MRI signal intensity of anterior cruciate ligament graft after transtibial versus anteromedial portal technique (TRANSIG): design of a randomized controlled clinical trial

Rupture of the anterior cruciate ligament (ACL) is a frequently seen (sport) injury mostly induced by a non-contact deceleration motion. The risk of primary ACL rupture has been reported to occur in 1.5 to 1.7 % in healthy athletic population [1]. The ACL provides anterior-posterior and rotational stability to the knee joint. Initially, a rupture of the ACL leads to a synovial layer in the knee joint. The ends of the ruptured ACL tears will shrink and as a result of that, there is no healing process of the ACL. Long term consequences are chronic knee instability and osteoarthritis [2, 3].

There are several surgical techniques to reconstruct the ACL, which vary in graft type, number of bundles, method of fixation and tunnel position. More than 5000 ACL reconstructions are performed in The Netherlands each year [4]. The focus of ACL reconstruction is now changing toward the tunnel position of the ACL grafts since there is no established “gold-standard” technique for ACL reconstruction [5, 6]. The most frequently performed surgical technique is the transtibial (TT) drilling technique in which a femoral tunnel is drilled through the tibial tunnel. In this way, the femoral tunnel is placed non-anatomically relative to the native femoral ACL footprint [7]. Another surgical technique is the anteromedial portal (AMP) anatomic drilling technique which principle is based on restoring the native insertion site anatomy on both tibial and femoral side. The choice of drilling technique is depending on several factors such as surgeon experience, available equipment, patient age, skeletal maturity, body habitus, activity level and graft choice [5].

Robin et al. conducted a systematic review of the advantages and disadvantages of both reconstruction techniques based on 27 articles [5]. The main advantages of TT technique are single incision, isometric graft throughout knee range of motion and minimal tunnel and intercondylar notch impingement. However, disadvantages are that the tibial tunnel dictates the femoral tunnel, vertical and anterior graft placement, increased biomechanical demand during rehabilitation and TT requires notchplasty for visualization.

AMP technique leads to anatomic placement of femoral tunnel and independently tibial tunnel, anteroposterior stability, faster return to activity and useful for revision ACL reconstruction [5]. The main disadvantages of AMP are difficulty visualization in hyperflexion, posterior-wall blowout, technically demanding, limit fixation techniques due to short sockets, increased risk of injury to peroneal nerve and extension loss during stance phase [5].

Currently, there is no consensus which surgical technique elicits the best clinical outcomes. However, TT is the technique until now with long term follow-up results [5, 8].

Success of the ACL reconstruction can be measured by clinical, functional and patient-oriented outcome assessments include physical examination and patient-oriented questionnaires. However, these assessments are an indirect measure of the graft integrity and require large numbers of patients to detect differences between both operation techniques [9]. There is a need for a quantitative in vivo measurements method for the evaluation of the biomechanical performance and integrity of the ACL graft.

Magnetic resonance imaging (MRI) is the most effective and accurate technique for the quantitative in vivo assessment of the ACL with a sensitivity and specificity of more than 90 % [10]. Most common used MRI sequences for assessment of the ACL are turbo spin echo (TSE) sequences such as proton density weighted imaging (PDWI). Normally, an intact ACL appears in all planes as a low-signal linear band with an orientation at least as steep as the intercondylar roof. Between the fibers of the ACL there can be fat or fluid and therefore the ACL is not completely black on PDWI images. Primary signs of ACL rupture are increased signal on MRI, fiber discontinuity, abnormal orientation and undetectable fibers [11].

MRI-derived measures of the signal intensity (SI) of the ACL graft have been described as an independent predictor of graft properties [9]. Lower SI indicates low water and fat content and thus better maturity of the graft. MRI assessment with PDWI fails to correlate SI with actual graft function. A more promising technique is T2*-weighted gradient-echo MRI imaging which has been reported as a useful imaging modality to assess graft integrity [12]. The signal intensity ratio (SIR) can be calculated by:

The purpose of this study is to compare the MRI derived SI measurements of the ACL graft one year after ACL reconstruction, in order to compare the graft integrity of both the AMP and TT ACL reconstruction technique. The anatomical AMP reconstruction technique restores rotational stability. Non-anatomical TT reconstruction technique restores anterior/posterior stability but lesser rotational stability [5]. It is hypothesized that the AMP technique will result in significantly lower MRI signal intensity one year postoperatively and thereby better graft maturity due to the better rotational stability compared to the TT technique. The results of this study may clarify which surgical technique will reveal the best clinical, functional and quantitative MRI outcomes. This paper reports on the study design of the TRANSIG (TRanstibial vs ANteromedial portal technique SIGnal Intensity) trial.

SI measurements with MRI has been used in other clinical studies for evaluation of the ACL graft and maturation after ACL reconstruction compared to clinical and functional outcomes [9, 12, 17, 18]. However, none of these studies used SI to compare the TT technique with the AMP technique. Also, some of these studies examined the feasibility of T2*WI. The T2*WI sequence was more strongly associated with clinical outcomes (KT-2000 arthrometer) [12]. Biercevicz et al. showed also that volume and grayscale values from T2*WI MRI scans are predictive of the healing ligament [9, 18].

The anticipated results are primarily focused on graft maturity assessed by the signal intensity on the MRI SIR measurement one year after operation. It is hypothesized that in performing an anatomical ACL reconstruction, graft maturity will be better compared with the transtibial technique at one year follow up. The background of this hypothesis is the statement that the anatomical oriented ACL graft restores rotational stability in contrast to the transtibial ACL graft that only restores anteroposterior stability. Restoring the rotational stability is the keystone to a successful maturation of the ACL graft. Whether the anatomical technique will be superior to the transtibial one considering the functional results after one year follow up has to be addressed. We will use the IKDC and KOOS evaluation scores as well as the single leg hop test and AP laxity measurement. It is questionable if these parameters will be correlated with the rotational stability. A long term follow up will be necessary. With the IKDC and the KOOS evaluation and the functional tests after 2, 5 and 10 years functional outcome will be evaluated. This will be conducted in another follow up study. At longer time follow up, the risk on revision or a return of the pivot shift and other signs of instability in case of a failure will be clear in both techniques. It is important to realize that many other factors than using an anatomical or transtibial technique (timing operation, meniscal injury, level and type of sports, time when return to sports, age and sex difference man/woman) contribute to a graft failure.

To our knowledge, this is the first study which compares the TT and AMP technique for ACL reconstruction by the use of MRI SI.

This paper describes the design of a randomized controlled trial on the SI of the graft after TT and AMP ACL reconstruction. The results of this study may clarify which surgical technique will reveal the best clinical, functional and quantitative MRI outcomes.

ACL, anterior cruciate ligament; AMP, anteromedial portal; IKDC, International Knee Documentation Committee; KOOS, knee injury and osteoarthritis outcome score; MRI, magnetic resonance imaging; PCL, posterior cruciate ligament; PDWI, proton density weighted imaging; ROI, region of interest; SI, signal intensity; SIR, signal intensity ratio; T2*WI, T2*-weighted imaging; TT, transtibial