Lateral Malleolar Fractures.: The stability of an isolated lateral malleolar fracture depends on the location of the fracture in relation to the level of the tibiotalar joint, which defines the distal portion of the syndesmotic ligament and the stability it provides to the ankle joint. The Danis-Weber classification (see Fig. 58-8) is useful and predictive of outcome in these types of unimalleolar fractures.³³ This classification groups fractures into three groups (A, B, and C), each of which has three subgroups. Lateral malleolar fractures below the tibiotalar joint (Danis-Weber type A) rarely disrupt other bony or ligamentous structures, and in the absence of injury to the medial structures such fractures are unlikely to affect the dynamic congruity of the ankle joint.³⁸ The management of uncomplicated lateral malleolar fractures involves casting for 6 to 8 weeks, with no weightbearing for at least the first 3 weeks, and ongoing follow-up to ensure proper union. Concomitant tenderness over the deltoid ligament may suggest a biomechanical disruption of both malleoli, an associated fracture of the medial malleolus, or an associated fracture of the posterior malleolus and warrants orthopedic consultation in the ED, especially if the medial clear space on the mortise view is widened (see Fig. 58-6).³⁸ CT imaging can be useful in such situations as it may identify occult medial or posterior malleolar fractures.

Fibular fractures proximal to the tibiotalar joint line (a Danis-Weber type C injury; see Fig. 58-8) frequently, but not always, disrupt the distal tibiotalar syndesmosis and the medial structures and commonly require orthopedic consultation in the ED and operative intervention. Treatment of an isolated fracture at the level of the tibiotalar joint (a Danis-Weber type B injury; see Fig. 58-8) is controversial because 50% of these injuries are accompanied by an injury to the distal tibiofibular syndesmosis that may require operative intervention.⁴⁰ Distal tibiofibular space measurements on plain radiography have a sensitivity of only 31% and a specificity of 83%, compared with CT scan, in detecting tibiofibular syndesmosis injuries.⁴¹ Tenderness on palpation of the syndesmotic ligament or a widening of the medial joint space on the mortise view adds further support to the need for emergency consultation.

Medial Malleolar Fractures.: Medial malleolar fractures are usually the result of eversion or external rotation. These two forces exert tension on the deltoid ligament, causing an avulsion of the tip of the medial malleolus or a rupture of the deltoid ligament. Although they can occur in isolation, medial malleolar fractures are commonly associated with lateral or posterior malleolar disruption. Because of this, the identification of a medial malleolar fracture warrants a careful examination of the entire length of the fibula for tenderness, the presence of which warrants radiographic evaluation to rule out a proximal fibular fracture (Fig. 58-9).

An isolated nondisplaced medial malleolar fracture can be treated with casting for 6 to 8 weeks, with no weightbearing for at least the first 3 weeks and close orthopedic follow-up. Any displacement or concomitant disruption of the lateral components of the ankle warrants orthopedic consultation in the ED for consideration of operative management.³⁸

Posterior Malleolar Fractures.: Isolated fractures of the posterior malleolus are rare and imply an avulsion of the posterior tibiofibular ligament. These injuries can be associated with proximal fibular fractures and medial and lateral collateral ligament sprains. Treatment usually consists of casting for 6 weeks, provided that no associated injury or ankle instability is present.⁴² Fractures involving more than 25% of the tibial surface usually require open reduction and internal fixation.³⁸

Pathophysiology.: Most ankle sprains occur from extreme inversion and plantar flexion causing symptoms on the lateral aspect of the ankle. Usually the anterior talofibular ligament is injured first, followed by the calcaneofibular ligament if the deforming forces are sufficiently strong (see Fig. 58-1). Approximately two thirds of ankle sprains are isolated anterior talofibular ligament injuries, whereas 20% involve both anterior talofibular and calcaneofibular ligament injuries. In addition, the lateral talocalcaneal ligament may be stressed with an inversion injury, leading to avulsion fractures at either end of the attachment sites.⁶¹ Isolated calcaneofibular or posterior talofibular ligament injuries are rare.

Isolated injury of the deltoid ligament occurs in less than 5% of ankle sprains. Rupture of this ligament occurs most commonly in conjunction with lateral malleolar fractures, especially when an external rotational force is involved.

Injuries of the distal tibiofibular syndesmotic ligaments are uncommon in the general population but may represent 10 to 20% of injuries in competitive athletes.⁶² Dorsiflexion and external rotation forces are usually responsible for this injury, the presence of which may significantly prolong the recovery time from lateral collateral ligament sprains.⁶²

Ligamentous injuries are classified into three grades based on functional and presumed pathologic findings. A grade I injury involves ligamentous stretching without grossly evident tearing or joint instability. A grade II injury involves a partial tear of the ligament with moderate joint instability, often accompanied by significant localized swelling and pain. A grade III injury involves a complete tear of the ligament with marked joint instability, severe edema, and ecchymosis. This classification system, although commonly used, fails to characterize ankle injuries involving two or more ligaments, and it does not consider nonligamentous injuries. Although more comprehensive classification systems have been proposed,⁶¹ there is a strong association with increased gradation of ankle sprain and long-term risk of chronic instability, early osteoarthritis, chronic pain, and permanent disability.^63,64

Clinical Features.: Although desirable, an accurate history of ankle position and injury mechanism is often unavailable. Inversion followed by external rotation of the ankle suggests the potential for deltoid or syndesmotic injury. Forced dorsiflexion with snapping may indicate peroneal tendon displacement. Previous injuries to the same ankle or symptoms of recurrent ankle instability or pain suggest the presence of a subacute or chronic pathologic process.

On physical examination, the presence of edema, ecchymosis, and point tenderness over the medial or lateral collateral ligaments or the syndesmotic ligaments suggests a ligamentous injury. Inability to bear weight in the absence of a fracture suggests the presence of a grade II or III ankle sprain.⁶⁵ With inversion injuries, point tenderness may also be present along the distal fibula, the lateral aspect of the talus, the lateral aspect or anterior process of the calcaneus, or the base of the fifth metatarsal. Deltoid ligament tenderness necessitates palpation of the full length of the fibula to rule out a proximal fibular fracture (a type C Danis-Weber or Maisonneuve fracture; see Figs. 58-8 and 58-9) and a low threshold for imaging the entire tibia and fibula should exist. The fibular compression test, also known as the squeeze test, reveals fibular and syndesmotic injuries.⁶² To perform this test, the examiner places the fingers over the fibula and the thumb over the tibia at midcalf and squeezes the two bones. Pain anywhere along the length of the fibula suggests a fibular fracture or an interosseous membrane or syndesmotic ligament disruption at that location.⁶² Finally, the Achilles tendon should be assessed.

Stress testing is the application of a deforming force to assess joint motion beyond the physiologic range, the presence of which suggests ligament disruption or mechanical instability. Although rarely required, stress testing is safe to perform and can be helpful for acute and severe ankle injury in which rupture of two or more ligaments is suspected, a fracture suspected to be isolated in which the presence of an additional ligament rupture would influence management, the possibility of a concomitant syndesmotic injury, follow-up evaluation of an acute ankle injury after pain and swelling have subsided, and a chronically symptomatic ankle. With the exception of these scenarios, stress testing is not indicated because it is painful and does not alter management. The normal ranges for stress tests are controversial, so the uninjured side should be examined for comparison.

Common ankle stress tests include the anterior drawer test, the inversion stress test, and the external rotation test. The anterior drawer test primarily assesses the integrity of the anterior talofibular ligament. For this test to be performed, the patient is seated with the knee in 90 degrees of flexion and the ankle in a neutral position or 10 degrees of plantar flexion. The examiner then pulls on the heel with one hand and pushes the leg posteriorly with the other. Anterior displacement of the talus, the perception of a “clunk,” and the induction of a sulcus anteromedially over the joint indicate partial or complete tear of the anterior talofibular ligament.

The inversion stress test, or talar tilt test, evaluates both the anterior talofibular ligament and the calcaneofibular ligament. It is performed by inverting the heel with the knee in 90 degrees of flexion and the ankle in neutral position. Palpation of the head of the talus laterally or a finding of increased laxity compared with the uninjured side suggests partial or complete tear of these ligaments.

The external rotation stress test is indicated when injury to the distal tibiofibular syndesmotic ligaments is suspected. It is performed by externally rotating the foot with the knee in 90 degrees flexion and the ankle in a neutral position. Pain at the syndesmosis or the sensation of lateral talar motion suggests partial or complete tear of the ligaments.

Diagnostic Strategies: Radiology.: Standard ankle radiographic views are useful to exclude fractures and to detect instability by the measurement of joint spaces (see earlier discussion and Fig. 58-6).⁸ Presence of avulsion fractures, which can be located at the bases of the malleoli, the lateral process of the talus, the lateral aspect of the calcaneus, the posterior malleolus, the lateral aspect of the distal tibia, or the base of the fifth metatarsal, constitute an important clue to the location of ligamentous injuries.

In addition to the standard mortise measurements previously discussed, two measurements on the anteroposterior radiograph further evaluate the distal tibiofibular syndesmosis (see Fig. 58-6).⁸ At the distal overlap between the fibula and the tibia, the distance between the posterior edge of the lateral tibial groove and the medial fibular cortex (syndesmosis A) should not exceed 5 mm.⁸ Furthermore, the amount of tibiofibular bony overlap (syndesmosis B) should be at least 10 mm.⁸ Measurements outside of these values suggest a syndesmotic diastasis. Stress radiographs, accomplished by taking radiographs during stress testing of the ankle, generally do not influence the emergency management of ankle sprains and are not recommended.⁶⁶

Many injuries can masquerade as ankle sprains.⁵⁸ Box 58-2 lists conditions to be considered in the differential diagnosis; Figure 58-12 shows locations of common fractures in or near the ankle that can be misdiagnosed as an ankle sprain.

Management.: Most ligament sprains, regardless of severity, heal well and result in a satisfactory outcome. To date, compelling evidence for a significant difference in outcomes between surgical and functional (nonsurgical) treatment is lacking. Limited data suggest that recovery times may be longer and complications more frequent with surgical treatment.⁶⁷ Most patients with acute sprains of the ankle should start with functional treatment.⁶⁸ For the minority who fail to respond, delayed operative repair of ruptured ligaments, sometimes years after the injury, has been shown to yield results equivalent to those with primary repair.^68,69

Functional treatment, which is defined as a form of therapy in which the ankle is not fully immobilized, allowing either complete or partial joint function, starts in the ED with RICE therapy (rest, ice, compression, and elevation); however, significant variability exists in how this combination is applied, and the optimal methods remain unclear.60,61,70 The evidence to date suggests that lace-up ankle support is more effective in short-term edema reduction than semirigid ankle support, elastic bandaging, and taping. Elastic bandaging causes fewer complications than taping but appears to correlate with slower return to work and sports.⁶⁰ One study suggests that compared with elastic bandaging, ankle bracing with a lace-up brace such as the Air-Stirrup Ankle Brace (Aircast, DJO Inc., Vista, Calif.) leads to improved functioning at both 10 days and 1 month.⁷¹

For grade I or II injuries, short-term protection with a tensor bandage, taping, a laced-up support, or a commercial walking boot or brace, with the optional use of crutches for a few days, is appropriate.68,70 For patients with first-time ankle sprains, treatment with a lace-up stirrup brace combined with elastic wrapping results in an earlier return to function compared with use of a brace alone, elastic wrap alone, or a walking cast.⁷² For severe grade II or grade III injuries, there is currently equipoise regarding the merit of immobilization compared with functional rehabilitation, with little high-quality evidence to guide therapy.^73,74 A recent study supports a 10-day period of immobilization with a below-knee cast or Aircast ankle brace to speed recovery from ankle sprains, with immobilization leading to reduced symptoms and faster recovery compared with tubular compression bandages.⁷⁵ However, a weakness in this study was the lack of a control group incorporating an active ankle physiotherapy program, known to be important for improved recovery. An accelerated functional rehabilitation program carried out over the first week of injury has also recently been shown to improve function in grade I and II ankle sprains in the short term.⁷⁶

Because there is little evidence for a more favorable outcome with complete immobilization over functional treatment incorporating a removable brace, the use of a lace-up support or air cast that permits some ankle motion is generally preferable.68,74,77 Such patients should also use crutches to avoid weightbearing until they can stand and walk a few steps on the injured ankle without pain. How long crutches will be required varies significantly, ranging from a few days to 2 or 3 weeks. Follow-up care with the patient’s primary physician within the first 2 weeks is appropriate for minor sprains, whereas orthopedic or sports medicine referral on an outpatient basis is prudent for severe sprains.

Analgesics are often necessary for pain management in ankle injuries, and studies suggest that nonsteroidal anti-inflammatory agents, acetaminophen, or oral opioids for severe cases are efficacious.78–80 Topical diclofenac gel also has been shown to have efficacy in pain reduction and allowing early mobilization.^67,81,82

After the acute management phase, the next two phases of functional treatment involve appropriate early rehabilitation and occur outside the ED.⁸³ Phase two, which begins after swelling has subsided and the patient is able to bear weight easily, involves strengthening the peroneal and dorsiflexor muscles by isometric, concentric, and eccentric exercises. The final phase begins when full range of motion has been reestablished and the patient can exercise painlessly. This starts with exercises to rebuild motor coordination and proprioception, recondition the muscles, and increase endurance. The patient uses an ankle tilt board or disk to develop coordination and performs increasingly demanding functional activities (e.g., brisk walking, running, and figure-of-eight running to hopping, jumping, and cutting) to build up the muscle groups.^83,84 With severe sprains the patient may benefit from the use of air casts, braces, or taping during the latter two phases of functional treatment and in the initial period of return to sports.⁸³ The entire treatment program usually lasts 4 to 6 weeks, depending on the injury’s severity.^61,70,85

Disposition.: Rarely, orthopedic consultation in the ED is indicated for an acute ligament sprain. Primary surgical repair of acute ligament rupture is controversial, and possible indications include sprains with displaced osteochondral lesions, complete tears of both the anterior talofibular and calcaneofibular ligaments in a young athlete, a ligament sprain associated with a fracture causing instability (e.g., a deltoid ligament rupture with a lateral malleolar fracture), and an acute severe sprain in a patient with a history of recurrent and severe sprains.⁶¹ Failure of nonoperative treatment also constitutes an indication for surgical repair; however, an orthopedic referral on an outpatient basis is adequate ED management.⁶⁹

Small avulsion fractures of the fibula with minimal or no displacement can be treated in the same manner as an ankle sprain. If the avulsed fragment is larger than 3 mm or significantly displaced, splinting and referral for orthopedic follow-up on an outpatient basis are justified.

Despite appropriate treatment, chronic problems develop in 10 to 30% of patients with ankle sprains.⁷⁰ These include functional instability, mechanical instability, chronic pain, stiffness, and recurrent swelling and occur more often in grade III ankle sprains.

Functional instability refers to the patient’s subjective sensation that the ankle gives way during activity. Although this may be a minor nuisance for some people, it can be devastating and debilitating for persons whose activities demand a high degree of ankle stability. Mechanical instability results from ligamentous laxity, which allows ankle joint movements beyond the physiologic range. In contrast to functional instability, mechanical instability can often be demonstrated clinically by the anterior drawer or talar tilt test and stress radiographs.⁶¹

Soft tissue abnormalities that cause chronic pain include synovial impingement, peroneal tendon subluxation or dislocation, intra-articular loose bodies, anterior tibiofibular syndesmotic ligament injuries, and degenerative arthritis. Bone-related causes of chronic pain include osteochondral lesions, fractures of the anterior process of the calcaneus, fractures of the lateral process of the talus, and anterior and posterior impingement.58,86

Patients with any of these chronic conditions should be referred for orthopedic follow-up care because they may require further imaging or arthroscopy for diagnosis or definitive treatment.

Achilles Tendon Rupture.: Achilles tendon rupture is most common in middle-aged men, and its causes are multifactorial. This condition is easily misdiagnosed, leading to a delay in therapy, a worse prognosis, and increased morbidity, including chronic weakness and loss of function. In the great majority of cases, a complete transection of the tendon is present; however, partial tears of the Achilles tendon can occur and may be more prone to misdiagnosis.

Achilles tendon rupture results from direct trauma or indirectly transmitted forces, including sudden unexpected dorsiflexion, forced dorsiflexion of a plantar-flexed foot, and strong push-off of the foot with simultaneous knee extension and calf contraction (as in a runner accelerating from the starting position). Factors predisposing to Achilles tendon rupture include preexisting disease such as rheumatoid arthritis, systemic lupus erythematosus, gout, hyperparathyroidism, or chronic renal failure, steroid use or injection, fluoroquinolone antibiotic therapy, and previous Achilles tendon rupture.⁸⁷

The diagnosis of Achilles tendon rupture is primarily clinical. Patients usually describe a sudden onset of pain at the back of the ankle associated with an audible “pop” or “snap.” Although the pain can resolve rapidly, weakness in plantar flexion persists. On examination, a visible and palpable tendon defect may be noted 2 to 6 cm proximal to the calcaneal insertion in acute presentations but will be less apparent in delayed presentations because of hematoma or edema. Even in cases of complete Achilles tendon rupture, weak plantar flexion may still be possible because of the actions of the tibialis posterior, toe flexors, and peroneal muscles. This retained ability for plantar flexion often leads to the misdiagnosis of complete ruptures as ankle strains or partial tears in as many as 25% of cases.⁸⁸ The classic maneuver to assess the integrity of the Achilles tendon is the Thompson test.⁸⁹ This is performed with the patient prone and the knee flexed at 90 degrees or the feet hanging over the end of the stretcher. Alternatively, the patient kneels on a chair with both knees flexed at 90 degrees and the feet hanging over the edge. Squeezing the calf muscles in these two positions should cause passive plantar flexion of the foot. Absence of this motion, or a markedly weakened response compared with the uninjured side, suggests complete rupture. Another recently described diagnostic test, the reverse Silfverskiöld test, compares dorsiflexion of the injured ankle with that in the uninjured ankle while the patient is in the supine position. Achilles tendon rupture results in a notably increased degree of dorsiflexion compared with the uninjured side.⁹⁰

Lateral radiographic views of the ankle may suggest rupture by showing opacification of the fatty tissue–filled space anterior to the Achilles tendon (Kager’s triangle) or an irregular contour and thickening of the tendon.⁸⁸ Ultrasonography or MRI can demonstrate partial or complete tendon ruptures, but these studies are indicated only in cases in which diagnostic uncertainty exists.⁸⁸

A lack of consensus exists regarding the choice between operative and nonoperative management in the treatment of Achilles tendon rupture.91–93 Surgical repair is routinely performed in active individuals owing to its lower incidence of rerupture. However, surgery carries higher rates of other complications, such as superficial or deep wound infections, in comparison with nonoperative management.^91,94 In both types of management, early mobilization improves functional recovery without increasing rerupture rates.^91,93 Minimally invasive surgery combined with early rehabilitation with postoperative functional bracing may further improve outcome.^95,96 Achilles tendon rerupture after initial nonoperative treatment usually necessitates surgical repair, with substandard results compared with primary repair.⁹⁷ ED orthopedic referral of patients with Achilles tendon rupture is necessary to determine the appropriate management.

Peroneal Tendon Dislocation or Tear.: The peroneal muscles are the primary evertors and pronators of the foot and also participate in plantar flexion. The peroneus longus and brevis tendons use the posterior peroneal sulcus (the fibular groove), located behind and underneath the lateral malleolus, as a pulley for their midfoot insertions. The peroneus brevis tendon inserts onto the tuberosity of the fifth metatarsal, and the peroneus longus tendon courses beneath the cuboid to insert onto the medial cuneiform and base of the first metatarsal. The superior peroneal retinaculum (Fig. 58-13), a fibrous structure running from the distal fibula to the posterolateral aspect of the calcaneus, maintains the peroneal tendons against the fibular groove.

Anterior subluxation or dislocation of the peroneal tendons occurs as a result of a tear of the superior peroneal retinaculum attachment from the fibula.98,99 This infrequent injury is commonly misdiagnosed as an ankle sprain and can occur in isolation or concomitant with other sprains or fractures. The mechanism of injury usually is forced dorsiflexion with reflex contraction of the peroneal muscles, resulting in avulsion of the retinaculum and anterior displacement of the peroneal tendons.⁹⁸

Patients with a peroneal tendon dislocation complain of sudden pain and a snapping sensation over the posterolateral ankle associated with weakness of eversion. Tenderness and swelling over the lateral retromalleolar area (a location not typically involved in ankle sprains) are characteristic. When accurate examination is not precluded by swelling, the dislocated tendons also may be palpable near the inferior tip of the lateral malleolus. Inability to actively evert the foot when it is held in dorsiflexion or frank subluxation of the tendons with this maneuver confirms the diagnosis. Findings on plain radiography are often normal; however, 15 to 50% of patients will be found to have an associated avulsion fracture of the lateral ridge of the distal fibula. An MRI study or ultrasound can be helpful in confirming the diagnosis. All patients with a suspected or confirmed peroneal tendon dislocation should be referred for orthopedic follow-up because these injuries require surgical repair.99,100 Spontaneous healing is rare in untreated cases, and chronic ankle instability and pain are common sequelae. Peroneal tendons also can tear longitudinally; such injuries manifest either acutely or subacutely with recurrent pain and swelling during activities.^100,101

Tibialis Posterior Tendon Rupture.: The tibialis posterior is primarily responsible for plantar flexion and inversion along the subtalar joint. Its tendon uses the posteroinferior surface of the medial malleolus as a pulley and inserts onto the navicular, the medial cuneiforms, and the bases of the second through the fifth metatarsals. The peroneus brevis opposes the action of the tibialis posterior. With rupture of the tibialis posterior tendon, the peroneus brevis becomes unopposed and the medial longitudinal arch loses its muscular support, leading to valgus deformity of the hindfoot and a unilateral flatfoot.¹⁰²

The mechanism of traumatic tibialis posterior rupture involves forced eversion.¹⁰² In addition to a unilateral flatfoot, pain and swelling on the medial aspect of the ankle are seen. Tenderness is present over the navicular, and the patient cannot perform a toe raise on the affected side. In addition, the patient with a tibialis posterior tendon rupture is unable to invert the foot when it is in plantar flexion and eversion. With a unilateral flatfoot, an observer standing behind the patient can see “more toes” on the lateral aspect of the affected side—a classic sign.¹⁰² Plain radiography can exclude other bone abnormalities. Ultrasonography and MRI are useful imaging modalities to diagnose this condition.¹⁰² Orthopedic consultation is indicated for tibialis posterior tendon ruptures, because surgical repair often is necessary.

Other Tendon Injuries.: The tibialis anterior is the primary dorsiflexor of the foot. Its tendon courses under the superior extensor retinaculum and inserts onto the navicular, the medial cuneiform, and the base of the first metatarsal. Tenosynovitis of the tibialis anterior tendon is associated with overuse and characterized by swelling, tenderness, and crepitus along the tendon. Treatment involves RICE therapy, analgesia, and close follow-up. Rupture of the tibialis anterior is rare and often is misdiagnosed as lumbosacral radiculopathy or peroneal nerve palsy because of the footdrop it produces. This condition requires orthopedic consultation in the ED because surgical repair is usually necessary.

The flexor hallucis longus is responsible for flexion of the great toe and participates in plantar flexion of the foot. Its tendon courses behind the medial malleolus through a fibro-osseous canal and inserts onto the distal phalanx of the great toe. Flexor hallucis longus tendinitis, also called dancer‘s tendinitis, most often occurs at the fibro-osseous canal.¹⁰³ On examination, tenderness and edema posterior to the medial malleolus are noted, and passive extension of the first metatarsophalangeal (MTP) joint causes significant pain when the foot is in neutral position. Initial treatment involves rest, nonsteroidal anti-inflammatory drugs, and a short course of immobilization. Orthopedic follow-up on an outpatient basis should be arranged to ensure proper resolution. Rarely, surgical intervention may be necessary.¹⁰³