Yeditepe University Faculty of Medicine 1st Year Anatomy Blog



leg

28. February.2012 Tuesday

The leg region (L. regio cruris) is the part that lies between the knee and and ankle joint. It includes most of the tibia (shin bone) and fibula (calf bone). The leg (L., crus) connects the knee and foot. Often laypersons refer incorrectly to the entire lower limb as “the leg.”

• proximally, most major structures pass between the thigh and leg through or in relation to the popliteal fossa behind the knee;

• distally, structures pass between the leg and foot mainly through the tarsal tunnel on the posteromedial side of the ankle, the exceptions being the anterior tibial artery and the ends of the deep and superficial fibular nerves, which enter the foot anterior to the ankle.

Fascial Compartments of the Leg

The deep fascia of the leg is called the crural fascia. The deep fascia surrounds the leg and is continuous above with the deep fascia of the thigh. Two intermuscular septa pass from its deep aspect to be attached to the fibula. These, together with the interosseous membrane, divide the leg into three compartments “anterior, lateral, and posterior”; each having its own muscles, blood supply, and nerve supply.

Inferiorly, two band-like thickenings of the fascia form retinacula that bind the tendons of the anterior compartment muscles before and after they cross the ankle joint, preventing them from bowstringing anteriorly during dorsiflexion of the joint:

• The superior extensor retinaculum is a strong, broad band of deep fascia, passing from the fibula to the tibia, proximal to the malleoli.

• The inferior extensor retinaculum, a Y-shaped band of deep fascia, attaches laterally to the anterosuperior surface of the calcaneus. It forms a strong loop around the tendons of the fibularis tertius and the extensor digitorum longus muscles.

Flexor retinaculum; extends from the medial malleolus downward and backward to be attached to the medial surface of the calcaneum. It binds the tendons of the deep muscles of the back of the leg to the back of the medial malleolus as they pass forward to enter the sole. The tendons lie in compartments, each of which is lined by a synovial sheath.

Superior peroneal retinaculum; connects the lateral malleolus to the lateral surface of the calcaneum. It binds the tendons of the peroneus longus and brevis to the back of the lateral malleolus. The tendons are provided with a common synovial sheath.

Inferior peroneal retinaculum; binds the tendons of the peroneus longus and brevis muscles to the lateral side of the calcaneum. The tendons each possess a synovial sheath, which is continuous above with the common sheath.

Antero-lateral aspect of the leg

ANTERIOR compartment of the leg

The anterior compartment of the leg, or dorsiflexor (extensor) compartment, is located anterior to the interosseous membrane, between the lateral surface of the shaft of the tibia and the medial surface of the shaft of the fibula, and anterior to the intermuscular septum that connects them. The anterior compartment is bounded anteriorly by the deep fascia of the leg and skin.

Muscles

[ See Table 1 for origins, insertions, innervations and main functions]

There are four muscles in the anterior compartment of the leg- tibialis anterior, extensor hallucis longus, extensor digitorum longus, and fibularis tertius. These muscles pass and insert anterior to the transversely oriented axis of the ankle (talocrural) joint and, therefore, are dorsiflexors of the ankle joint, elevating the forefoot and depressing the heel [Collectively they dorsiflex the foot at the ankle joint, extend the toes, and invert the foot].

Dorsiflexion is actively used in the swing phase of walking, when concentric contraction keeps the forefoot elevated to clear the ground as the free limb swings forward. Immediately after, in the stance phase, eccentric contraction of the tibialis anterior controls the lowering of the forefoot to the floor following heel strike. During standing, the dorsiflexors reflexively pull the leg (and thus the center of gravity) anteriorly on the fixed foot when the body starts to lean (the center of gravity begins to shift too far) posteriorly.

All the muscles of the anterior compartment of the leg are innervated by the deep fibular nerve, which is a branch of the common fibular nerve.

Tibialis anterior

The tibialis anterior muscle is the most anterior and medial (and also the most superficial) of the muscles in the anterior compartment of leg. The long tendon of the tibialis anterior begins halfway down the leg and descends along the anterior surface of the tibia. Its tendon passes within its own synovial sheath deep to the superior and inferior extensor retinacula to its attachment on the medial side of the foot. In so doing, its tendon is located farthest from the axis of the ankle joint, giving it the most mechanical advantage and making it the strongest dorsiflexor. Although antagonists at the ankle joint, the tibialis anterior and the tibialis posterior (in the posterior compartment) both cross the subtalar and transverse tarsal joints to attach to the medial border of the foot. Thus they act synergistically to invert the foot.

The tibialis anterior dorsiflexes the foot at the ankle joint and inverts the foot at the intertarsal joints. During walking, it provides dynamic support for the medial arch of the foot.

To test the the tibialis anterior, the person is asked to stand on the heels or dorsiflex the foot against resistance; if normal, its tendon can be seen and palpated.

Extensor hallucis longus

The extensor hallucis longus muscle is a thin muscle which lies between the tendons of the tibialis anterior and extensor digitorum longus in the lower one-half of the leg and descends into the foot. The extensor hallucis longus extends the great toe. Because it crosses anterior to the ankle joint, it also dorsiflexes the foot at the ankle joint. To test the extensor hallucis longus, the great toe is dorsiflexed against resistance; if acting normally, its entire tendon can be seen and palpated.

Extensor digitorum longus

The extensor digitorum longus muscle is the most posterior and lateral of the muscles in the anterior compartment of leg. The muscle becomes tendinous superior to the ankle, forming four tendons that attach to the phalanges of the lateral four toes. A common synovial sheath surrounds the four tendons of the extensor digitorum longus (plus that of the fibularis tertius) as they diverge on the dorsum of the foot and pass to their distal attachments. To test the extensor digitorum longus, the lateral four toes are dorsiflexed against resistance; if acting normally, the tendons can be seen and palpated. The extensor digitorum longus extends the toes and dorsiflexes the foot at the ankle joint.

Fibularis tertius

The fibularis tertius muscle is a separated part of extensor digitorum longus, which shares its synovial sheath. Proximally, the attachments and fleshy parts of the two muscles are continuous; however, distally the FT tendon is separate and attaches to the 5th metatarsal, not to a phalanx. Although fibularis tertius contributes (weakly) to dorsiflexion, it also acts at the subtalar and transverse tarsal joints, contributing to eversion of the foot. It may play a special proprioceptive role in sensing sudden inversion and then contracting reflexively to protect the anterior tibiofibular ligament, the most commonly sprained ligament of the body. The fibularis tertius is not always present.

Arteries

Anterior tibial artery

The artery associated with the anterior compartment of leg is the anterior tibial artery, which passes forward into the anterior compartment of leg through an aperture in the interosseous membrane.

The smaller terminal branch of the popliteal artery, the anterior tibial artery, begins at the inferior border of the popliteus muscle (i.e., as the popliteal artery passes deep to the tendinous arch of the soleus). The artery immediately passes anteriorly through a gap in the superior part of the interosseous membrane to descend on the anterior surface of this membrane between the tbialis anterior and extensor digitorum longus muscles. At the ankle joint, midway between the malleoli, the anterior tibial artery changes names, becoming the dorsalis pedis artery (dorsal artery of the foot).

Table 1. Muscles of the anterior compartment of the leg.

|Muscle |Origin | Insertion |Innervation |Main Action |

|Tibialis anterior |Lateral condyle and superior |Medial cuneiform and base of 1st|Deep fibular nerve (L4, L5) |Dorsiflexes ankle and inverts |

| |half of lateral surface of tibia|metatarsal | |foot |

| |and interosseous membrane | | | |

|Extensor digitorum longus |Lateral condyle of tibia and |Middle and distal phalanges of | |Extends lateral four digits and |

| |superior three quarters of |lateral four digits | |dorsiflexes ankle |

| |medial surface of fibula and | | | |

| |interosseous membrane | | | |

|Extensor hallucis longus |Middle part of anterior surface |Dorsal aspect of base of distal | |Extends great toe and |

| |of fibula and interosseous |phalanx of great toe (hallux) | |dorsiflexes ankle |

| |membrane | | | |

|Fibularis tertius |Inferior third of anterior |Dorsum of base of 5th metatarsal| |Dorsiflexes ankle and aids in |

| |surface of fibula and | | |eversion of foot |

| |interosseous membrane | | | |

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Distally, the anterior tibial artery gives rise to an anterior medial malleolar artery and an anterior lateral malleolar artery, which pass posteriorly around the distal ends of the tibia and fibula, respectively. These vessels connect with vessels from the posterior tibial and fibular arteries to form an anastomotic network around the ankle.

Veins

Deep veins follow the arteries and have similar names.

Nerves

Deep fibular nerve

The nerve associated with the anterior compartment of the leg is the deep fibular (peroneal) nerve.

It is one of the two terminal branches of the common fibular nerve, arising between the fibularis longus muscle and the neck of the fibula in the lateral compartment. The deep fibular nerve passes through the intermuscular septum and then passes deep to the extensor digitorum longus. It reaches the anterior interosseous

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membrane where it descends with the anterior tibial artery. The deep fibular nerve then exits the anterior compartment, continuing across the ankle joint to supply intrinsic muscles (extensors digitorum and hallucis brevis) and a small area of the skin of the foot. A lesion of this nerve results in an inability to dorsiflex the ankle (footdrop).

The deep fibular nerve:

• innervates all muscles in the anterior compartment;

• [continues into the dorsal aspect of the foot] innervates the extensor digitorum brevis, first two dorsal interossei muscles, and supplies the skin between the great and second toes.

Lateral compartment of leg

Muscles

[ See Table 2 for origins, insertions, innervations and main functions]

There are two muscles in the lateral compartment of leg (evertor compartment)- fibularis longus and fibularis brevis. Both evert the foot (turn the sole outward) and are innervated by the superficial fibular nerve, which is a branch of the common fibular nerve. The lateral compartment is the smallest (narrowest) leg compartment. It is bounded by the lateral surface of the fibula, the anterior and posterior intermuscular septa, and the deep fascia of the leg. The lateral compartment ends inferiorly at the superior fibular retinaculum, which spans between the distal tip of the fibula and the calcaneus. Here the tendons of the two muscles of the lateral compartment (fibularis longus and brevis) enter a common synovial sheath to accommodate their passage between the superior fibular retinaculum and the lateral malleolus, using the latter as a trochlea as they cross the ankle joint.

The fibularis longus and fibularis brevis muscles have their fleshy bellies in the lateral compartment but are tendinous as they exit the compartment within the common synovial sheath deep to the superior fibular retinaculum. Both muscles are evertors of the foot, elevating the lateral margin of the foot. As evertors, the fibularis muscles act at the subtalar and transverse tarsal joints. From the neutral position, only a few degrees of eversion are possible. In practice, the primary function of the evertors of the foot is not to elevate the lateral margin of the foot (the common description of eversion) but to depress or fix the medial margin of the foot in support of the toe off phase of walking and, especially, running and to resist inadvertent or excessive inversion of the foot (the position in which the ankle is most vulnerable to injury). When standing (and particularly when balancing on one foot), the fibularis muscles contract to resist medial sway (to recenter a line of gravity, which has shifted medially) by pulling laterally on the leg while depressing the medial margin of the foot.

To test the fibularis longus and brevis, the foot is everted strongly against resistance; if acting normally, the muscle tendons can be seen and palpated inferior to the lateral malleolus.

Fibularis longus

The fibularis longus muscle arises in the lateral compartment of leg, but its tendon crosses under the foot to attach to bones on the medial side. The common fibular nerve passes anteriorly around the fibular neck between the attachments of the fibularis longus to the fibular head and shaft. Distal to the superior fibular retinaculum, the common sheath shared by the fibular muscles splits to extend through separate compartments deep to the inferior fibular retinaculum.

The fibularis longus everts and plantarflexes the foot. In addition, the fibularis longus, tibialis anterior, and tibialis posterior muscles, which all insert on the undersurfaces of bones on the medial side of the foot, together act as a stirrup to support the arches of the foot. The fibularis longus supports mainly the lateral and transverse arches. When a person stands on one foot, the fibularis longus helps steady the leg on the foot.

Fibularis brevis

The fibularis brevis is a fusiform muscle that lies deep to the fibularis longus, and, true to its name, it is shorter than its partner in the lateral compartment. Its broad tendon grooves the posterior aspect of the lateral malleolus and can be palpated inferior to it. The narrower tendon of the fibularis longus lies on that of the fibularis brevis and does not contact the lateral malleolus

Table 2. Muscles of the lateral compartment of the leg.

|Muscle |Proximal Attachment (Origin) |Distal Attachment |Innervation |Main Action |

| | |(Insertion) | | |

|Fibularis longus |Head and superior two thirds of|Base of 1st metatarsal and |Superficial fibular nerve (L5, |Everts foot and weakly |

| |lateral surface of fibula |medial cuneiform |S1, S2) |plantarflexes ankle |

|Fibularis brevis |Inferior two thirds of lateral |Dorsal surface of tuberosity on| | |

| |surface of fibula |lateral side of base of 5th | | |

| | |metatarsal | | |

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Arteries

No major artery passes vertically through the lateral compartment of leg. Instead, perforating branches and accompanying veins supply blood to and drain blood from the compartment. Proximally, perforating branches of the anterior tibial artery penetrate the anterior intermuscular septum. Inferiorly, perforating branches of the fibular artery penetrate the posterior intermuscular septum, along with their accompanying veins (L. venae comitantes).

Veins

Deep veins generally follow the arteries.

Nerves

Superficial fibular nerve

The nerve associated with the lateral compartment of leg is the superficial fibular (peroneal) nerve. This nerve originates as one of the two major branches of the common fibular nerve, which enters the lateral compartment of leg from the popliteal fossa. After supplying the fibularis longus and fibularis brevis, the superficial fibular nerve continues as a cutaneous nerve, supplying the skin on the distal part of the anterior surface of the leg and nearly all the dorsum of the foot.

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Posterior aspect of the leg

Muscles

Muscles in the posterior (plantarflexor) compartment of leg, the largest of the three leg compartments, are organized into two groups, superficial and deep, by the transverse intermuscular septum. Generally, the muscles mainly plantarflex and invert the foot and flex the toes. All are innervated by the tibial nerve.

Muscles of the posterior compartment produce plantarflexion at the ankle, inversion at the subtalar and transverse tarsal joints, and flexion of the toes. Plantarflexion is a powerful movement (four times stronger than dorsiflexion) produced over a relatively long range (approximately 50° from neutral) by muscles that pass posterior to the transverse axis of the ankle joint. Plantarflexion develops thrust, applied primarily at the ball of the foot, that is used to propel the body forward and upward and is the major component of the forces generated during the push-off (heel off and toe off) parts of the stance phase of walking and running.

Superficial group

[ See Table 3 for origins, insertions, innervations and main functions]

The superficial group of calf muscles (muscles forming prominence of “calf” of posterior leg) includes the gastrocnemius, soleus, and plantaris All of these muscles insert onto the heel (calcaneus) of the foot and plantarflex the foot at the ankle joint. The gastrocnemius and soleus share a common tendon, the calcaneal tendon, which attaches to the calcaneus. Collectively these two muscles make up the three-headed triceps surae (L. sura, calf). This powerful muscular mass tugs on the lever provided by the calcaneal tuberosity, elevating the heel and thus depressing the forefoot, generating as much as 93% of the plantarflexion force.

As a unit, these muscles are large and powerful because they propel the body forward off the planted foot during walking and can elevate the body upward onto the toes when standing. Two of the muscles (gastrocnemius and plantaris) originate on the distal end of the femur and can also flex the knee.

To test the triceps surae, the foot is plantarflexed against resistance (e.g., by “standing on the toes,” in which case body weight [gravity] provides resistance). If normal, the calcaneal tendon and triceps surae can be seen and palpated.

A subcutaneous calcaneal bursa, located between the skin and the calcaneal tendon, allows the skin to move over the taut tendon. A deep bursa of the calcaneal tendon (retrocal-caneal bursa), located between the tendon and the calcaneus, allows the tendon to glide over the bone.

Gastrocnemius

The gastrocnemius muscle is the most superficial of the muscles in the posterior compartment and is one of the largest muscles in the leg. It originates from two heads, one lateral and one media.

At the knee, the facing margins of the two heads of the gastrocnemius form the lateral and medial borders of the lower end of the popliteal fossa. In the upper leg, the heads of the gastrocnemius combine to form a single elongate muscle belly, which forms much of the soft tissue bulge identified as the calf. In the lower leg, the muscle fibers of the gastrocnemius converge with those of the deeper soleus muscle to form the calcaneal tendon, which attaches to the calcaneus (heel) of the foot. The gastrocnemius plantarflexes the foot at the ankle joint and can also flex the leg at the knee joint.

The large size of the gastrocnemius and soleus muscles is a human characteristic that is directly related to our upright stance. These muscles are strong and heavy because they lift, propel, and accelerate the weight of the body when walking, running, jumping, or standing on the toes.

The calcaneal tendon (L. tendo calcaneus, Achilles tendon) is the most powerful (thickest and strongest) tendon in the body. Approximately 15 cm in length, it is a continuation of the flat aponeurosis formed halfway down the calf where the bellies of the gastrocnemius terminate.

Plantaris

The plantaris has a small muscle belly proximally and a long thin tendon, which descends through the leg and joins the calcaneal tendon. This vestigial muscle is absent in 5-10% of people and is highly variable in size and form when present. It acts with the gastrocnemius but is insignificant as either a flexor of the knee or a plantarflexor of the ankle. The plantaris has been considered to be an organ of proprioception for the larger plantarflexors. The short spindle-shaped muscle body of the plantaris descends medially between the gastrocnemius and soleus muscles and eventually fuses with the medial side of the calcaneal tendon near its attachment to the calcaneus. The plantaris contributes to plantarflexion of the foot at the ankle joint and flexion of the leg at the knee joint, and is innervated by the tibial nerve.

Soleus

The soleus is a large flat muscle under the gastrocnemius muscle. In the lower leg, the soleus muscle narrows to join the calcaneal tendon that attaches to the calcaneus. Electromyography (EMG) studies show that during symmetrical standing, the soleus is continuously active.

Deep group

[ See Table 4 for origins, insertions, innervations and main functions]

Four muscles make up the deep group in the posterior compartment of the leg: popliteus, flexor digitorum longus, flexor hallucis longus, and tibialis posterior. The popliteus acts on the knee joint, whereas the other muscles plantarflex the ankle with two continuing on to flex the toes. When the calcaneal tendon is ruptured, these muscles cannot generate the power necessary to lift the body's weight (i.e., to stand on the toes).

Popliteus

The popliteus is the smallest and most superior of the deep muscles in the posterior compartment of the leg. It is a thin, triangular muscle that forms the inferior part of the floor of the popliteal fossa. It unlocks the extended knee at the initiation of flexion and stabilizes the knee by resisting lateral (external) rotation of the tibia on the femur. The popliteus muscle ascends laterally across the lower aspect of the knee. When initiating gait from a standing position, contraction of the popliteus laterally rotates the femur on the fixed tibia, unlocking the knee joint.

Flexor hallucis longus

The flexor hallucis longus muscle is a powerful flexor of all of the joints of the great toe. The tendon of the flexor hallucis longus slips into a distinct groove on the posterior surface of the adjacent tarsal bone (talus) of the foot. The flexor hallucis longus flexes the great toe. It is particularly active during the toe-off phase of walking when the body is propelled forward off the stance leg and the great toe is the last part of the foot to leave the ground. It can also contribute to plantarflexion of the foot at the ankle joint. To test the flexor hallucis longus, the distal phalanx of the great toe is flexed against resistance; if normal, the tendon can be seen and palpated on the plantar aspect of the great toe as it crosses the joints of the toe.

Table 3. Muscles of the superficial compartment of the leg.

|Muscle | Origin | Insertion |Innervation |Main Action |

|Gastrocnemius |Lateral head: lateral aspect of lateral condyle of|Posterior surface of |Tibial nerve (S1, S2) |Plantarflexes ankle when knee is |

| |femur |calcaneus via | |extended; raises heel during |

| |Medial head: popliteal surface of femur; superior |calcaneal tendon | |walking; flexes leg at knee joint|

| |to medial condyle | | | |

|Soleus |Posterior aspect of head and superior quarter of | | |Plantarflexes ankle independent |

| |posterior surface of fibula; soleal line and | | |of position of knee; steadies leg|

| |middle third of medial border of tibia; and | | |on foot |

| |tendinous arch extending between the bony | | | |

| |attachments | | | |

|Plantaris |Inferior end of lateral supracondylar line of | | |Weakly assists gastrocnemius in |

| |femur; oblique popliteal ligament | | |plantarflexing ankle |

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Flexor digitorum longus

The flexor digitorum longus muscle originates on the medial side of the posterior compartment of leg. The tendon crosses inferior to the tendon of the flexor hallucis longus muscle to reach the medial side of the foot and then divides into four tendons. The flexor digitorum longus flexes the lateral four toes. It is involved with gripping the ground during walking and propelling the body forward off the toes at the end of the stance phase of gait.

The two muscles of the posterior compartment that pass to the toes are crisscrossed. The muscle attaching to the great toe (flexor hallucis longus) arises laterally (from the fibula) in the deep subcompartment, and the muscle attaching to the lateral four toes (flexor digitorum longus) arises medially (from the tibia). Their tendons cross in the sole of the foot. To test the flexor digitorum longus, the distal phalanges of the lateral four toes are flexed against resistance; if they are acting normally, the tendons of the toes can be seen and palpated.

Tibialis posterior

The tibialis posterior muscle lies between and is overlapped by the flexor digitorum longus and the flexor hallucis longus muscles. Near the ankle, the tendon of the tibialis posterior is crossed superficially by the tendon of the flexor digitorum longus muscle and lies medial to this tendon in the groove on the posterior surface of the medial malleolus. The tibialis posterior inverts and plantarflexes the foot, and supports the medial arch of the foot during walking. To test the tibialis anterior, the foot is inverted against resistance with the foot in slight plantarflexion; if normal, the tendon can be seen and palpated posterior to the medial malleolus.

Table 4. Muscles of the deep compartment of the leg.

|Muscle |Origin | Insertion |Innervation |Main Action |

|Popliteus |Lateral surface of lateral |Posterior surface of tibia, |Tibial nerve (L4, L5, S1) |Weakly flexes knee and unlocks |

| |condyle of femur and lateral |superior to soleal line | |it by rotating femur 5° on fixed|

| |meniscus | | |tibia; medially rotates tibia of|

| | | | |unplanted limb |

|Flexor hallucis longus |Inferior two thirds of posterior|Base of distal phalanx of great | |Flexes great toe at all joints; |

| |surface of fibula; inferior part|toe (hallux) | |weakly plantarflexes ankle; |

| |of interosseous membrane | | |supports medial longitudinal |

| | | | |arch of foot |

|Flexor digitorum longus |Medial part of posterior surface|Bases of distal phalanges of | |Flexes lateral four digits; |

| |of tibia inferior to soleal |lateral four digits | |plantarflexes ankle; supports |

| |line; by a broad tendon to | | |longitudinal arches of foot |

| |fibula | | | |

|Tibialis posterior |Interosseous membrane; posterior|Tuberosity of navicular, | |Plantarflexes ankle; inverts |

| |surface of tibia inferior to |cuneiform, cuboid, and | |foot |

| |soleal line; posterior surface |sustentaculum tali of calcaneus;| | |

| |of fibula |bases of 2nd, 3rd, and 4th | | |

| | |metatarsals | | |

Arteries

Popliteal artery

The popliteal artery is the major blood supply to the leg and foot and enters the posterior compartment of leg from the popliteal fossa behind the knee. The popliteal artery passes into the posterior compartment of leg between the gastrocnemius and popliteus muscles. As it continues inferiorly it passes under the tendinous arch formed between the fibular and tibial heads of the soleus muscle and enters the deep region of the posterior compartment of leg where it immediately divides into an anterior tibial artery and a posterior tibial artery.

Anterior tibial artery

The anterior tibial artery passes forward through the aperture in the upper part of the interosseous membrane and enters the anterior compartment of leg. It continues inferiorly onto the dorsal aspect of the foot.

Posterior tibial artery

The posterior tibial artery descends through the deep region of the posterior compartment of leg on the superficial surfaces of the tibialis posterior and flexor digitorum longus muscles. It passes through the tarsal tunnel behind the medial malleolus and continues into the sole of the foot. In the leg, the posterior tibial artery has two major branches, the circumflex fibular artery and fibular artery:

• Circumflex fibular artery passes laterally through the soleus muscle and around the neck of the fibula to connect with the anastomotic network of vessels surrounding the knee;

• Fibular artery is the largest and most important branch of the tibial artery, arises inferior to the distal border of the popliteus and the tendinous arch of the soleus. It parallels the course of the tibial artery, but descends along the lateral side of the posterior compartment. The fibular artery passes behind the attachment between the distal ends of the tibia and fibula and terminates in a network of vessels over the lateral surface of the calcaneus.

• The nutrient artery of tibia, the largest nutrient artery in the body, arises from the origin of the anterior or posterior tibial artery.

Veins

Deep veins in the posterior compartment generally follow the arteries.

Nerves

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Lymphatic Drainage of the Leg

The greater part of the lymph from the skin and superficial fascia on the front of the leg drains upward and medially in vessels that follow the great saphenous vein, to end in the vertical group of superficial inguinal lymph nodes. Lymph vessels from the skin and superficial fascia on the back of the leg drain upward and either pass forward around the medial side of the leg to end in the vertical group of superficial inguinal nodes or drain into the popliteal nodes.

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Gastrocnemius Strain

Gastrocnemius strain (tennis leg) is a painful acute injury resulting from partial tearing of the medial belly of the gastrocnemius at or near its musculotendinous junction, often seen in individuals older than 40 years of age. It is caused by overstretching the muscle by concomitant full extension of the knee and dorsiflexion of the ankle joint. Usually, an abrupt onset of stabbing pain is followed by edema and spasm of the gastrocnemius.

Calcaneal Tendon Reflex

The ankle jerk reflex, or triceps surae reflex, is a calcaneal tendon reflex. It is a myotatic reflex elicited while the person's legs are dangling over the side of the examining table. The calcaneal tendon is struck briskly with a reflex hammer just proximal to the calcaneus. The normal result is plantarflexion of the ankle joint. The calcaneal tendon reflex tests the S1 and S2 nerve roots. If the S1 nerve root is injured or compressed, the ankle reflex is virtually absent.

Ruptured Calcaneal Tendon

Rupture of the calcaneal tendon is often sustained by poorly conditioned people with a history of calcaneal tendinitis. The injury is typically experienced as an audible snap during a forceful push off (plantarflexion with the knee extended) followed immediately by sudden calf pain and sudden dorsiflexion of the plantarflexed foot. In a completely ruptured tendon, a gap is palpable, usually 1-5 cm proximal to the calcaneal attachment. The muscles affected are the gastrocnemius, soleus, and plantaris.

Calcaneal tendon rupture is probably the most severe acute muscular problem of the leg. Individuals with this injury cannot plantarflex against resistance (cannot raise the heel from the ground or balance on the affected side), and passive dorsiflexion (usually limited to 20° from neutral) is excessive.

Ambulation is possible only when the limb is laterally (externally) rotated, rolling over the transversely placed foot during the stance phase without push off. Bruising appears in the malleolar region, and a lump usually appears in the calf owing to shortening of the triceps surae. In older or nonathletic people, non-surgical repairs are often adequate, but surgical intervention is usually advised for those with active lifestyles.

Calcaneal Tendinitis

Inflammation of the calcaneal tendon constitutes 9-18% of running injuries. Microscopic tears of collagen fibers in the tendon, particularly just superior to its attachment to the calcaneus, result in tendinitis, which causes pain during walking, especially when wearing rigidsoled shoes. Calcaneal tendinitis often occurs during repetitive activities, especially in individuals who take up running after prolonged inactivity or suddenly increase the intensity of their training, but it may also result from poor footwear or training surfaces.

Fabella in Gastrocnemius

Close to its proximal attachment, the lateral head of the gastrocnemius contains a sesamoid bone, the fabella (L., bean), which articulates with the lateral femoral condyle and is visible in lateral radiographs of the knee in 3-5% of people..

Superficial Fibular Nerve Entrapment

Chronic ankle sprains may produce recurrent stretching of the superficial fibular nerve, which may cause pain along the lateral side of the leg and the dorsum of the ankle and foot. Numbness and paresthesia (tickling or tingling) may be present and increase with activity.

Deep Fibular Nerve Entrapment

Excessive use of muscles supplied by the deep fibular nerve (e.g., during skiing, running, and dancing) may result in muscle injury and edema in the anterior compartment. This entrapment may cause compression of the deep fibular nerve and pain in the anterior compartment.

Pain occurs in the dorsum of the foot and usually radiates to the web space between the 1st and 2nd toes. Because ski boots are a common cause of this type of nerve entrapment, this condition has been called the “ski boot syndrome”; however, the syndrome also occurs in soccer players and runners and can also result from tight shoes.

Injury to Common Fibular Nerve and Footdrop

Because of its superficial position, the common fibular is the nerve most often injured in the lower limb, mainly because it winds subcutaneously around the fibular neck, leaving it vulnerable to direct trauma. This nerve may also be severed during fracture of the fibular neck or severely stretched when the knee joint is injured or dislocated.

Severance of the common fibular nerve results in flaccid paralysis of all muscles in the anterior and lateral compartments of the leg (dorsiflexors of ankle and evertors of foot). The loss of dorsiflexion of the ankle causes footdrop, which is further exacerbated by unopposed inversion of the foot. This has the effect of making the limb “too long”: The toes do not clear the ground during the swing phase of walking.

There are several other conditions that may result in a lower limb that is “too long” functionally, for example, pelvic tilt and spastic paralysis or contraction of the soleus. There are at least three means of compensating for this problem:

• A waddling gait, in which the individual leans to the side opposite the long limb, “hiking” the hip.

• A swing-out gait, in which the long limb is swung out laterally (abducted) to allow the toes to clear the ground.

• A high-stepping steppage gait, in which extra flexion is employed at the hip and knee to raise the foot as high as necessary to keep the toes from hitting the ground.

Because the dropped foot makes it difficult to make the heel strike the ground first as in a normal gait, a steppage gait is commonly employed in the case of flaccid paralysis. Sometimes an extra “kick” is added as the free limb swings forward in an attempt to flip the forefoot upward just before setting the foot down.

Injury to Tibial Nerve

Injury to the tibial nerve is uncommon because of its deep and protected position in the popliteal fossa; however, the nerve may be injured by deep lacerations in the fossa. Posterior dislocation of the knee joint may also damage the tibial nerve.

Complete division results in the following clinical

features:

Motor: All the muscles in the back of the leg and the sole of the foot are paralyzed. The opposing muscles dorsiflex the foot at the ankle joint and evert the foot at the subtalar and transverse tarsal joints, an attitude referred to as calcaneovalgus.

Sensory: Sensation is lost on the sole of the foot; later, trophic ulcers develop.

Posterior Tibial Pulse

The posterior tibial pulse can usually be palpated between the posterior surface of the medial malleolus and the medial border of the calcaneal tendon. Because the posterior tibial artery passes deep to the flexor retinaculum, it is important when palpating this pulse to have the person invert the foot to relax the retinaculum. Failure to do so may lead to the erroneous conclusion that the pulse is absent.

Both arteries are examined simultaneously for equality of force. Palpation of the posterior tibial pulses is essential for examining patients with occlusive peripheral arterial disease. Although posterior tibial pulses are absent in approximately 15% of normal young people, absence of posterior tibial pulses is a sign of occlusive peripheral arterial disease in people older than 60 years. For example, intermittent claudication, characterized by leg pain and cramps, develops during walking and disappears after rest. These conditions result from ischemia of the leg muscles caused by narrowing or occlusion of the leg arteries.

Superficial Peroneal Nerve Block

Area of anesthesia: Skin on the lower anterior and lateral sides of the leg and the dorsum of the foot and toes (except the cleft between the first and second toes, which is innervated by the deep peroneal nerve and the lateral side of the little toe, which is supplied by the sural nerve) Indications: Repair of lacerations in the area of its cutaneous distribution.

Procedure: The superficial peroneal nerve is a branch of the common peroneal nerve. In the lower third of the leg it becomes superficial and its terminal branches pass to their distribution on the dorsum of the foot and toes.

The superficial peroneal nerve is easily blocked in the lower part of the leg by infiltrating the anesthetic in the subcutaneous tissue along a transverse line connecting the medial and lateral malleoli.

Deep Peroneal Nerve Block

Area of anesthesia: Skin in the cleft between the big and second toes

Indications: Repair of lacerations in the cleft between the big and second toes

Procedure: The deep peroneal nerve is a terminal branch of the common peroneal nerve. It descends in the anterior compartment of the leg and at the ankle it passes onto the dorsum of the foot. Here the nerve lies on the lateral side of the dorsalis pedis artery and is superficially placed between the tendons of extensor digitorum

longus and the extensor hallucis longus muscles.

First, the dorsalis pedis artery is palpated midway between the medial and lateral malleoli. With the foot actively dorsiflexed, the tendons of the extensor digitorum longus and extensor hallucis longus muscles can be seen. The nerve lies on the lateral side of the artery between these tendons. The needle is then inserted over the nerve, and the surrounding tissues are infiltrated with anesthetic.

Tibial Nerve Block

Area of anesthesia: Skin of the sole of the foot (medial and lateral plantar nerves)

Indications: Repair of lacerations on the sole of foot

Procedure: The tibial nerve (L4 and L5 and S1 through S3) is the largest terminal branch of the sciatic nerve. At the ankle, the nerve, accompanied by the posterior tibial artery, becomes superficial. It lies behind the medial malleolus, between the tendons of the flexor digitorum longus and the flexor hallucis longus muscles, and is covered by the flexor retinaculum.

The tibial nerve may be blocked as it lies behind the medial malleolus. By careful palpation, the pulsations of the posterior tibial artery can be felt midway between the medial malleolus and the heel. The nerve lies immediately posterior to the artery, and the anesthetic needle can be inserted at this location.

Varicose Veins

A varicosed vein is one that has a larger diameter than normal and is elongated and tortuous. Varicosity of the esophageal and rectal veins is described elsewhere. This condition commonly occurs in the superficial veins of the lower limb and, although not life threatening, is responsible for considerable discomfort and pain.

Varicose veins have many causes, including hereditary weakness of the vein walls and incompetent valves; elevated intraabdominal pressure as a result of multiple pregnancies or abdominal tumors; and thrombophlebitis of the deep veins, which results in the superficial veins becoming the main venous pathway for the lower limb. It is easy to understand how this condition can be produced by incompetence of a valve in a perforating vein. Every time the patient exercises, high-pressure venous blood escapes from the deep

veins into the superficial veins and produces a varicosity, which might be localized to begin with but becomes more extensive later.

The successful operative treatment of varicose veins depends on the ligation and division of all the main tributaries of the great or small saphenous veins, to prevent a collateral venous circulation from developing, and the ligation and division of all the perforating veins responsible for the leakage of high-pressure blood from the deep to the superficial veins. It is now common practice to also remove or strip the superficial veins. Needless to say, it is imperative to ascertain that the deep veins are patent before operative measures are taken.

Deep Vein Thrombosis andLong-Distance Air Travel

Passengers who sit immobile for hours on long-distance flights are very prone to deep vein thrombosis in the legs. Preventative measures include stretching of the legs every hour to improve the venous circulation., Occlusions of the Popliteal, Anterior, and Posterior Tibial Arteries

Popliteal artery occlusion occurs just below the beginning of the artery (just below the opening in the adductor magnus muscle). In some cases the occlusion extends distally to involve the origins of the anterior and posterior tibial arteries and even the peroneal artery. Symptoms include intermittent claudication, night cramps, and rest pain caused by ischemic neuritis. Signs include impaired or absent arterial pulses, lowered skin temperature, color changes, muscle weakness, and trophic changes.

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The common fibular nerve originates from the sciatic nerve in the posterior compartment of thigh or in the popliteal fossa, and follows the medial margin of the biceps femoris tendon over the lateral head of the gastrocnemius muscle and toward the fibula. Here it gives origin to two cutaneous branches, which descend in the leg:

• Sural communicating nerve, which joins the sural branch of the tibial nerve and contributes to innervation of skin over the lower posterolateral side of the leg;

• Lateral sural cutaneous nerve, which innervates skin over the upper lateral leg.

The common fibular nerve continues around the neck of the fibula and enters the lateral compartment by passing between the attachments of the fibularis longus muscle to the head and shaft of fibula. Here the common fibular nerve divides into its two terminal branches:

• Superficial fibular nerve

• Deep fibular nerve

The superficial fibular nerve descends in the lateral compartment deep to the fibularis longus and innervates the fibularis longus and fibularis brevis. It then penetrates deep fascia in the lower leg and enters the foot where it divides into medial and lateral branches, which supply dorsal areas of the foot and toes except for:

the web space between the great and second toes, which is supplied by the deep fibular nerve; the lateral side of the little toe, which is supplied by the sural branch of the tibial nerve.

The deep fibular nerve passes anteromedially through the intermuscular septum into the anterior compartment of leg, which it supplies.

Tibial nerve

The nerve associated with the posterior compartment of leg is the tibial nerve, a major branch of the sciatic nerve that descends into the posterior compartment from the popliteal fossa

The tibial nerve passes under the tendinous arch formed between the fibular and tibial heads of the soleus muscle and passes vertically through the deep region of the posterior compartment of leg on the surface of the tibialis posterior muscle with the posterior tibial vessels. The tibial nerve leaves the posterior compartment of leg at the ankle by passing through the tarsal tunnel behind the medial malleolus. It enters the foot to supply most intrinsic muscles and skin.

In the leg, the tibial nerve gives rise to:

• branches that supply all the muscles in the posterior compartment of leg

• two cutaneous branches, the sural nerve and medial calcaneal nerve.

Sural nerve

The sural nerve originates high in the leg between the two heads of the gastrocnemius muscle. It descends superficial to the belly of the gastrocnemius muscle and penetrates through the deep fascia approximately in the middle of the leg where it is joined by a sural communicating branch from the common fibular nerve. It passes down the leg, around the lateral malleolus, and into the foot.

The sural nerve supplies skin on the lower posterolateral surface of the leg and the lateral side of the foot and little toe.

Medial calcaneal nerve

The medial calcaneal nerve is often multiple and originates from the tibial nerve low in the leg near the ankle and descends onto the medial side of the heel. The medial calcaneal nerve innervates skin on the medial surface and sole of the heel.

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