The Stability-Conservative Anterior Cruciate Ligament Reconstruction Rehabilitation Protocol


Introduction

The primary goal of anterior cruciate ligament reconstruction (ACLR) is to restore stability without sacrificing mobility or strength. The primary purpose of ACLR rehabilitation is to restore mobility and strength without sacrificing stability. It is the central hypothesis of this chapter that overly aggressive rehabilitation is both unnecessary and potentially compromises knee stability. The stability-conservative rehabilitation protocol can best be summarized as follows: Avoid graft strain and abrasion while restoring motion and strength in the early postoperative period.

This is based on the following premises and principles.

Premises

  • 1.

    Stability after ACLR can be compromised by an overly aggressive rehabilitation protocol.

  • 2.

    Full motion and strength can reliably be obtained with a less aggressive approach designed to minimize anterior cruciate ligament (ACL) strain and abrasion in the graft in the first 3 postoperative months when the fixation points and the graft are weak.

  • 3.

    No fixation device will ever be able to guarantee that grafts will not slip and/or elongate during healing if they are strenuously and repetitively strained prior to tunnel healing and relatively complete ligamentization.

  • 4.

    Because only about half of reconstructed knees currently achieve stability that is roughly symmetrical with the other knee (see later discussion), it is important to not sacrifice stability in the name of faster rehabilitation.

Principles

  • 1.

    Restoration of full extension and almost full flexion should be aggressively pursued immediately after surgery, but not hyperextension and hyperflexion, which strain the graft.

  • 2.

    Strengthening, especially of the quadriceps, must be performed only within safe arcs of knee motion to avoid compromising stability.

  • 3.

    Repetitive loading should be avoided within the first 3 postoperative months to avoid strain and tunnel abrasion of the ACL graft beyond that found during activities of daily living.

History

Until the late 1980s, ACL rehabilitation was rendered cautiously on the theory that stability was fragile and strain in the graft needed to be minimized in the early postoperative period to avoid loss of stability. It was well known that grafts lose much of their tensile strength in the first few postoperative months. It was recognized that grafts require time to heal into bone tunnels, before which they are subject to loosening (see Chapter 86 ). Finally, it was also known that quadriceps contractions in the terminal 50 degrees of extension exerted a powerful anterior translational moment on the tibia that strains the ACL. As bone–patellar tendon–bone (BPTB) grafts became popular during the 1980s, it became apparent that many knees became stiff and had prolonged quadriceps weakness. This stiffness was potentially a worse problem than the laxity of ACL deficiency. A stable but stiff knee was more likely to be worse than an unstable knee. In 1990 Shelbourne published his classic paper introducing accelerated rehabilitation. This challenged the then-accepted view that grafts needed to be carefully protected during the first few postoperative months. He stated that his patients who were somewhat noncompliant with his postoperative restrictions and were more active had no greater incidence of instability than the compliant patients. However, these more active patients had less stiffness and weakness. He postulated that “accelerated” early aggressive rehabilitation was thus not harmful and also necessary to ensure restoration of motion and strength. Based on these observations, he developed his accelerated rehabilitation protocol, which is currently used in some form by most ACL surgeons, especially those using BPTB grafts.

Symmetric Stability after Anterior Cruciate Ligament Reconstruction is not Assured

Many surgeons commonly use exercises such as cycling and squats that cause quadriceps contractions in the terminal 50 degrees of extension in the early postoperative period. As shown by the research of Beynnon and others (see Chapter 108 ), these activities exert a significant strain on the ACL. The accelerated rehabilitation protocol states that stability will not be compromised by such ACL-straining activities if the surgery is properly performed. Yet as shown in the most recent meta-analysis to review all such papers and as discussed elsewhere in this book (see Chapter 114 ), symmetrical stability after ACLR is currently achieved in only about half of all reconstructed knees, even in the hands of the very experienced ACL surgeons. Accelerated rehabilitation was developed, in particular, to overcome stiffness and weakness in BPTB patients. However, mean KT-1000 scores for BPTB from the literature showed that 34% of reconstructed knees had more than 2 mm of increased laxity than the normal knee, the stability level usually seen with a partially torn ACL. Of the 66% that were within 2 mm, it is estimated that one-fourth or 17% had exactly 2 mm of increased laxity. Thus 34% + 17% or 51% in all had 2 mm or more increased laxity. This leaves only about half with restoration of stability that is the same as the opposite knee. In addition, 5.9%, or roughly 1 in every 17 knees, had abnormal stability (i.e., a failed graft). Thus some of the most experienced knee surgeons in the world in the current literature are only restoring even approximately symmetrical stability—within 1 mm of the other knee—to half of the operated BPTB knees. Half have stability at a level seen with a partially torn ACL or worse. The point is that full stability after ACLR is not achieved as often as thought, and is certainly not a given. Thus caution with activities, such as rehabilitation therapies that have the potential to destabilize the knee, is warranted.

Why Protect the Graft in the First 3 Months Postoperatively?

Fixation Point Healing

The studies of Milano and others, which are discussed in Chapter 86 , show that soft tissue healing into tunnels can take 2 months or longer. During this time, strain on the graft has the potential to make the fixation slip and the graft lax. This healing occurs several weeks earlier in BPTB grafts than in soft tissue grafts.

Graft Strength

Grafts undergo cell death, edema, and then revascularization in the first few months postoperatively (see Chapter 85 ). During this time the graft loses approximately 75% of its strength.

Thus both fixation strength and interstitial strength are compromised during the first few postoperative months. Strain of the graft can induce laxity by both fixation point slippage and graft elongation from plastic deformation. Cyclical loading has the potential to damage the graft by tunnel abrasion before tunnel healing has occurred.

Muscular Inhibition after Anterior Cruciate Ligament Reconstruction

Effusions, ACL injury, 14,15 and knee pain 16,17 have all been shown to have an inhibitory effect on knee musculature, especially the quadriceps, apparently through afferent inhibition of motor neuron activity. This means that during roughly the first 3 postoperative weeks, when most patients have a large hematoma and some knee pain, it may be difficult or impossible to generate large-enough muscle contractions to strengthen or effectively prevent atrophy. In the past, when we attempted to begin strengthening immediately after surgery, we noticed that strength gains did not occur, probably for this reason. In addition, the exercises produced significant patient discomfort. For this reason we no longer begin strengthening until roughly the end of the third postoperative week for isometric quadriceps, and later for other muscle groups in which atrophy is less of a concern.

Cyclical Loading does Cause Laxity

Every study that has examined this subject has shown that cyclical loading induces elongation of the graft–fixation construct. These studies typically show several millimeters of elongation. 18–20 The best such study showed 1 mm after the first 100 cycles. Many of these studies look only at the first 1000 cycles. 18 One thousand cycles is equal to the number of steps taken in less than 1 week of normal activity and less than 1 week of cycling during rehabilitation. It is highly likely that this elongation would further increase if more cycles were performed. It is important to realize that only 2 mm of elongation from cyclical loading is enough to change the side-to-side difference from −1 to −3 mm, converting good stability to the stability level seen in a partial ACL tear.

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