Anterior Cruciate Ligament Rupture Clinical Trial
Official title:
Radiological Follow-up of Alternative ACL Reconstruction Technique
Following recent advances in the understanding of successful anterior cruciate ligament (ACL) reconstruction, three important factors have been identified: femoral tunnel positioning, femoral tunnel aperture shape, and native remnant preservation. Accordingly, the researchers have adapted their technique to address these goals. This study is designed to assess the feasibility of evaluating these graft characteristics, on post-operative imaging, and the ability to show potential improvements with the researchers' technical changes. The study plans to use three-dimensional computer tomography (3D-CT) and magnetic resonance imaging (MRI) to assess these properties and the integration of the graft. In addition, the researchers will use their routine functional scores to monitor the patients' outcome. If successful, the research team hope to set-up a randomised control trial of this alternative technique versus conventional methods with assessment through the same imaging mediums and clinical follow-up.
Rupture of the ACL has an incidence of 30 cases per 100,000 individuals in the UK. The number
of reconstructions performed is increasing as more patients wish to maintain optimum knee
function and stability, in older age-groups, than previously seen. The research centre
(hospital) presently performs between 100 and 150 ACL reconstructions each year but, thus,
this figure is likely to continue to rise.
The ACL performs a role in preventing anterior translation of the tibia on the femur,
throughout the range of motion of the knee, but also provides rotational stability.
Inadequate post-injury function, or failure, can result in continued feeling of instability
(within the knee) and this may prevent return to employment as well as recreational
activities. This is of particular importance to heavy manual workers and competitors in
change-of-direction sports.
Reconstruction of the ACL most commonly involves the use of autologous hamstring or patellar
tendon grafts that are implanted during an arthroscopic procedure. Rehabilitation, following
reconstruction, is lengthy as the graft takes months to incorporate and over a year to regain
mechanical properties. Therefore, these patients undergo a long period of functional
rehabilitation, under the guidance of the physiotherapists, with repeated outpatient surgical
follow-up to assess recovery and detect rare (but important) complications of surgery.
As understanding of the anatomy and biomechanics of the ACL has improved, the techniques used
to perform this procedure have evolved accordingly. The goals of reconstructive surgery are
to restore stability to the knee and allow the patient to return to employment and
recreational activities. Research over the last 5 years has increasingly turned to defining
the anatomy of this ligament and positioning the graft in an anatomical position. Bony
landmarks have been identified for the position of the femoral footprint of the ACL - the
intercondylar and bifurcate ridges - making positioning of the graft accurately possible.
Appreciation of the importance of the remnant tissue - as an indication of previous
attachment and as a conduit for revascularisation of the graft - and these bony landmarks for
the tibial and femoral attachments, of the ligament, have led to changes in surgical
philosophy and technique.
Of particular interest is the femoral tunnel. Successful ACL reconstruction has clearly been
shown to be associated with femoral tunnel positioning so that the graft is centred in the
original footprint and replicates the normal biomechanics of the knee. As there is a degree
of variation between individuals, previous methods of positioning the graft relative to other
structures (or using surrogate measurements) have been superseded by the need to identify
these remaining anatomical landmarks. Therefore, operative technique has focussed on femoral
footprint identification and centring the graft within this area.
Standard techniques, using a 30-degree arthroscope, provide limited views of both the femoral
and tibial footprints. This is due to the orientation of these structures within the knee -
parallel to the direction the arthroscope is introduced into the knee through the lateral
portal. Remnant ACL tissue is removed, to improve visualisation and prevent impingement, as
this was felt to be beneficial. As it is now recognised that remnant preservation is
important, two conflicting challenges exist. The first is to improve visualisation whilst the
second is to preserve the ACL stump as much as possible.
Attempts to improve the view obtained have led some surgeons to suggest introducing the
arthroscope through a medial portal. However, this is not without additional problems such as
instrument overcrowding and fluid leak from the knee. A 70-degree arthroscope increases the
field of vision (particularly of structures parallel to the scope) without having to make
additional portal sites. Therefore, the researchers have begun using this instrument within
their team. Although, by improving the view, the researchers think this has improved
positioning of the graft, it is difficult to assess either intra-operatively or on
post-operative plain radiographs. 3D-CT is a validated and accurate tool for the assessment
of femoral tunnel placement in the post-operative patient. Previous studies have been able to
use this to measure the position of the tunnel, the tunnel aperture dimensions and the volume
of the tunnel within the bone.
Visualisation can also be affected by the reamers used to create the tunnels for the graft.
Traditional reamers are used over rigid wires. In order to introduce them into the knee,
without causing damage to other structures, the knee must be maximally flexed. This leads to
problems with the flow of the arthroscopy fluid (in a confined space) and may cloud of the
operative field. This may be impossible to achieve in obese or well-muscled patients and the
result is that some reaming takes place without a good view of positioning. A flexible
reaming system can be used with the knee in a less flexed position further improving the view
obtained. In addition, as the flexible guidewire (for the flexible reamers) enters the
femoral wall more obliquely, the aperture created by the circular reamer is more oval in
shape and length of the femoral tunnel may also be improved. This potentially means greater
volume of graft within the femur and greater surface area for integration. The aperture
shape, length and volume of this femoral tunnel can be further studied on the 3D-CT. This
study of the femoral tunnel characteristics will be compared to both intra-operative
assessments of position and size as, if there is good correlation, simpler techniques may be
used in the future without the need for each patient to have a CT scan. A single CT study
will be sufficient to make an assessment of these parameters for this study.
The research team have previously published a novel technique (using a 70-degree arthroscope)
to achieve better visualisation of the footprints and give the surgeon a better chance of
positioning the graft within the desired area (the native ACL footprint). Another group have
published the combined technique of the 70-degree arthroscope and flexible reamers suggesting
the advantages we anticipate in terms of tunnel characteristics. The researchers wish to
formally evaluate the success of this alternative method against standard techniques.
The goal of ACL remnant preservation (and placement of the tunnels within this tissue) has
been shown to result in increased revascularisation of the graft, increased
cell-proliferation, and improved proprioception in the knee post-operatively. However, it has
not been shown whether newer techniques (such as use of a 70-degree arthroscope and flexible
reamers) impact on the ability of the surgeon to achieve this. Therefore, comparison of the
healing rates and ligament appearances between those performed using this modified technique
versus traditional methods is of interest. MRI is sensitive for the visualisation of
soft-tissue structures. The researchers will, therefore, use this modality to evaluate the
graft and remnant tissue. This will allow the research team to assess both position of the
graft, within the remnant tissue, and integration of this graft over time. Other groups have
been able to use MRI in this way to assess revascularisation of the graft and the maturation
of graft material over time.
As the MRI will be used to assess graft integration, this will need to be repeated
(throughout the follow-up period) to make serial measurements and quantify this progression.
If the researchers can show that it is feasible to replicate the previous successful use of
MRI (as well as CT), and record a clear difference with the use of the flexible reamers and
70-degree arthroscope, they can lead on into a randomised control trial (RCT) of their
technique versus standard methods. The researchers hope to demonstrate not only can CT and
MRI be used to accurately measure graft position, tunnel shape and healing but also a
difference between techniques in the main trial. As the standard techniques are used by other
surgeons within the research team's department, this will provide the researchers with access
to a comparative group. The team will be able to record results in both arms, which will
provide information for conducting a full scale RCT. It will also allow for quantification of
the changes the researchers can expect to be measuring, in an RCT, which will aid the power
calculations required to guide recruitment numbers.
The required additional imaging can be timed with routine out-patient follow-up appointments.
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