Methods

A total of 40 freshly frozen swine limbs were divided into 4 groups of 10 specimens, according to the tibial fixation technique used. In group A, the tibial fixation of the tendon graft wasmade through an anchor passing the graft. In group B, the tibial fixation was performed through a metal interference screw in a single bone tunnel. In group C, the tibial fixation included an anchor associated with a tendinous suture (but not with a wire crossing the tendon). In group D, two confluent bony tunnels were drilled and combined with an interference screw in one of them.

Results

The lowest mean force (70.56 N) was observed in group A, and the highest mean force (244.85 N) was observed in group B; the mean values in the other 2 groups ranged from 171.68 N (group C) to 149.43 N (group D). Considering the margin of error (5%), there was a significant difference between the groups (p < 0.001).

Conclusion

Fixation with an interference screw in a single tunnel bone showed the highest tensile strength among the evaluated techniques.

Keywords:
anterior cruciate ligament; articular ligaments; knee; orthopedic procedures

Resumo

Objetivo

Avaliar a força de resistência à tração de diferentesmétodos de fixação tibial na reconstrução do ligamento anterolateral (LAL). Além disso, comparar os mecanismos de falha da fixação tibial dessa reconstrução em joelhos suínos.

Métodos

Foram usados 40 membros recém-congelados de suínos, divididos em quatro grupos de dez espécimes, conforme as técnicas de fixação tibial usadas. No grupo A, a fixação tibial do enxerto tendíneo foi feita por meio de uma âncora e seu fio transpassou o enxerto. No grupo B, a fixação tibial foi feita por meio de parafuso de interferência metálico em túnel ósseo único. No grupo C, a fixação tibial incluiu uma âncora associada à sutura de ponto sobre o tendão (sem a presença de fio que transpassasse o tendão) e, no grupo D, foram usados dois túneis ósseos confluentes associados a um parafuso de interferência em um dos túneis.

Resultados

A força média menos elevada (70,56 N) ocorreu no grupo A e a mais elevada (244,85 N), no grupo B; as médias dos outros dois grupos variaram entre 171,68N (grupo C) e 149,43 N (Grupo D). Considerando-se a margem de erro fixada (5%), foi observada diferença significativa entre os grupos (p < 0,001).

Conclusão

A fixação com parafuso de interferência em túnel ósseo único apresentou a maior força de resistência à tração dentre as técnicas avaliadas. Abstract Objective The present study aims to evaluate different methods of tibial fixation in the reconstruction of the anterolateral ligament (ALL). In addition, the present paper aims to compare the effectiveness of these methods and theirmechanisms of failure in swine knees.

Palavras-Chave:
ligamento cruzado anterior; ligamentos articulares; joelho; procedimentos ortopédicos

Introduction

Anterior cruciate ligament (ACL) ruptures are among the most common injuries in athletes.¹1 Mall NA, Chalmers PN, Moric M, Tanaka MJ, Cole BJ, Bach BR Jr, et al. Incidence and trends of anterior cruciate ligament reconstruction in the United States. Am J Sports Med 2014;42(10): 2363-2370 ²2 Schon JM, Moatshe G, Brady AW, Cruz RS, Chahla J, Dornan GJ, et al. Anatomic Anterolateral Ligament Reconstruction of the Knee Leads to Overconstraint at Any Fixation Angle. Am J Sports Med 2016;44(10):2546-2556 However, in up to 25% of the ACL reconstructions, patients report residual rotational instability, demonstrating that achieving complete axial stability with surgically isolated ACL reconstruction remains a challenge.³3 Helito CP, Bonadio MB, Gobbi RG, da Mota E Albuquerque RF, Pécora JR, Camanho GL, et al. Combined intra- and extra-articular reconstruction of the anterior cruciate ligament: the reconstruction of the knee anterolateral ligament. Arthrosc Tech 2015;4 (03):e239-e244 Recently, the anterolateral ligament (ALL) has been described and recognized as a potential contributor to rotational laxity.²2 Schon JM, Moatshe G, Brady AW, Cruz RS, Chahla J, Dornan GJ, et al. Anatomic Anterolateral Ligament Reconstruction of the Knee Leads to Overconstraint at Any Fixation Angle. Am J Sports Med 2016;44(10):2546-2556 ⁴4 Sonnery-Cottet B, Thaunat M, Freychet B, Pupim BH, Murphy CG, Claes S. Outcome of a combined anterior cruciate ligament and anterolateral ligament reconstruction techniquewith aminimum 2-year follow-up. Am J Sports Med 2015;43(07):1598-1605 ⁵5 Helito CP, Demange MK, Bonadio MB, Tírico LE, Gobbi RG, Pécora JR, et al. Anatomy and histology of the knee anterolateral ligament. Orthop J Sports Med 2013;1(07):2325967113513546 This structure was first described by Segond⁶6 Segond P. Recherchescliniques et experimentalessur les ép anchementssanguins du genou par entorse. Paris: Aux Bureaux du Progres Medical; 1879 in 1879 as a “pearly fibrous band evident in internal rotation”⁶6 Segond P. Recherchescliniques et experimentalessur les ép anchementssanguins du genou par entorse. Paris: Aux Bureaux du Progres Medical; 1879 ⁷7 Claes S, Vereecke E, Maes M, Victor J, Verdonk P, Bellemans J. Anatomy of the anterolateral ligament of the knee. J Anat 2013; 223(04):321-328 and, for more than 130 years, there were several different ALL accounts, but few actually focused on its structure. The anatomy and biomechanical properties of the ALL were recently described,⁸8 Kennedy MI, Claes S, Fuso FA, Williams BT, Goldsmith MT, Turnbull TL, et al. The anterolateral ligament: an anatomic, radiographic, and biomechanical analysis. Am J Sports Med 2015;43 (07):1606-1615 ⁹9 Parsons EM, Gee AO, Spiekerman C, Cavanagh PR. The biomechanical function of the anterolateral ligament of the knee. Am J Sports Med 2015;43(03):669-674 ¹⁰10 Spencer L, Burkhart TA, Tran MN, Rezansoff AJ, Deo S, Caterine S, et al. Biomechanical analysis of simulated clinical testing and reconstruction of the anterolateral ligament of the knee. Am J Sports Med 2015;43(09):2189-2197 showing its importance in complete function restoration in ACL reconstruction.²2 Schon JM, Moatshe G, Brady AW, Cruz RS, Chahla J, Dornan GJ, et al. Anatomic Anterolateral Ligament Reconstruction of the Knee Leads to Overconstraint at Any Fixation Angle. Am J Sports Med 2016;44(10):2546-2556 Anterolateral ligament reconstruction is believed to reduce residual pivot-shift after an intra-articular reconstruction and thus improve postoperative knee kinematics.¹¹11 Dodds AL, Gupte CM, Neyret P, Williams AM, Amis AA. Extraarticular techniques in anterior cruciate ligament reconstruction: a literature review. J Bone Joint Surg Br 2011;93(11):1440-1448

Although several techniques describe ALL reconstruction, there is no gold standard for its fixation.

Anterior cruciate ligament reconstruction with hamstring autografts has a failure rate ranging from 4¹²12 Maletis GB, Cameron SL, Tengan JJ, Burchette RJ. A prospective randomized study of anterior cruciate ligament reconstruction: a comparison of patellar tendon and quadruple-strand semitendinosus/ gracilis tendons fixed with bioabsorbable interference screws. Am J Sports Med 2007;35(03):384-394 to 27.3%¹³13 Beynnon BD, Johnson RJ, Fleming BC, Kannus P, KaplanM, Samani J, et al. Anterior cruciate ligament replacement: comparison of bone-patellar tendon-bone grafts with two-strand hamstring grafts. A prospective, randomized study. J Bone Joint Surg Am 200284-A(09):1503-1513 However, these values may be underestimated, since the exact number of failed ACL reconstructions is difficult to calculate.¹⁴14 Kamath GV, Redfern JC, Greis PE, Burks RT. Revision anterior cruciate ligament reconstruction. Am J Sports Med 2011;39(01): 199-217 Similar to ACL reconstructions, a secure clamping technique is paramount to withstand graft forces in ALL reconstructions, allowing rehabilitation protocols with weight loads for an early return to sports activity.¹⁵15 Harvey A, Thomas NP, Amis AA. Fixation of the graft in reconstruction of the anterior cruciate ligament. J Bone Joint Surg Br 2005;87(05):593-603

The present study aims to analyze the tensile strength required for graft tibial insertion failure in four tibial fixation methods commonly used in anterolateral ligament reconstruction.

Material and Methods

The tensile force in Newtons (N) required for failure of four different fixation modes used in ALL reconstruction was biomechanically analyzed at the laboratory. A total of 40 freshly frozen swine hind limbs were divided into 4 groups of 10 specimens according to the method of tibial fixation used. In group A, the tibial fixation of the tendon graft was performed with an anchor (Hexagon) and Ultrabraid wire (Smith & Nephew, London, UK) passing through the graft. In group B, the tibial fixation was performed with a 7 × 20 mm Traumédica metal interference screw in a single bone tunnel. In group C, the tibial fixation included an anchor (Hexagon) with tendon suture (but not transecting it) and, in group D, 2 confluent bone tunnels were associated with a 7 × 20 mm Traumédica interference screw in 1 of them. All of the anatomical parts were removed from animals with ∼ 100 kg and aged between eight and nine months old. None of the samples showed signs of previous lesions or of degenerative disease, and all of them had a functionally stable knee joint. The swine knees were evenly dissected. All of the peripheral knee structures were sectioned and excised, leaving only the tibia (Fig. 1). The swine foot extensor tendons¹⁶16 Getty R. Sisson/Grossman. Anatomia dos animais domésticos. 5a ed. Rio de Janeiro: Interamericana; 1981 were dissected and removed to be used as tendinous grafts, standardized with 12 cm in length and 4 mm in diameter (Fig. 2). The width of each tibial plateau was measured to standardize the samples (Fig. 3 and Table 1).

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Table 1
Mediolateral distance from the tibial plateau (mm)

Fig. 1
Tibia preparation.

Fig. 2
Graft preparation.

Fig. 3
Plateau width.

Surgical Technique

After removing all muscles, ligaments, and joint capsules from the swine knees, the tibias were prepared for the test. The digital extensor tendons were dissected and extracted from the parts; next, all of the samples were stored at -20°C for between 24 and 48 hours until testing. Prior to the assay, each sample was thawed overnight at 4°C. The tests were performed between 24 and 72 hours after thawing. All of the tests were performed at room temperature, and the samples were constantly kept in a container with saline solution. All of the fixation methods were performed at the site considered the anatomical tibial insertion of the ALL, between the fibular head and the Gerdy tubercle,¹⁶16 Getty R. Sisson/Grossman. Anatomia dos animais domésticos. 5a ed. Rio de Janeiro: Interamericana; 1981 as described by Vicente et al¹⁷17 Vincent JP, Magnussen RA, Gezmez F, Uguen A, JacobiM,Weppe F, et al. The anterolateral ligament of the human knee: an anatomic and histologic study. Knee Surg Sports Traumatol Arthrosc 2012; 20(01):147-152 and by Helito et al.⁵5 Helito CP, Demange MK, Bonadio MB, Tírico LE, Gobbi RG, Pécora JR, et al. Anatomy and histology of the knee anterolateral ligament. Orthop J Sports Med 2013;1(07):2325967113513546 ¹⁸18 Helito CP, Miyahara HS, Bonadio MB, Tirico EL, Gobbi RG, Demange MK, et al. Anatomical study of the anterolateral ligament of the knee. Rev Bras Ortop 2013;48(04):368-373

Sample Preparation

After the preparation of the sample, the graft was fixed to the tibia according to the method ascribed to each group.

Group A

Tendon graft fixed with a 5 mm anchor (Hexagon) and Ultrabraid suture passing through the part, with 5 surgical knots¹⁹19 Cirino LMI. Manual de técnica cirúrgica para a graduac¸ão. São Paulo: Sarvier; 2006 (Pauchet technique) (Fig. 4A).

Fig. 4
A, Group A. B, Group B. C, Group C. D, Group D.

Group B

Tendon graft fixed with a 7 × 20 mm Traumédica metal interference screw into a 6 × 30 mm bone tunnel at mid-distance between the fibular head and the Gerdy tubercle (Fig. 4B).

Group C

Tendon graft fixed with a 5 mm anchor and 5 surgical knots¹⁹19 Cirino LMI. Manual de técnica cirúrgica para a graduac¸ão. São Paulo: Sarvier; 2006 with Ultrabraid wire – Pauchet technique – and suture over the folded tendon (cavalier). Two “arms” were formed, 1 with 8 cm (posterior) fixed at the load cell, and another with 4 cm (anterior), in which a proximal suture was made and again fixed at the load cell, constituting the double graft described by Sonnery-Cottet et al²⁰20 Sonnery-Cottet B, Daggett M, Helito CP, Fayard JM, Thaunat M. Combined anterior cruciate ligament and anterolateral ligament reconstruction. Arthrosc Tech 2016;5(06):e1253-e1259 (Fig. 4C).

Group D

Two bone tunnels were prepared with a 6 × 30 mm drill at 90° angles from each other for communication between them. The tendon was passed through the tunnels, resulting in a graft with two “arms.” The graft arm in the 8 cm posterior tunnel was fixed with a 7 × 20 mm metal interference screw, and the graft arm in the 4 cm anterior tunnel was fixed with a proximal suture and attached to the load cell, constituting the double graft described by Sonnery-Cottet et al²⁰20 Sonnery-Cottet B, Daggett M, Helito CP, Fayard JM, Thaunat M. Combined anterior cruciate ligament and anterolateral ligament reconstruction. Arthrosc Tech 2016;5(06):e1253-e1259 (Fig. 4D).

Biomechanical Tests

The groups were submitted to a tensile biomechanical test with an UPM 200 Universal Tensile Testing Machine with a capacity of 200N and 20T (Schenck, Passo Fundo, RS, Brazil) with a 20 kgf load cell (9 USB (HBM, Inc. Marlborough, MA, USA), and speed of 60 mm/minute. The strength parameters were recorded by a computer with a Spider 8 software system (HBM, Inc. Marlborough, MA, USA) complemented with a Catman Easy 3.1 data acquisition amplifier (HBM, Inc. Marlborough, MA, USA) using the acquisition routines provided by the manufacturer.

The tibias were positioned beneath the load cell attached to the machine by a tubular support secured by a bone screw (Fig. 5). The tendon was fixed as a graft in the proximal tibial region as previously described, so that ∼ 4 cm of tendon remained free and 4 cm were attached to the load cell; the tibial axis was visually aligned with the axis of the machine. During the assembly, the tubular support was fixed to the base of the machine with a bench vise, allowing only the proximal displacement of the tendon, which was attached to the moving element of the machine. The test was performed with the tibia in ∼ 30° of flexion, simulating the ALL tensile angle.

Fig. 5
Tibia position during tests.

The evaluated parameters were the following: maximum limit tensile strength of the different types of ligament fixation, expressed in Newtons; and failure modes. Failures were defined by a sudden drop at the graph curve (N) during testing. The test was then discontinued, and the graph was preliminarily analyzed.

The present study was approved by the Ethics Committee of our University regarding researches with animals under the number CEUA 039/2016.

Statistical Analysis

Data were expressed as mean, standard deviation (SD) and coefficient of variation (CV) for numerical variables, and as absolute frequencies for the categorical variable.

The sample size was determined from data from previous studies.⁹9 Parsons EM, Gee AO, Spiekerman C, Cavanagh PR. The biomechanical function of the anterolateral ligament of the knee. Am J Sports Med 2015;43(03):669-674 ²¹21 Yang DL, Cheon SH, Oh CW, Kyung HS. A comparison of the fixation strengths provided by different intraosseous tendon lengths during anterior cruciate ligament reconstruction: a biomechanical study in a porcine tibial model. Clin Orthop Surg 2014;6(02):173-179 ²²22 Altman DG. Practical statistics for medical research. London: Chapman & Hall Publishers; 1991 The tensile strength was compared between groups with an F test (analysis of variance [ANOVA]) with multiple size comparisons. Data normality and equality of variances hypothesis were respectively determined by the Shapiro-Wilk and by the Levene tests, and size comparisons were used due to the rejection of equality of variances between the groups.²²22 Altman DG. Practical statistics for medical research. London: Chapman & Hall Publishers; 1991 ²³23 Conover WJ. Practical nonparametric statistics. New York: John Wiley & Sons; 1980

The margin of error used in the statistical test decision was 5.0%. Data was entered in an Excel (Microsoft Corporation, Redmond, WA, USA) spreadsheet, and the statistical calculations were performed with IBM SPSS Statistics for Windows, Version 23.0 (IBM Corp., Armonk, NY, USA).²²22 Altman DG. Practical statistics for medical research. London: Chapman & Hall Publishers; 1991 ²³23 Conover WJ. Practical nonparametric statistics. New York: John Wiley & Sons; 1980

Results

Table 1 shows the statistical data of the plateau width from each group, highlighting a very small variability.

The maximum CV was 5.74%, evidencing the high homogeneity of tibia size in each group.

Table 2 shows the average strength in each group. For the fixed margin of error (5%), there was a significant difference between the groups (p< 0.001), whereas multiple comparison tests (between group pairs) demonstrated significant differences, except for groups C and D.

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Table 2
Mean force per group

The variability expressed by the CV was reasonably elevated in group D, being > 50%, and it was deemed reduced in the remaining groups, which presented values < 33.3%.

Table 3 presents the types of failures in each group. The most frequent were: nine cases of failure by graft rupture in group A; eight cases of tibial tunnel graft slip in group B; seven cases of second arm proximal knot loosening in group C; and six cases of tibial cortical breakage in group D.

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Table 3
Failure type per group

Discussion

The models were submitted to biomechanical tests to allow the direct comparison of different techniques and fixation devices of the substitute ALL graft in swine tibias.

The fixation with interference screws in a single bone tunnel had the highest tensile strength for ALL reconstruction, being adequate to the human native ligament requirement as shown by Helito et al,²⁴24 Helito CP, BonadioMB, Rozas JS,Wey JM, Pereira CA, CardosoTP, et al. Biomechanical study of strength and stiffness of the knee anterolateral ligament. BMC Musculoskelet Disord 2016;17:193 who demonstrated the ALL biomechanics resistance with a maximum strength of 204.8 N and an average stiffness of 41.9 N/mm. These results allow the selection of suitable grafts and fixation methods for possible ALL reconstructions associated with ACL reconstructions.²⁴24 Helito CP, BonadioMB, Rozas JS,Wey JM, Pereira CA, CardosoTP, et al. Biomechanical study of strength and stiffness of the knee anterolateral ligament. BMC Musculoskelet Disord 2016;17:193 This suggests that the single bands of all grafts, both autologous or homologous, commonly used in the clinical practice for knee ligament reconstruction, have the required biomechanical resistance features,²⁴24 Helito CP, BonadioMB, Rozas JS,Wey JM, Pereira CA, CardosoTP, et al. Biomechanical study of strength and stiffness of the knee anterolateral ligament. BMC Musculoskelet Disord 2016;17:193 emphasizing the importance of “sufficient” fixation methods.

The attachment of soft tissues, such as ligaments, to bone is routinely used in orthopedic surgery and sports medicine.²⁵25 Cole BJ, Sayegh ET, Yanke AB, Chalmers PN, Frank RM. Fixation of soft tissue to bone: techniques and fundamentals. J Am Acad Orthop Surg 2016;24(02):83-95 ²⁶26 Suchenski M, McCarthy MB, Chowaniec D, Hansen D, McKinnon W, Apostolakos J, et al. Material properties and composition of soft-tissue fixation. Arthroscopy 2010;26(06):821-831 Fixation with interference screws provides a tight fit between the bone, the graft/tendon and the screw, being frequently used to attach replacement ligaments in drilled tunnels for ligament reconstruction. Suture anchors are used in surgical procedures when tissue attachment to a bone surface is required.²⁶26 Suchenski M, McCarthy MB, Chowaniec D, Hansen D, McKinnon W, Apostolakos J, et al. Material properties and composition of soft-tissue fixation. Arthroscopy 2010;26(06):821-831 The ideal method should provide adequate mechanical fixation and strength equal to or greater than those occurring in rehabilitation before tendon graft integration to the bone.²⁵25 Cole BJ, Sayegh ET, Yanke AB, Chalmers PN, Frank RM. Fixation of soft tissue to bone: techniques and fundamentals. J Am Acad Orthop Surg 2016;24(02):83-95 ²⁶26 Suchenski M, McCarthy MB, Chowaniec D, Hansen D, McKinnon W, Apostolakos J, et al. Material properties and composition of soft-tissue fixation. Arthroscopy 2010;26(06):821-831

In groups A and C, using anchors as the fixation method, the transtendinous suture was shown to weaken the graft, making it more vulnerable to lower tensile loads. This was exemplified by the mean inferiority of group A (70 N) compared with group C (149 N). However, anchors allow direct implantation (with no need for drilling, threading or predrilling) with a self-insertion tip, in addition to improving and tensioning individual sutures. Suture anchors produce tension throughout the tendon-bone interface. The size and positioning of the implant on cortical or spongy bone determines the strength of the fixation.²¹21 Yang DL, Cheon SH, Oh CW, Kyung HS. A comparison of the fixation strengths provided by different intraosseous tendon lengths during anterior cruciate ligament reconstruction: a biomechanical study in a porcine tibial model. Clin Orthop Surg 2014;6(02):173-179 Barber et al²⁷27 Barber FA, Herbert MA, Coons DA, Boothby MH. Sutures and suture anchors-update 2006. Arthroscopy 2006;22;10. 1063.e1- -1069.e1 concluded that some more recent suture anchors showed significant improvements in load-to-failure values when compared to braided polyester sutures. Therefore, it is observed that the suture material also influences the failure mode.²⁷27 Barber FA, Herbert MA, Coons DA, Boothby MH. Sutures and suture anchors-update 2006. Arthroscopy 2006;22;10. 1063.e1- -1069.e1

In the present study, the fixation in groups B and D was performed with interference screws. In group B, only one bone tunnel was made; in group D, two divergent tunnels were prepared and communicated to the graft passage, as reported. Group B presented a higher tensile strength compared to the other groups, whereas group D showed early failure in all of the samples, such as cortical breakage and a tensile strength discrepancy with a reasonably high CV. Therefore, we conclude that this surgical technique is not reproducible in swine bones, requiring other tests in human bones. The failure patterns (Table 3) resulting from the tensile strength in each group show that the failure mechanism was variable, depending on the fixation method, with one type of failure predominating in each group.

A potential bias of our study was the use of swine knees. Nurmi et al²⁸28 Nurmi JT, Sievänen H, Kannus P, Järvinen M, Järvinen TL. Porcine tibia is a poor substitute for human cadaver tibia for evaluating interference screw fixation. Am J Sports Med 2004;32(03): 765-771 reported that the trabecular bone density of the pig tibia was significantly higher compared with the human tibia at a peripheral computed tomography (CT) quantitative scanning.²⁸28 Nurmi JT, Sievänen H, Kannus P, Järvinen M, Järvinen TL. Porcine tibia is a poor substitute for human cadaver tibia for evaluating interference screw fixation. Am J Sports Med 2004;32(03): 765-771 ²⁹29 Kim MK, Na SI, Lee JM, Park JY. Comparison of bioabsorbable suture anchor fixation on the tibial side for anterior cruciate ligament reconstruction using free soft tissue graft: experimental laboratory study on porcine bone. Yonsei Med J 2014;55(03):760-765 Despite this, swine tibias were often used in similar experimental studies (mainly for ACL reconstructions), and no significant differences were found regarding the use of interference screws for graft fixation in pigs and humans.²¹21 Yang DL, Cheon SH, Oh CW, Kyung HS. A comparison of the fixation strengths provided by different intraosseous tendon lengths during anterior cruciate ligament reconstruction: a biomechanical study in a porcine tibial model. Clin Orthop Surg 2014;6(02):173-179 In a previous study about interference screw graft fixation in swine and human bones, the maximum differences in tensile strength were insignificant.²⁸28 Nurmi JT, Sievänen H, Kannus P, Järvinen M, Järvinen TL. Porcine tibia is a poor substitute for human cadaver tibia for evaluating interference screw fixation. Am J Sports Med 2004;32(03): 765-771 Direct comparisons among human specimens are challenging due to the difficulty of controlling factors such as differences in donor age and in bone density. Therefore, we have decided to use swine bones, allowing us to control these factors.²⁹29 Kim MK, Na SI, Lee JM, Park JY. Comparison of bioabsorbable suture anchor fixation on the tibial side for anterior cruciate ligament reconstruction using free soft tissue graft: experimental laboratory study on porcine bone. Yonsei Med J 2014;55(03):760-765 ³⁰30 Scheffler SU, Südkamp NP, Göckenjan A, Hoffmann RF, Weiler A. Biomechanical comparison of hamstring and patellar tendon graft anterior cruciate ligament reconstruction techniques: The impact of fixation level and fixation method under cyclic loading. Arthroscopy 2002;18(03):304-315 ³¹31 Suggs J, Wang C, Li G. The effect of graft stiffness on knee joint biomechanics after ACL reconstruction-a 3D computational simulation. Clin Biomech (Bristol, Avon) 2003;18(01):35-43

Another potential bias relates to the location of the ALL, visually determined by the surgeon while building the parts. The tension was linear instead of rotational, as in humans, and slow, rather than fast, as in sprains.

In other studies, the tibial ALL fixation point was also constant and slightly posterior to midway between the Gerdy tubercle and the fibular head. This fixation may be associated with a Segond fracture, an anterolateral tibial bone avulsion found in about 9% of the patients with ACL ruptures.⁵5 Helito CP, Demange MK, Bonadio MB, Tírico LE, Gobbi RG, Pécora JR, et al. Anatomy and histology of the knee anterolateral ligament. Orthop J Sports Med 2013;1(07):2325967113513546 ⁷7 Claes S, Vereecke E, Maes M, Victor J, Verdonk P, Bellemans J. Anatomy of the anterolateral ligament of the knee. J Anat 2013; 223(04):321-328 ³²32 Hess T, Rupp S, Hopf T, Gleitz M, Liebler J. Lateral tibial avulsion fractures and disruptions to the anterior cruciate ligament. A clinical study of their incidence and correlation. Clin Orthop Relat Res 1994;(303):193-197

The present study involved the zero-time biomechanical test in immediate postoperative conditions. Therefore, no histological comparison was possible.¹³13 Beynnon BD, Johnson RJ, Fleming BC, Kannus P, KaplanM, Samani J, et al. Anterior cruciate ligament replacement: comparison of bone-patellar tendon-bone grafts with two-strand hamstring grafts. A prospective, randomized study. J Bone Joint Surg Am 200284-A(09):1503-1513 Lastly, neither the graft slippage measurement to reduce error, nor intra- or interobserver reliability tests were performed.

Conclusion

Fixation with an interference screw in a single bone tunnel had the highest tensile strength among the evaluated techniques. The converging tunnels in swine tibia were not reproducible, requiring additional tests in human bones for further evaluation.

References

¹
Mall NA, Chalmers PN, Moric M, Tanaka MJ, Cole BJ, Bach BR Jr, et al. Incidence and trends of anterior cruciate ligament reconstruction in the United States. Am J Sports Med 2014;42(10): 2363-2370
²
Schon JM, Moatshe G, Brady AW, Cruz RS, Chahla J, Dornan GJ, et al. Anatomic Anterolateral Ligament Reconstruction of the Knee Leads to Overconstraint at Any Fixation Angle. Am J Sports Med 2016;44(10):2546-2556
³
Helito CP, Bonadio MB, Gobbi RG, da Mota E Albuquerque RF, Pécora JR, Camanho GL, et al. Combined intra- and extra-articular reconstruction of the anterior cruciate ligament: the reconstruction of the knee anterolateral ligament. Arthrosc Tech 2015;4 (03):e239-e244
⁴
Sonnery-Cottet B, Thaunat M, Freychet B, Pupim BH, Murphy CG, Claes S. Outcome of a combined anterior cruciate ligament and anterolateral ligament reconstruction techniquewith aminimum 2-year follow-up. Am J Sports Med 2015;43(07):1598-1605
⁵
Helito CP, Demange MK, Bonadio MB, Tírico LE, Gobbi RG, Pécora JR, et al. Anatomy and histology of the knee anterolateral ligament. Orthop J Sports Med 2013;1(07):2325967113513546
⁶
Segond P. Recherchescliniques et experimentalessur les ép anchementssanguins du genou par entorse. Paris: Aux Bureaux du Progres Medical; 1879
⁷
Claes S, Vereecke E, Maes M, Victor J, Verdonk P, Bellemans J. Anatomy of the anterolateral ligament of the knee. J Anat 2013; 223(04):321-328
⁸
Kennedy MI, Claes S, Fuso FA, Williams BT, Goldsmith MT, Turnbull TL, et al. The anterolateral ligament: an anatomic, radiographic, and biomechanical analysis. Am J Sports Med 2015;43 (07):1606-1615
⁹
Parsons EM, Gee AO, Spiekerman C, Cavanagh PR. The biomechanical function of the anterolateral ligament of the knee. Am J Sports Med 2015;43(03):669-674
¹⁰
Spencer L, Burkhart TA, Tran MN, Rezansoff AJ, Deo S, Caterine S, et al. Biomechanical analysis of simulated clinical testing and reconstruction of the anterolateral ligament of the knee. Am J Sports Med 2015;43(09):2189-2197
¹¹
Dodds AL, Gupte CM, Neyret P, Williams AM, Amis AA. Extraarticular techniques in anterior cruciate ligament reconstruction: a literature review. J Bone Joint Surg Br 2011;93(11):1440-1448
¹²
Maletis GB, Cameron SL, Tengan JJ, Burchette RJ. A prospective randomized study of anterior cruciate ligament reconstruction: a comparison of patellar tendon and quadruple-strand semitendinosus/ gracilis tendons fixed with bioabsorbable interference screws. Am J Sports Med 2007;35(03):384-394
¹³
Beynnon BD, Johnson RJ, Fleming BC, Kannus P, KaplanM, Samani J, et al. Anterior cruciate ligament replacement: comparison of bone-patellar tendon-bone grafts with two-strand hamstring grafts. A prospective, randomized study. J Bone Joint Surg Am 200284-A(09):1503-1513
¹⁴
Kamath GV, Redfern JC, Greis PE, Burks RT. Revision anterior cruciate ligament reconstruction. Am J Sports Med 2011;39(01): 199-217
¹⁵
Harvey A, Thomas NP, Amis AA. Fixation of the graft in reconstruction of the anterior cruciate ligament. J Bone Joint Surg Br 2005;87(05):593-603
¹⁶
Getty R. Sisson/Grossman. Anatomia dos animais domésticos. 5a ed. Rio de Janeiro: Interamericana; 1981
¹⁷
Vincent JP, Magnussen RA, Gezmez F, Uguen A, JacobiM,Weppe F, et al. The anterolateral ligament of the human knee: an anatomic and histologic study. Knee Surg Sports Traumatol Arthrosc 2012; 20(01):147-152
¹⁸
Helito CP, Miyahara HS, Bonadio MB, Tirico EL, Gobbi RG, Demange MK, et al. Anatomical study of the anterolateral ligament of the knee. Rev Bras Ortop 2013;48(04):368-373
¹⁹
Cirino LMI. Manual de técnica cirúrgica para a graduac¸ão. São Paulo: Sarvier; 2006
²⁰
Sonnery-Cottet B, Daggett M, Helito CP, Fayard JM, Thaunat M. Combined anterior cruciate ligament and anterolateral ligament reconstruction. Arthrosc Tech 2016;5(06):e1253-e1259
²¹
Yang DL, Cheon SH, Oh CW, Kyung HS. A comparison of the fixation strengths provided by different intraosseous tendon lengths during anterior cruciate ligament reconstruction: a biomechanical study in a porcine tibial model. Clin Orthop Surg 2014;6(02):173-179
²²
Altman DG. Practical statistics for medical research. London: Chapman & Hall Publishers; 1991
²³
Conover WJ. Practical nonparametric statistics. New York: John Wiley & Sons; 1980
²⁴
Helito CP, BonadioMB, Rozas JS,Wey JM, Pereira CA, CardosoTP, et al. Biomechanical study of strength and stiffness of the knee anterolateral ligament. BMC Musculoskelet Disord 2016;17:193
²⁵
Cole BJ, Sayegh ET, Yanke AB, Chalmers PN, Frank RM. Fixation of soft tissue to bone: techniques and fundamentals. J Am Acad Orthop Surg 2016;24(02):83-95
²⁶
Suchenski M, McCarthy MB, Chowaniec D, Hansen D, McKinnon W, Apostolakos J, et al. Material properties and composition of soft-tissue fixation. Arthroscopy 2010;26(06):821-831
²⁷
Barber FA, Herbert MA, Coons DA, Boothby MH. Sutures and suture anchors-update 2006. Arthroscopy 2006;22;10. 1063.e1- -1069.e1
²⁸
Nurmi JT, Sievänen H, Kannus P, Järvinen M, Järvinen TL. Porcine tibia is a poor substitute for human cadaver tibia for evaluating interference screw fixation. Am J Sports Med 2004;32(03): 765-771
²⁹
Kim MK, Na SI, Lee JM, Park JY. Comparison of bioabsorbable suture anchor fixation on the tibial side for anterior cruciate ligament reconstruction using free soft tissue graft: experimental laboratory study on porcine bone. Yonsei Med J 2014;55(03):760-765
³⁰
Scheffler SU, Südkamp NP, Göckenjan A, Hoffmann RF, Weiler A. Biomechanical comparison of hamstring and patellar tendon graft anterior cruciate ligament reconstruction techniques: The impact of fixation level and fixation method under cyclic loading. Arthroscopy 2002;18(03):304-315
³¹
Suggs J, Wang C, Li G. The effect of graft stiffness on knee joint biomechanics after ACL reconstruction-a 3D computational simulation. Clin Biomech (Bristol, Avon) 2003;18(01):35-43
³²
Hess T, Rupp S, Hopf T, Gleitz M, Liebler J. Lateral tibial avulsion fractures and disruptions to the anterior cruciate ligament. A clinical study of their incidence and correlation. Clin Orthop Relat Res 1994;(303):193-197

*
Work developed at the Instituto de Ortopedia e Traumatologia of Passo Fundo, RS, Brazil

Publication Dates

Publication in this collection
03 June 2019
Date of issue
Mar-Apr 2019

History

Received
06 July 2017
Accepted
21 Sept 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[3] ³
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Kennedy MI, Claes S, Fuso FA, Williams BT, Goldsmith MT, Turnbull TL, et al. The anterolateral ligament: an anatomic, radiographic, and biomechanical analysis. Am J Sports Med 2015;43 (07):1606-1615

[9] ⁹
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[10] ¹⁰
Spencer L, Burkhart TA, Tran MN, Rezansoff AJ, Deo S, Caterine S, et al. Biomechanical analysis of simulated clinical testing and reconstruction of the anterolateral ligament of the knee. Am J Sports Med 2015;43(09):2189-2197

[11] ¹¹
Dodds AL, Gupte CM, Neyret P, Williams AM, Amis AA. Extraarticular techniques in anterior cruciate ligament reconstruction: a literature review. J Bone Joint Surg Br 2011;93(11):1440-1448

[12] ¹²
Maletis GB, Cameron SL, Tengan JJ, Burchette RJ. A prospective randomized study of anterior cruciate ligament reconstruction: a comparison of patellar tendon and quadruple-strand semitendinosus/ gracilis tendons fixed with bioabsorbable interference screws. Am J Sports Med 2007;35(03):384-394

[13] ¹³
Beynnon BD, Johnson RJ, Fleming BC, Kannus P, KaplanM, Samani J, et al. Anterior cruciate ligament replacement: comparison of bone-patellar tendon-bone grafts with two-strand hamstring grafts. A prospective, randomized study. J Bone Joint Surg Am 200284-A(09):1503-1513

[14] ¹⁴
Kamath GV, Redfern JC, Greis PE, Burks RT. Revision anterior cruciate ligament reconstruction. Am J Sports Med 2011;39(01): 199-217

[15] ¹⁵
Harvey A, Thomas NP, Amis AA. Fixation of the graft in reconstruction of the anterior cruciate ligament. J Bone Joint Surg Br 2005;87(05):593-603

[16] ¹⁶
Getty R. Sisson/Grossman. Anatomia dos animais domésticos. 5a ed. Rio de Janeiro: Interamericana; 1981

[17] ¹⁷
Vincent JP, Magnussen RA, Gezmez F, Uguen A, JacobiM,Weppe F, et al. The anterolateral ligament of the human knee: an anatomic and histologic study. Knee Surg Sports Traumatol Arthrosc 2012; 20(01):147-152

[18] ¹⁸
Helito CP, Miyahara HS, Bonadio MB, Tirico EL, Gobbi RG, Demange MK, et al. Anatomical study of the anterolateral ligament of the knee. Rev Bras Ortop 2013;48(04):368-373

[19] ¹⁹
Cirino LMI. Manual de técnica cirúrgica para a graduac¸ão. São Paulo: Sarvier; 2006

[20] ²⁰
Sonnery-Cottet B, Daggett M, Helito CP, Fayard JM, Thaunat M. Combined anterior cruciate ligament and anterolateral ligament reconstruction. Arthrosc Tech 2016;5(06):e1253-e1259

[21] ²¹
Yang DL, Cheon SH, Oh CW, Kyung HS. A comparison of the fixation strengths provided by different intraosseous tendon lengths during anterior cruciate ligament reconstruction: a biomechanical study in a porcine tibial model. Clin Orthop Surg 2014;6(02):173-179

[22] ²²
Altman DG. Practical statistics for medical research. London: Chapman & Hall Publishers; 1991

[23] ²³
Conover WJ. Practical nonparametric statistics. New York: John Wiley & Sons; 1980

[24] ²⁴
Helito CP, BonadioMB, Rozas JS,Wey JM, Pereira CA, CardosoTP, et al. Biomechanical study of strength and stiffness of the knee anterolateral ligament. BMC Musculoskelet Disord 2016;17:193

[25] ²⁵
Cole BJ, Sayegh ET, Yanke AB, Chalmers PN, Frank RM. Fixation of soft tissue to bone: techniques and fundamentals. J Am Acad Orthop Surg 2016;24(02):83-95

[26] ²⁶
Suchenski M, McCarthy MB, Chowaniec D, Hansen D, McKinnon W, Apostolakos J, et al. Material properties and composition of soft-tissue fixation. Arthroscopy 2010;26(06):821-831

[27] ²⁷
Barber FA, Herbert MA, Coons DA, Boothby MH. Sutures and suture anchors-update 2006. Arthroscopy 2006;22;10. 1063.e1- -1069.e1

[28] ²⁸
Nurmi JT, Sievänen H, Kannus P, Järvinen M, Järvinen TL. Porcine tibia is a poor substitute for human cadaver tibia for evaluating interference screw fixation. Am J Sports Med 2004;32(03): 765-771

[29] ²⁹
Kim MK, Na SI, Lee JM, Park JY. Comparison of bioabsorbable suture anchor fixation on the tibial side for anterior cruciate ligament reconstruction using free soft tissue graft: experimental laboratory study on porcine bone. Yonsei Med J 2014;55(03):760-765

[30] ³⁰
Scheffler SU, Südkamp NP, Göckenjan A, Hoffmann RF, Weiler A. Biomechanical comparison of hamstring and patellar tendon graft anterior cruciate ligament reconstruction techniques: The impact of fixation level and fixation method under cyclic loading. Arthroscopy 2002;18(03):304-315

[31] ³¹
Suggs J, Wang C, Li G. The effect of graft stiffness on knee joint biomechanics after ACL reconstruction-a 3D computational simulation. Clin Biomech (Bristol, Avon) 2003;18(01):35-43

[32] ³²
Hess T, Rupp S, Hopf T, Gleitz M, Liebler J. Lateral tibial avulsion fractures and disruptions to the anterior cruciate ligament. A clinical study of their incidence and correlation. Clin Orthop Relat Res 1994;(303):193-197

Group	Mean	Standard deviation	Coefficient of variation (%)
A	66.70	2.41	3.61
B	65.90	2.85	4.32
C	66.90	3.84	5.74
D	67.90	2.38	3.51

Groups	Mean	Standard deviation	Coefficient of variation (%)
A	70.56^a	12.49	17.70
B	244.85^b	34.89	14.25
C	171.68^c	21.56	12.56
D	149.43^c	85.44	57.17
p-value p^a< 0,001^* Significant difference at 5%. a Per F test (Anova) with comparison per size test. Distinct subscribed letters indicate significant differences between corresponding groups.

Failure type	Group
Failure type	A(n)	B(n)	C(n)	D(n)
Graft rupture	9	2	−	3
Knot loosening	1	−	−	−
Tibial tunnel graft slips	−	8	−	−
Second arm proximal knot loosening	−	−	7	−
Distal knot loosening	−	−	2	−
Anchor loosening	−	−	1	−
Cortical rupture	−	−	−	6
Femoral fixation loosening	−	−	−	1
Total	10	10	10	10

Brasil

Brasil

Biomechanical Evaluation of Different Tibial Fixation Methods in the Reconstruction of the Anterolateral Ligament in Swine Bones^* * Work developed at the Instituto de Ortopedia e Traumatologia of Passo Fundo, RS, Brazil

Abstract

Objective

Methods

Results

Conclusion

Resumo

Objetivo

Métodos

Resultados

Conclusão

Introduction

Material and Methods

Surgical Technique

Sample Preparation

Group A

Group B

Group C

Group D

Biomechanical Tests

Statistical Analysis

Results

Discussion

Conclusion

References

Publication Dates

History

Brasil

Brasil

Biomechanical Evaluation of Different Tibial Fixation Methods in the Reconstruction of the Anterolateral Ligament in Swine Bones* * Work developed at the Instituto de Ortopedia e Traumatologia of Passo Fundo, RS, Brazil

Abstract

Objective

Methods

Results

Conclusion

Resumo

Objetivo

Métodos

Resultados

Conclusão

Introduction

Material and Methods

Surgical Technique

Sample Preparation

Group A

Group B

Group C

Group D

Biomechanical Tests

Statistical Analysis

Results

Discussion

Conclusion

References

Publication Dates

History

Biomechanical Evaluation of Different Tibial Fixation Methods in the Reconstruction of the Anterolateral Ligament in Swine Bones^* * Work developed at the Instituto de Ortopedia e Traumatologia of Passo Fundo, RS, Brazil