AUTHOR AND EDITOR INFORMATION

Section 1 of 6  

• Authors and Editors
• Introduction
• Relevant Anatomy
• Contraindications
• Treatment
• References

INTRODUCTION

Section 2 of 6  

• Authors and Editors
• Introduction
• Relevant Anatomy
• Contraindications
• Treatment
• References

Do not regard extensor tendon lacerations as a "fitting challenge for the neophyte." The general principles and timing of management are similar to those pertaining to flexor tendon injuries. In combined repairs, flexor tendon rehabilitation must take priority. The mechanism of injury generally includes lacerations, crush injuries, avulsions, burns, and deep abrasions. Associated fractures are common with extensor injuries in the digits. In closed injury over the dorsum of the proximal interphalangeal joint, suspect extensor tendon injury. The criterion period for primary repair has been extended from the classic 6 hours to 12 hours if antibiotics are used.

The extensor tendon is extrasynovial except at the wrist level. Tendons are surrounded by paratenon for nourishment, supplying segmental arterial input. Interposition of scar between the tendon ends may result in the extensor tendon unit becoming too long, thus losing the ability to perform a useful function. Splinting extensor tendons even longer than the flexors is important to prevent damage to the repair by the more powerful flexor tendons. Although the extensor action is weaker than that of the flexors, the extensor mechanism is able to accommodate the full range of flexor tendon excursion by distal shift of the extensor expansion during digital flexion.

As in all hand surgery, meticulous handling of the tissues is vital. Scar formation can be demonstrated at every contact point along the tendon.

RELEVANT ANATOMY

Section 3 of 6  

• Authors and Editors
• Introduction
• Relevant Anatomy
• Contraindications
• Treatment
• References

The superficial layer of the fascia covering the dorsum of the hand has a delicate, fatty component that contains the dorsal venous channels. A deeper membranous layer is attached to the deep fascia by areolar tissue. This areolar layer balloons with acute injury and is involved in the classic degloving, leaving the underlying paratenon intact. The extensor retinaculum is divided into 6 compartments: (1) abductor pollicis longus, extensor pollicis brevis; (2) extensor carpi radialis longus, extensor carpi radialis brevis; (3) extensor pollicis longus; (4) extensor indicis proprius, extensor digitorum communis; (5) extensor digiti quinti; and (6) extensor carpi ulnaris. The extensor carpi radialis longus and extensor carpi radialis brevis insert onto the bases of the second and third metacarpals, respectively, and the extensor carpi ulnaris inserts onto the base of the fifth metacarpal. Since the extensor carpi radialis brevis lies closest to the central axis of the wrist, it is the purest wrist extensor.

Preservation of the function of this tendon thus is a priority. Extension of the wrist is a secondary function for the digital flexors, with wrist flexion enhancing their action. Extension of the digits is a combination of extrinsic and intrinsic muscle action. The extrinsic extensors are primarily responsible for metacarpophalangeal extension, with extension of the interphalangeal joints an intrinsic function. The extensor digitorum communis to the little finger usually arises from that of the ring finger at the metacarpal level. An inconstant pattern of intertendinous connections (juncturae tendineae) exists at the metacarpal level. These may limit independent metacarpophalangeal extension.

Some extensor digitorum communis attachment to the base of the proximal phalanx or capsule of the metacarpophalangeal joint may be present. The extensor indicis proprius passes through the fourth space in the extensor retinaculum on the ulnar side of the extensor digitorum communis to the index finger to insert into the extensor expansion. The extensor indicis proprius contributes to ulnar deviation of the index finger and to pointing. The extensor digiti quinti travels alone through the fifth compartment, ulnar to the extensor digitorum communis to the little finger, and frequently splits into 2 tendons. The radial division usually is joined to the extensor digitorum communis to the little finger. The interossei and lumbricals are the principal extensors of the interphalangeal joints of the fingers.

Extensor apparatus of the fingers

The extensor expansion or hood covers most of the dorsum of the proximal and middle phalanges. The retinacular system stabilizes the apparatus. The sagittal bands are orientated transversely over the capsule and collateral ligaments of the metacarpophalangeal joints, separating them from the intrinsic muscles. During extension they overlie the metacarpophalangeal joints but move distally in digital flexion. Most of the fibers of the central tendon (slip) insert into the capsule of the proximal interphalangeal joint and the base of the middle phalanx. Distal to the sagittal bands, the intrinsic muscles that make up the lateral bands (interossei, lumbricals) contribute proximal vertical and distal oblique fibers to the sides of the central tendon. Some contribution of the extensor digitorum communis to the lateral bands is present, in addition to the intrinsics.

Distal to the proximal interphalangeal joint, the lateral bands first are separated by a triangular ligament and then fuse to form a conjoined tendon, which inserts into the base of the distal phalanx. The extensor hood is free to slide proximally with metacarpophalangeal extension and distally with metacarpophalangeal flexion. With the hood in the distal position, the interossei contribute to metacarpophalangeal flexion through their vertical fibers, with little effect on the interphalangeal joints. With the hood in the proximal position and the metacarpophalangeal joints fixed in extension, the interossei, through the oblique fibers of the lateral bands, are able to extend the interphalangeal joints.

Conversely, the lumbrical muscles are effective interphalangeal extensors irrespective of the degree of metacarpophalangeal flexion. Similar to the interossei, they provide flexion of the metacarpophalangeal joint via their vertical fibers. The lateral bands normally lie dorsal to the axis of motion of the extended proximal interphalangeal joint and shift volarward with proximal interphalangeal flexion. The triangular ligament prevents the lateral bands from shifting volar to the axis of motion to become flexors of the proximal interphalangeal joint.

The primary function of the extensor digitorum communis is metacarpophalangeal function, but with full metacarpophalangeal extension or metacarpophalangeal extension blocked, the extensor digitorum communis can extend the interphalangeal joints.

The principal components of the retinacular system are the transverse and oblique ligaments (Landsmeer ligament). The transverse fibers originate from the flexor sheath and proximal phalanx on the volar aspect, pass through a window in the Cleland ligament, and insert into the lateral bands and triangular ligament dorsal to the axis of proximal interphalangeal joint rotation. The deeper and more tendinous oblique retinacular ligament arises from the volar proximal interphalangeal joint capsule and proximal two thirds of the middle phalanx and inserts distally into the conjoined tendon.

The extensor pollicis longus traverses the third dorsal compartment of the wrist. It adducts and supinates the first ray and extends the metacarpophalangeal and interphalangeal joints.

The extensor pollicis brevis and abductor pollicis longus are important stabilizers of the first metacarpal base. The extensor pollicis brevis extends the carpometacarpal and metacarpophalangeal joints, inserting into the base of the proximal phalanx. It occasionally inserts into the distal phalanx as well. The anatomy of the thumb metacarpophalangeal joint resembles the proximal interphalangeal joint anatomy of the digits. The adductor and abductor pollicis longus tendons contribute to a dorsal expansion, which has transverse fibers acting like the retinacular system to stabilize the tendons of extensor pollicis brevis and extensor pollicis longus. The intrinsics are able to extend (but not hyperextend) the interphalangeal joint through fibrous interconnections in the dorsal expansion.

CONTRAINDICATIONS

Section 4 of 6  

• Authors and Editors
• Introduction
• Relevant Anatomy
• Contraindications
• Treatment
• References

The most common injury at the metacarpophalangeal joint level is the "fight bite" due to human tooth injury. In these contaminated injuries, primary repair is contraindicated. Once the acute infection has been treated, the swelling has lessened, and the passive range of motion has been restored, repair can be undertaken.

TREATMENT

Section 5 of 6  

• Authors and Editors
• Introduction
• Relevant Anatomy
• Contraindications
• Treatment
• References

Surgical Therapy

Injuries at specific levels

Distal interphalangeal joint (zone I)

Complete division of the terminal conjoined tendon beyond the insertion of the oblique retinacular ligaments results in the mallet finger deformity. With time, often an associated proximal interphalangeal volar plate relaxation with resultant swan neck deformity occurs (this mimics the swan neck deformity observed with volar plate rupture). As a general principle, any tendon imbalance tends to result in the opposite deformity in the uninvolved joint. This typically is observed in rheumatoid deformity.

• Open injury: These injuries are invariably intra-articular. Lavage and debridement of the joint, tendon repair, skin closure, and K wire fixation are the principles of management. A degree of hyperextension is desirable but avoid skin blanching. Remove the wire after 4 weeks and replace it with a mallet finger splint for 2 weeks. Introduce active flexion during the eighth week.
• Closed injury
  • Treat all these closed, with the single exception of those with an associated fracture involving a large intra-articular fragment (>30% of the articular surface). Accurate reduction of these large fragments is necessary. A pullout wire tied around a button on the volar pulp and a longitudinal C wire are used (or just the latter if the fixation is stable). In cases involving smaller fragments, percutaneous transarticular wire fixation avoids the need for open operation and both maintains the reduction and fixes the joint in extension.
  • In the routine closed injury without bony involvement, use a mallet finger splint, aiming for slight hyperextension. Take particular care to ensure that the dorsal skin is not blanched or jeopardized by local pressure consequent to the splint. Splintage alone produces the best results in closed injures, but it requires absolute patient compliance. The splint should be worn for 6 weeks. Introduce active extension after 8 weeks. If extensor lag is present after this time, reintroduce the splint.
• Established mallet finger deformity: Unopposed flexion of the distal interphalangeal joint results in stretching of the scar. Early scar contracts, thus a trial of splintage may be warranted in the first few months after injury. Surgical correction by excision of the redundant scar and prolonged splintage is best for those patients with established deformity. Verdan resected a segment of tendon more proximally. Failures are best treated by distal interphalangeal arthrodesis in 100º of flexion.
• Associated swan neck deformity: This is consequent to the combination of volar plate laxity at the proximal interphalangeal joint and imbalance of the extensor mechanism. It is best corrected by addressing the distal interphalangeal deformity. Alternately, a sliding tenotomy of the central tendon can be performed, taking great care not to produce a boutonnière deformity.
• Splinting techniques: Splintage must be applied constantly for a good result to be achieved. Proximal interphalangeal joint motion should not be restricted. K wire fixation causes little articular damage. Use a mallet finger splint for closed injuries.

Middle phalangeal level (zone II)

No clinical deformity is present since the oblique retinacular ligaments are preserved. Division of the conjoined tendon distal to the insertion of Landsmeer ligaments results in a mallet finger deformity. Repair and immobilize open injuries as for a mallet finger, with the exception that 4 weeks of immobilization is sufficient.

Proximal interphalangeal joint level (zone III)

Disruption of the central slip results in the boutonnière (ie, button hole) deformity. The head of the middle phalanx herniates through the extensor expansion. As the triangular ligament ruptures, the lateral bands displace volarly. Compensatory distal interphalangeal hyperflexion may be present. Closed injuries easily are missed, but the Carducci test is invaluable: with the wrist and metacarpophalangeal joints in partial flexion, the power of proximal interphalangeal extension is tested. An extensor lag of greater than 15° is diagnostic (flexion to diminish the contribution of the lateral bands to proximal interphalangeal extension).

• Open injury: Treat any laceration over the proximal interphalangeal joint as a central slip rupture until proven otherwise. These are best repaired with the proximal interphalangeal joint fixed in full extension. In contaminated wounds, repair is best delayed.
• Closed injury: Treat all closed injuries apart from those involving a large intra-articular bony fragment by splintage. Initial splintage is static or by K wire in uncooperative patients. Dislocation of the proximal interphalangeal joint usually is associated with disruption of the central slip. A bony fragment may be visible on radiographs and is an indication for operative intervention. However, patients usually present not with a boutonnière deformity but rather with diffuse swelling and limited range of motion due to periarticular soft tissue injury.
• Established boutonnière deformity: Patients who present with an established deformity are divided into 2 groups, those with mobile injuries and those with fixed injuries. In the latter group, establishing a full passive range of motion prior to the repair is essential. This may require surgical release of the contracted volar structures and passive stretching, or it may require merely the latter. However, obtaining a good result from surgery is difficult. Surgical options include the following:
  • Eaton and Littler technique - Incomplete transection of the lateral bands, allowing them to retract proximally and leaving the oblique retinacular ligament intact
  • Matev technique - One lateral band transferred to the base of the middle phalanx
  • Elliot technique - Anatomic repair of triangular ligament after reduction of the lateral band subluxation; shortening of the central slip by excision of elongated scar
  • Hayward technique

  The joint is fixed in all options by a transarticular wire. Retain the wire for 6 weeks, followed by external splintage for a variable period according to the extensor delay. External splintage usually requires a dynamic splint (eg, Capener splint, Joint jack, COSCO splint). Splintage is indicated for established deformities, following C wire removal in open injuries and after secondary repair, and as a preliminary trial in older patients.

  The Fowler procedure involves section of the conjoined tendon over the proximal section of the middle phalanx, with preservation of the oblique retinacular ligament. This is an option for symptomatic splinting failures (ie, those that fail to regain passive range of motion). Release of the oblique retinacular ligaments may be necessary if the distal interphalangeal joint cannot be flexed passively following repair, which is often more disfiguring than the boutonnière deformity. Alternately, operative failures can be addressed by arthrodesis, as necessary. The position of arthrodesis follows the normal digital cascade (30-90°). In rheumatoid arthritis, an interpositional arthroplasty is best.

• Swan neck deformity: The Littler oblique retinacular ligament technique for swan neck deformity relocates the one lateral band volarly and inserts it into the volar aspect of the middle phalanx. This functions to tighten as the proximal interphalangeal joint extends. Variations on the original Littler technique include the use of the palmaris longus in the "spiral oblique retinacular ligament" technique. The Littler flexor digitorum superficialis tenodesis routes the free proximal end of the flexor digitorum superficialis tendon through the volar aspect of the middle phalanx.

Proximal phalanx level (zone IV)

The injury may involve the central tendon, the lateral bands, or both. Unilateral division of a lateral band usually does not manifest as a deformity. Division of the central tendon manifests as a boutonnière deformity, but this is a rare occurrence. Division at this level usually involves an open wound. Treatment is by direct repair and K wire immobilization.

Metacarpophalangeal joint level (zone V)

The division of the extensor hood overlying the metacarpophalangeal joint results in an extensor lag. Active extension of the proximal phalanx against resistance is diminished. In the index or little fingers, this may not be evident if the proper tendon is intact (extensor digiti quinti, extensor indicis proprius).

The most common injury at this level is the "fight bite" due to human tooth injury. In these contaminated injuries, primary repair is contraindicated. Once the acute infection has been treated, the swelling has lessened, and the passive range of motion has been restored, repair can be undertaken. Splint the metacarpophalangeal joints in a full extension splint for 3 weeks. Of importance, the proximal interphalangeal and distal interphalangeal joints should remain free. Use a dynamic extension splint following removal of the splint until no extensor lag remains.

Metacarpal level (level VI)

The liberal juncturae tendineae tend to mask the underlying deformity. Repair all divided structures. A horizontal mattress suture is often better for these flat structures. If the tendon repair is likely to encounter the extensor retinaculum, dividing the latter is best. Splintage and immobilization are the same as in the former.

Division at the wrist joint (zone VII)

The extensor retinaculum is divided and repaired by Z lengthening. The tendons at this and more proximal levels resemble flexor tendons (ie, round) and should be sutured as such using a core suturing technique.

Thumb

Division of the extensor pollicis longus at the interphalangeal joint level results in a mallet deformity, while division at the metacarpal level only results in the inability to hyperextend the thumb. In the examination for extensor pollicis longus transection, passively extending the metacarpophalangeal joint is important to neutralize the intrinsic action on the interphalangeal joint. Also check for retropulsion of the thumb.

Division of the extensor pollicis brevis results in minimal deformity, or it may resemble a boutonnière deformity. In the latter, the action of extensor pollicis longus draws the interphalangeal joint into hyperextension, thus completing the deformity. The volar migration of the extensor pollicis longus tendon below the axis of rotation further compounds this deformity. In repairs to the extensor pollicis longus, supinating and adducting the first ray is important to take tension off the anastomosis. Transfix the involved joint with a K wire. Secondary repair is usually not possible after 4 weeks because of proximal retraction of the extensor pollicis longus. An extensor indicis proprius transfer is a better option.

REFERENCES

Section 6 of 6

• Authors and Editors
• Introduction
• Relevant Anatomy
• Contraindications
• Treatment
• References

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• Sylaidis P, Youatt M, Logan A. Early active mobilization for extensor tendon injuries. The Norwich regime. J Hand Surg [Br]. Oct 1997;22(5):594-6. [Medline].
• Tomaino MM, Plakseychuk A. Two-stage extensor tendon reconstruction after composite tissue loss from the dorsum of the hand. Am J Orthop. Feb 2000;29(2):122-4. [Medline].
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Article Last Updated: Oct 5, 2006