Rehabilitation Following Repair of a Torn Latissimus Dorsi Tendon

• Clinical decision making
• Evidence-based practice
• Guidelines
• Rehabilitation
• Rupture
• Shoulder
• Tendon injuries

Physical therapists are called upon to manage a variety of musculoskeletal injuries. For many common injuries, treatment guidelines have been established and documented.1–5 However, therapists also must be prepared to develop intervention plans for unusual diagnoses based on general principles of tissue healing.

The goals of rehabilitation following tendon reconstruction are to restore motion and strength (muscle force-generating capacity) without subjecting the healing tissue to excessive forces that may hinder healing or rupture the repair.⁶ One of the most important clinical considerations is how quickly to advance the patient’s program and in what manner, for instance by increasing resistance, range of motion (ROM), or repetitions. Intervention should be guided by knowledge of the physiology of healing, especially as it influences tissue tensile strength.⁷

Tendon healing progresses through the same overlapping phases as other tissues: inflammation, proliferation, and remodeling.⁸ During the inflammatory phase, the first 3 to 5 days following injury or surgery, phagocytic cells remove devitalized and damaged tissue. Chemicals are released that stimulate fibroblast activity, initiating the transition to the proliferative phase. This second stage can begin as early as 48 hours following injury and can last 6 to 8 weeks. New blood vessels form in the wound to enhance delivery of nutrients to the healing tissue. Fibroblasts multiply and produce new extracellular matrix and collagen. This immature collagen is randomly oriented and has limited strength. The third stage, the remodeling phase, overlaps the latter portion of the proliferative phase and continues for several months. Throughout this phase, collagen gradually becomes oriented along lines of stress, and its structure becomes organized to provide increasing resistance to stretch and tearing.⁹

Mason and Allen⁷ examined the tensile strength of healing flexor carpi ulnaris and extensor carpi radialis tendons in dogs. Following surgery, the involved limb was: (1) immobilized to prevent tensile force on the repair for the duration of the experiment (35 days), (2) immobilized for 21 days, then allowed unrestricted motion, or (3) immobilized for 1 week, then allowed flexion but not extension, which subjected tendons to tensile forces from muscle contraction but not from passive lengthening. The authors found that in the first 3 to 5 days after surgery, tensile strength at the site of laceration, as well as the ability of the tendon to hold sutures, decreased 50% to 75% from the strength immediately following repair. The tensile strength then began a rapid increase, but was not consistently greater than the immediate post-repair strength until 14 days following surgery. Strength continued to increase until day 16 and then reached a plateau. During this period, Mason and Allen observed that progression through the phases of healing and the resulting increase in tensile strength were unaffected by whether or not the limb was immobilized with the tendon slack. Unprotected tendons, however, were much more likely to rupture, due to increased tensile forces with use, than were immobilized tendons.

A second phase of improvement in tensile strength began between days 19 and 21. From this point until the end of the experiment (day 35), tendons in dogs that were allowed active motion (unrestricted motion or flexion only) developed strength much more rapidly than in dogs with immobilized tendons. The authors noted that the period of initial loss of strength appeared to correspond to the “phase of exudation and fibrous union” (inflammatory phase), the first period of strengthening corresponds to the “phase of fibroplasia” (proliferative phase), and the second strengthening period to the “phase of maturation or organizing differentiation” (remodeling).^7(p454) Based on their findings, Mason and Allen⁷ recommended that, in the clinical setting, repaired tendons be immobilized for 2 weeks and then allowed “restricted” use for 1 to 2 weeks. Beyond this time, they suggested that “active use” could be initiated.

Hirsch¹⁰ examined tensile strength in intact peroneus brevis tendons in the rabbit, as well as in tendons that had undergone surgical repair following a laceration. The force required to rupture an intact tendon was found to be about 3 times the maximum force generated by the muscle. Hirsch noted that this force provides a large safety margin, making rupture of healthy tendons unlikely in conventional activities.

For the first 8 weeks following surgery (early remodeling phase), Hirsch¹⁰ found that the force required to rupture a lacerated and repaired tendon was less than the force generated by a maximum muscle contraction. At 24 weeks following surgery, the tensile strength of lacerated and repaired tendons was only 50% of that of healthy intact tendon. These findings suggest that maximum muscle contraction forces should be avoided for at least 8 weeks following tendon repair and that significant tendon weakness exists for a considerable period thereafter. Hirsch performed muscle releases on all of the lacerated and repaired tendons due to the inability to immobilize the limbs in such a way as to prevent excessive force on the repair. He therefore could study only the rate of increasing tensile strength in the absence of tensile stresses.

Gelberman et al¹¹ compared the tensile strength of healing canine flexor tendons that were either immobilized following repair or subjected to passive tensile stresses early or late in the healing process. The flexor tendons of dogs in the control group were immobilized for the duration of the experiment. In the first experimental group, early passive mobilization exercises began immediately following tendon laceration and repair. In the second experimental group, delayed passive mobilization exercises began 3 weeks following repair. Passive mobilization in both groups was performed for 5 minutes daily.

The researchers¹¹ found that, 3 weeks following surgery, the tendons in the early mobilization group withstood a tensile load twice that of the other 2 groups. At 12 weeks after repair, the tendons in the early mobilization group ruptured at tensile forces almost 50% as high as the tensile forces on undamaged tendons; the tendons in the delayed mobilization group ruptured at 33% and the immobilized tendons ruptured at only 20% of the tensile force required for rupture of undamaged tendons. Gelberman et al recommended initiating carefully controlled passive mobilization of repaired tendons soon after the surgery.

Enwemeka et al¹² examined the effects of early active mobilization of tensile strength in healing tendon. In a rat model, lacerated and repaired Achilles tendons allowed unrestricted active motion following 5 days of casting had increased tensile strength at 8 days after repair compared with tendons immobilized for the full 8-day period or with tendons allowed active motion from the second day to the fifth day following repair. They also found increased incidence of rupture in both the immobilized tendons and the tendons allowed active motion at day 2. The authors interpreted their data as showing that active motion was important in enhancing tensile strength of repairs, but that this effect occurred only if the motion was allowed too early in the healing process. This finding is consistent with those of Mason and Allen.⁷ Enwemeka et al emphasized that the rate of healing in rats is much faster than in humans, but the progression through the phases of healing is similar.

Direct studies of tensile strength of healing tendons in humans are not possible due to ethical considerations. However, tensile strength can be inferred by comparing rates of rupture between experimental groups. In a study of recovery following finger flexor tendon lacerations in humans, early passive mobilization (following up to 5 days of immobilization) improved final active range of motion (AROM) compared with immobilization for 3 1/2 weeks, without increasing incidence of tendon rupture.¹³ Because of these results, early controlled passive mobilization has become a cornerstone of successful flexor tendon injury rehabilitation programs.¹⁴

Traditionally, Achilles tendon ruptures have been casted for 4 to 9 weeks following surgical repair to prevent rerupture.¹⁵ Two prospective, randomized clinical studies^16,17 compared immobilization with an early mobilization protocol following Achilles tendon repair. The findings of these 2 studies^16,17 suggest that, in Achilles tendon repairs, early mobilization does not significantly change tensile strength of repairs in comparison with immobilization.

The implications of basic science findings on tendon healing for design of a rehabilitation program can be summarized as follows. During the inflammatory phase of healing, 3 to 5 days following injury or surgery, tendon tensile strength and ability to hold sutures are at their lowest levels. During this time, protected rest is recommended. Following this period of rest, a program subjecting the healing tendon to gradually increasing tensile forces should be initiated. Progression of the program should be incremental and slow to allow and promote collagen proliferation, maturation, and fiber alignment.

During the proliferative phase, 5 to 28 days after injury, controlled passive movement should be initiated, keeping the repaired tendon in a protected position to avoid excessive tensile forces. The allowed passive range of motion (PROM) can be gradually increased as healing progresses. As the tissue moves into the remodeling phase of healing (4–8 weeks following injury), the tendon begins to be able to tolerate the level of force generated by active muscle contraction. Active motion should begin with an exercise progression designed to increase tensile force in a controlled manner. Initially, active movement in gravity-eliminated positions will prevent excessive resistance due to the weight of the limb; gradual increases in the muscle force generated may be achieved through increased antigravity movement as the repair becomes stronger. External resistance to the involved tendon (eg, weights, elastic cord) should be avoided until 8 weeks following surgery, with the resistance increased incrementally after that time. At 12 weeks following surgery, the tendon repair should be able to withstand the full force of muscle contraction without rupture.

Rupture of the tendon of the latissimus dorsi (LD) muscle appears to be uncommon. Only 4 previous case reports of spontaneous rupture of the LD tendon have been reported in the English-language literature (Tab. 1).^18–21 The outcomes of both surgical and nonsurgical management were good. These cases briefly mentioned rehabilitation following surgery, but they provided little specific information about the intervention are given. Our literature search found no detailed reports of rehabilitation following an LD tendon rupture or repair.

The LD is a large muscle originating on the spinous processes and supraspinous ligaments of all lower thoracic (T7–12), lumbar, and sacral vertebrae; the lumbar fascia; the posterior third of the iliac crest; the 4 caudal ribs; and the inferior angle of the scapula. It inserts on the floor of the bicipital groove of the humerus via a conjoined tendon with the teres major muscle (TM). The TM is a small muscle originating on the dorsal surface of the inferior angle of the scapula. Differentiating injury to the LD and TM tendons is clinically difficult, but may be possible via magnetic resonance imaging.²² Function of the LD and TM muscles is very similar. With the proximal end fixed, they function to adduct, extend, and internally rotate the humerus; with the arms overhead and the hands holding a fixed object, they pull the trunk up and forward.²³ Functionally, they assist in pulling objects toward the body or in lifting the body during climbing. Tensile force on the tendon is increased by motions that passively stretch the muscle (flexion, abduction, and external rotation) or through active contraction of the muscle for shoulder extension, adduction, and internal rotation. Combinations of stretches (eg, flexion with external rotation) or muscle contraction in a stretched position (eg, shoulder extension from a fully flexed position) increase the tensile forces generated.

Due to its large size and good vascularity, the LD muscle is a common source of free flaps for repair of major soft tissue defects. Laitung and Peck²⁴ and Fraulin et al²⁵ studied function following LD transfer or free flap graft and found little residual disability.

The purposes of this case report are to document the rehabilitation of a patient following LD tendon repair and to present the scientific rationale for the treatment approach.

Intervention

Postoperative Weeks 7 and 8

Details of the plan of care are presented in the Appendix. The initial shoulder strengthening program began with active flexion, abduction, and external rotation (lifting the weight of the arm) with the patient seated or standing. In the upright body position, the LD muscle is not recruited against gravity in these motions or when the arm lifts movable objects. Flexion, abduction, and external rotation provide a passive stretch to the LD tendon. Because antagonists to the LD muscle perform these motions, it may be subjected to reciprocal inhibition neurologically.^29,30 This would decrease the likelihood of LD muscle contraction in a stretched position and, therefore, protect the repair from excessive tensile force. Combinations of flexion, abduction, and external rotation were avoided to prevent excessive tensile forces in this early period. The patient was instructed to limit motion to his pain-free ROM. The amount of resistance for these shoulder movements was progressively increased as long as the increase did not produce pain during treatment.

During the examination, the patient expressed frustration with his postsurgical activity restrictions. Early in the intervention progression, he began a vigorous strengthening program for muscles of the forearm, wrist, and hand in positions that protected the LD tendon repair (Appendix). This distal strengthening program was important for several reasons. For this patient, strengthening and reconditioning the muscles controlling the more distal joints in the arm and hand was important for functional return. Strengthening could be done in these areas without endangering the repair. Moreover, this early program seemed to satisfy the patient’s wish for vigorous rehabilitation, thus decreasing his frustrations with his activity restrictions while respecting the limitations of the healing tissue. The program was performed on the BTE Work Simulator II,* which provides good isolation of the targeted muscles (Fig. 1). The precise positioning allowed with this equipment protected the LD muscle from being used to stabilize the shoulder during distal upper-extremity exercises.

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Figure 1.

Forearm strengthening in positioning to protect latissimus dorsi tendon repair.

Biceps muscle curls with dumbbells were initiated. Triceps muscle strengthening was avoided due to concern that the patient might use the LD muscle to stabilize the shoulder. Use of a treadmill was added for aerobic conditioning. There was concern that if the patient, in attempting to prevent a fall, grabbed the rails, he could produce a forceful contraction of his left LD; therefore, he was instructed to hold the rail with his right hand only, and the pace was kept to a fast walk.

Manually resisted scapular protraction, retraction, and elevation were begun with the patient in a side-lying position. Manual resistance was chosen for these movements to ensure that the therapist could monitor and prevent LD muscle substitution. Resisted scapular depression was avoided at this time because this movement would probably have been accomplished through LD muscle contraction (via the humerus).

By the end of week 8, the patient had full active pain-free shoulder flexion. The absence of pain suggested that the tendon repair was able to withstand passive tensile forces in that plane of motion. Range of motion in other directions was improving and pain was resolving at the ends of ROM.

Postoperative Weeks 9 Through 12

Exercises that would use the LD muscle with very light resistance were added (eg, shoulder extension from a flexed position with the elbow extended using light elastic band resistance). As a general rule, resistance or ROM in a specific exercise was increased only if it did not produce pain. New exercises were attempted cautiously and were allowed only if they did not cause pain. Exercise on an isokinetic Upper Body Ergometer† was begun. This machine allows selection of various speeds with the mechanism providing sufficient resistance to prevent exceeding that speed. A high speed (120 rotations per minute) was chosen initially to limit torque-generating potential to protect the LD tendon. The speed was gradually decreased through this period, progressively increasing the resistance and tensile forces generated.

Active range of motion was improving in all directions except internal rotation, which was noted to be 50 degrees (decreased from 65° initially). Gentle manual stretching for this movement was added, and internal rotation improved.

Resistance or duration was increased for all exercises, but only one parameter was increased in a single visit. By week 12, strength throughout the forearm, wrist and hand was 5/5. With the goal of 5/5 strength in these areas met, BTE strengthening for the lower arm was discontinued. Shoulder strength was 5/5 for flexion, abduction and external rotation. Internal rotation was 4+/5, and adduction and extension from 90 degrees of flexion or abduction was 4/5, at least partially limited by pain in the axilla.

During week 10, without consulting with the physical therapist or physician, the patient attempted to do a pull-up at home. He reported being unable to do more than hang from his arms due to pain in the left axilla. Although there was no lingering pain or loss of strength or ROM following this incident, the patient was cautioned that he risked rupturing the repair by putting too much force on the tendon too soon.

During week 11, the patient requested permission to attempt a pull-up again. Following consultation with the surgeon, it was suggested that the patient wait another 2 weeks to ensure adequate healing.

During week 12, the patient began to report pain along the incision in the axilla at the end of flexion and abduction range with LD muscle concentric/eccentric resistance activities such as pulling elastic cords, weighted pulleys, or closed kinetic chain vertical push-pull exercises direction on the BTE Work Simulator II (Fig. 2). There was no change in palpation findings from the initial evaluation. It was thought that the pain was due to increased mechanical stress on the scar due to combined tensile forces due to passive stretch and active contraction. These exercises were limited to pain-free ROM and resistance, and manual scar mobilization in the axilla was added. The pain decreased but recurred intermittently. Exercise progression for all other exercises continued, as there was no pain with these activities.

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Figure 2.

Pull-down exercise on BTE Work Simulator II.

Postoperative Weeks 13 Through 16

Following the surgeon’s recommendation, during week 13 the patient attempted a pull-up at home, with pain reported throughout the activity. He was able to complete the ascending (concentric) portion of the exercise despite the pain, but was unable to complete the descending (eccentric) portion and had to drop to the ground. He did not have any residual pain or loss of strength or ROM following this incident.

Total Gym‡ pull-ups were added as a way to simulate the pull-up motion with less than body-weight resistance (Fig. 3). The patient found even this exercise painful if performed to full ROM. The choice was made to avoid end-range shoulder flexion and maintain a relatively high level of resistance. However, it might have been possible for the patient to exercise at full ROM if the resistance had been sufficiently decreased.

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Figure 3.

Simulated pull-up with reduced body-weight resistance.

During week 15, the patient reported completing 2 pull-ups at home despite moderate to severe pain in the area of the incision. There was no change in the palpation examination, suggesting no structural damage to the repair. The patient was reminded of the need to avoid painful tensile forces in the healing tendon to protect the repair. Due to pain in the scar with pull-ups and continuing pain when attempting full-range flexion on the Total Gym, ultrasound to the axilla was added and manual scar mobilization was continued. The patient reported immediate improvement in pain with exercises on the Total Gym following ultrasound and scar mobilization.

During week 16, the patient was able to complete 5 pull-ups despite 3–4/10 pain on the last 2 repetitions. He reported no pain while exercising on the Total Gym at full ROM at level 10 (33% of body weight).

Outcome

Seventeen weeks following surgery, the patient passed his SWAT team physical examination and returned to work. Left shoulder AROM was full. An isometric test of static LD muscle strength was performed on the BTE Work Simulator II using Kendall and colleagues’²⁷ recommended positioning for manual muscle testing of the LD muscle (shoulder extension with the shoulder in a neutral position and the patient lying prone; Fig. 4). The LD muscle force generation was 35 lb on the left compared with 38 lb on the right (left-side force generation 92% of that of the uninjured dominant right side).

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Figure 4.

Testing position for isometric latissimus dorsi muscle strength.

The patient was discharged with therapy goals met including return to work, unrestricted recreational activities, and independence in an ongoing home strengthening program. When contacted for follow-up 1 year later, he reported that he was able to perform all regular activities including rodeo competition and work.

Appendix

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Details of the Plan of Care for the Current Patient^a

• Received February 26, 2005.
• Accepted September 19, 2005.

• Physical Therapy