Anatomy of the Foot and Ankle
Foot Anatomy and Common Foot Problems
Elizabeth Quinn is an exercise physiologist, sports medicine writer, and fitness consultant for corporate wellness and rehabilitation clinics.
Updated on October 17, 2022
Yaw Boachie-Adjei, MD, is a board-certified, double-fellowship Orthopedic Surgeon.
Table of Contents
Table of Contents
The anatomy of the foot and its function can predispose to common foot problems.
Common causes of foot pain include plantar fasciitis, bunions, flat feet, heel spurs, mallet toe, metatarsalgia, claw toe, and Morton’s neuroma. If your feet hurt, there are effective ways to ease the pain This article provides an overview of foot anatomy and foot problems that come from overuse, injury, and normal wear and tear of the foot.
Foot Anatomy
Each of your feet has 28 bones, 30 joints, and more than 100 muscles, ligaments, and tendons. These structures work together to carry out two main functions:
- Weight-bearing
- Propulsion (forward movement)
Plus, the foot must be flexible to adapt to uneven surfaces and remain stable.
The foot has three sections: the forefoot, midfoot, and hindfoot. There are bones, joints, muscles, tendons, and ligaments in each of these sections.
Bones
Forefoot Bones
- Phalanges : These are the toes. They are made up of a total of 14 bones: two for the big toe and three for each of the other four toes.
- Metatarsals : These are five long bones that extend from the base of each toe to the midfoot. The first metatarsal bone leads to the big toe and plays an important role in propulsion (forward movement). The second, third, and fourth metatarsal bones provide stability to the forefoot.
- Sesamoid bones: These are two small, oval-shaped bones beneath the first metatarsal on the underside (plantar surface) of the foot. It is embedded in a tendon at the head of the bone (the part nearest to the big toe). Its role is to reinforce and reduce stress on the tendon.
Midfoot Bones
The midfoot contains five irregularly shaped bones called the tarsals. Together, the tarsals form the arch of the foot. The arch plays a key role in weight-bearing and foot stability.
These bones include:
- Navicular
- Cuboid
- Medial cuneiform
- Intermediate cuneiform
- Lateral cuneiform
Hindfoot
- Calcaneus : This is the large bone at the heel of the foot, also known as the heel bone. Its main function is to transfer most of the body weight from the legs to the ground.
- Talus : This is the bone that sits between the calcaneus and the two bones of the lower leg (the tibia and fibula). It helps transfer weight and pressure across the ankle joint.
Joints
Joints are where two bones meet. In the feet, each big toe has two joints: the metatarsophalangeal joint at the base of the toe and the interphalangeal joint just above it.
The other four toes have three joints each: the metatarsophalangeal joint at the base of the toe, the proximal interphalangeal joint in the middle of the toe, and the distal phalangeal joint closest to the tip of the toe.
Muscles
The muscles that control the movements of the foot start in the lower leg and are attached to the bones in the foot with tendons.
These are the main muscles that facilitate movement in the foot:
- Tibialis posterior: The muscle that supports the foot’s arch
- Tibialis anterior: The muscle that allows the foot to move upward
- Peroneus longus and brevis : The muscles that control movement on the outside of the ankle
- Extensors: The muscles that raise the toes to make it possible to take a step
- Flexors: The muscles that stabilize the toes and curl them under
Tendons
Tendons are fibrous connective tissues that attach muscles to bones. There are three major tendons that help facilitate foot movement, including flexion (forward bending of the foot) and dorsiflexion (backward bending of the foot):
- Achilles tendon: This is the most notable tendon of the foot which runs from the calf muscle to the heel. It is the strongest and largest tendon in the body that makes it possible to run, jump, climb stairs, and stand on your toes.
- Tibialis posterior: This tendon attaches the calf muscle to the bones on the inside of the foot and supports the arch of the foot.
- Tibialis anterior: This runs from the outer bone of the lower leg to the tarsals and first metatarsal which enables dorsiflexion.
Ligaments
Ligaments are fibrous connective tissues that connect bone to bone. These are the primary ligaments of the foot:
- Plantar fascia : This is the longest ligament of the foot that runs from the heel to the toes to form the arch. The plantar fascia provides strength for walking and assists with balance.
- Plantar calcaneonavicular : This is a ligament that connects the calcaneus to the talus. Its role is to support the head of the talus.
- Calcaneocuboid : This is the ligament that connects the calcaneus to the tarsal bones. It helps the plantar fascia support the arch of the foot.
Common Foot Problems
The average person has walked about 75,000 miles by age 50. Given how many moving parts there are in the foot, it’s not surprising how vulnerable it is to injury or overuse.
Nine conditions specific to the foot can cause pain, restrict the movement of the foot, or lead to foot instability.
Plantar Fasciitis
Plantar fasciitis is caused by microtears in the thick fibrous tissue on the underside of the foot, usually due to overstretching. Symptoms include pain in the heel and arch that is often worse in the mornings. Plantar fasciitis is common among-distance walkers or runners.
Bunions
A bunion is a bony protrusion on either the inside edge of the foot or the pinkie toe side. Bunions form gradually when the bones in the foot become misaligned, often due to wearing shoes that don’t fit well or that squeeze the toes together tightly.
The big toe can bend so far inward that it actually crosses under or over the adjacent toe, causing a secondary misalignment called a hammertoe. Usually, a painful callous will form on top of the second toe.
Flat Feet
Pes planus (flat feet) is when the arc of the foot straightens out, often so completely that the entire sole comes in contact with the floor.
Flat feet can cause pain in the midfoot area as well as swelling of the ankle and arch. The imbalance can also lead to hip, knee, or lower back pain.
Pes planus can be congenital (meaning you are born with it), but more often it is a result of age or injury. Between 20% and 30% of people have some degree of flat-footedness.
Heel Spurs
As the largest bone in the foot, the calcaneus (heel) is prone to injury caused by faulty foot biomechanics (meaning problems with your gait).
One of the more common is the development of bony overgrowth called heel spurs that cause severe pain when standing or walking. Also known as calcaneal spurs, heel spurs are most common in people who have plantar fasciitis, flat feet, or high arches.
Mallet Toe
With a mallet toe, the joint in the middle of a toe becomes permanently bent to the extent that it points downward.
Mallet toes develop because of an imbalance in the muscles, tendons, or ligaments that hold the bones straight. As with bunions and hammertoe, mallet toe often forms as a result of wearing ill-fitting shoes, although it can also be caused by trauma or certain diseases.
Metatarsalgia
Metatarsalgia is pain under the ball of the foot. It is often the result of pressure caused by high heel shoes or from conditions such as arthritis, nerve compression, or fractures or tears in ligaments that support the ball of the foot.
Claw Toe
A claw toe is a deformity in which a toe bends downward from the middle joints and can sometimes even curl under the foot entirely. When this happens, callouses or corns will form on top of the affected toe. Sometimes, a corn can place pressure on nerves in the foot, causing pain.
Morton’s Neuroma
This is a common problem in which compression on a nerve in the ball of the foot causes burning, tingling, and pain near the third and fourth toes. High heels are most often the culprit. Morton’s neuroma can make you feel like you have a pebble in your shoe or on a fold in your sock.
Medical Conditions That Can Cause Foot Problems
The feet are subject to a variety of medical problems, including:
- Sprains and strains
- Ruptured tendon or ligament
- Bone fractures
- Tendinitis (tendon inflammation)
- Osteoarthritis (“wear-and-tear arthritis”)
- Rheumatoid arthritis (autoimmune arthritis)
- Diabetes
- Gout
- Athlete’s foot
- Onychomycosis (nail fungal infection)
Diagnosis
To diagnose problems related to the anatomical structures in the foot, your healthcare provider or an orthopedic specialist will look at your foot to look for signs of swelling, deformity, skin growth, or misalignment.
They will review your symptoms and medical history and ask you to walk around to look for abnormalities in your gait (referred to as a gait analysis).
Imaging tests are often central to the diagnosis and can include:
- X-ray: This standard imaging test involves low-level radiation and is suitable for detecting things like bone fractures, dislocations, or arthritis damage.
- Computed tomography (CT): This imaging technology combines multiple X-rays to create a more three-dimensional representation of the foot structure.
- Magnetic resonance imaging (MRI): This imaging technique uses a powerful magnet and radio waves to create highly detailed images without radiation. It is especially good at imaging soft tissues.
Treatment
The treatment for a foot problem will depend on the underlying cause.
Foot pain from any cause can often be relieved with over-the-counter painkillers such as Tylenol (acetaminophen), Advil (ibuprofen), or Aleve (naproxen).
More severe cases may require steroid injections to reduce joint inflammation or prescription pain relievers like Celebrex (celecoxib) to relieve chronic arthritis pain.
For foot problems caused by anatomical deformities, foot orthotics (inserts worn inside the shoes) can help compensate for these problems and reduce pain. Standard versions are available in pharmacies, but often a doctor will order custom-made orthotics or custom-fitted shoes.
Physical therapy can improve the strength and flexibility of the feet and ankles. Sometimes conditions like a displaced fracture, bunions, or hammertoe will require surgery if they are causing severe pain or disability.
Summary
The foot is a complex structure comprised of bones, joints, muscles, ligaments, and tendons. It is vulnerable to injury both from trauma and overuse, as well as diseases and infections. Among some of the more common structural foot problems are bunions, claw toes, flat feet, hammertoes, heel spurs, mallet toes, metatarsalgia, Morton’s neuroma, and plantar fasciitis.
The diagnosis of a structural foot problem may involve a physical exam, a review of your symptoms and medical history, a gait analysis, and an imaging test such as an X-ray, CT scan, or MRI scan.
The treatment can vary based on the condition but may involve over-the-counter or prescription painkillers, foot orthotics, custom-fitted shoes, physical therapy, or surgery.
Frequently Asked Questions
What is the bottom of your foot called?
The bottom of the foot is known as the sole. The padded area on the bottom of the foot is known as the plantar aspect.
What is the top of your feet called?
The top of your foot above the arch is known as the instep. In medical terms, the top of the foot is the dorsum or dorsal region. The back of the hand is also known as the dorsal region.
What are common foot problems in older adults?
- Foot pain
- Peripheral neuropathy (nerve damage)
- Arthritis
- Plantar fasciitis
- Metatarsalgia
- Hallux rigidus (degenerative disease of the first metatarsal)
- Lesser toe deformities
- Hyperkeratosis
- Plantar heel pain
Verywell Health uses only high-quality sources, including peer-reviewed studies, to support the facts within our articles. Read our editorial process to learn more about how we fact-check and keep our content accurate, reliable, and trustworthy.
- Bito T, Tashiro Y, Suzuki Y, et al. Forefoot transverse arch height asymmetry is associated with foot injuries in athletes participating in college track events.J Phys Ther Sci. 2018;30(8):978–983. doi:10.1589/jpts.30.978
- Freedman BR, Gordon JA, Soslowsky LJ. The Achilles tendon: fundamental properties and mechanisms governing healing.Muscles Ligaments Tendons J. 2014;4(2):245–255. PMID: 25332943
- American Podiatric Association. Winter foot care: Tips to keep feet warm and cozy all winter long.
- Petraglia F, Ramazzina I, Costantino C. Plantar fasciitis in athletes: diagnostic and treatment strategies. A systematic review.Muscles Ligaments Tendons J. 2017;7(1):107–118. doi:10.11138/mltj/2017.7.1.107
- Pita-Fernandez S, Gonzalez-Martin C, Alonso-Tajes F, et al. Flat Foot in a Random Population and its Impact on Quality of Life and Functionality.J Clin Diagn Res. 2017;11(4):LC22–LC27. doi:10.7860/JCDR/2017/24362.9697
- Park SY, Bang HS, Park DJ. Potential for foot dysfunction and plantar fasciitis according to the shape of the foot arch in young adults.J Exerc Rehabil. 2018;14(3):497–502. doi:10.12965/jer.1836172.086
- Rodríguez-Sanz D, Tovaruela-Carrión N, López-López D, et al. Foot disorders in the elderly: A mini-review. Dis Mon. 2018;64(3):64-91. doi:10.1016/j.disamonth.2017.08.001
- Muchna A, Najafi B, Wendel CS, Schwenk M, Armstrong DG, Mohler J. Foot problems in older adults: associations with incident falls, frailty syndrome, and sensor-derived gait, balance, and physical activity measures. Journal of the American Podiatric Medical Association. 2018;108(2):126-139. doi:10.7547/15-186
Additional Reading
- American Academy of Orthopaedic Surgeons. Posterior Tibial Tendon Dysfunction.
- Arthritis Foundation. Anatomy of the Foot.
- Mayo Clinic. Hammertoe and Mallet Toe.
By Elizabeth Quinn
Elizabeth Quinn is an exercise physiologist, sports medicine writer, and fitness consultant for corporate wellness and rehabilitation clinics.
Anatomy of the Foot and Ankle
A solid understanding of anatomy is essential to effectively diagnose and treat patients with foot and ankle problems. Anatomy is a road map. Most structures in the foot are fairly superficial and can be easily palpated. Anatomical structures (tendons, bones, joints, etc) tend to hurt exactly where they are injured or inflamed. Therefore a basic understanding of surface anatomy allows the clinician to quickly establish the diagnosis or at least narrow the differential diagnosis. For those conditions that require surgery a detailed understanding of anatomy is critical to ensure that the procedure is performed efficiently and without injuring any important structures. With a good grasp of foot anatomy it readily becomes apparent which surgical approaches can be used to access various areas of the foot and ankle.
There are a variety of anatomical structures that make up the anatomy of the foot and ankle (Figure 1) including bones, joints, ligaments, muscles, tendons, and nerves. These will be reviewed in the sections of this chapter.
Figure 1: Bones of the Foot and Ankle
Regions of the Foot
The foot is traditionally divided into three regions: the hindfoot, the midfoot, and the forefoot (Figure 2). Additionally, the lower leg often refers to the area between the knee and the ankle and this area is critical to the functioning of the foot.
The Hindfoot begins at the ankle joint and stops at the transverse tarsal joint (a combination of the talonavicular and calcaneal-cuboid joints). The bones of the hindfoot are the talus and the calcaneus.
The Midfoot begins at the transverse tarsal joint and ends where the metatarsals begin –at the tarsometatarsal (TMT) joint. While the midfoot has several more joints than the hindfoot, these joints have limited mobility. The five bones of the midfoot comprise the navicular, cuboid, and the three cuneiforms (medial, middle, and lateral).
The Forefoot is composed of the metatarsals, phalanges, and sesamoids. The bones that make up the forefoot are those that are last to leave the ground during walking. There are twenty-one bones in the forefoot: five metatarsals, fourteen phalanges, and two sesamoids. The great toe has only a proximal and distal phalanx, but the four lesser toes each have proximal, middle, and distal phalanges, which are much small than those of the great toe. There are two sesamoid bones embedded in the flexor hallucis brevis tendons that sit under the first metatarsal at the level of the great toe joint (1st metatarsophalangeal joint).
Figure 2: Regions of the Foot
Columns of the Foot
The foot is sometimes described as having two columns (Figure 3). The medial column is more mobile and consists of the talus, navicular, medial cuneiform, 1st metatarsal, and great toe. The lateral column is stiffer and includes the calcaneus, cuboid, and the 4th and 5th metatarsals.
Figure 3: Columns of the Foot
Bones and Joints
The foot is comprised of 28 bones (Figure 1). Where two bones meet a joint is formed –often supported by strong ligaments. It is helpful to think of the joints of the foot based on their mobility (Table 1). A few of the joints are quite mobile and are required for the foot to function normally from a biomechanical point of view. These are often referred to as essential joints. There are some joints that move a moderate amount, and there are other joints that are held tightly together with strong ligaments. These non-mobile joints are sometimes referred to as non-essential joints. (This may be a poor term in that it incorrectly implies that the joints are not important; they are important. Rather the correct sense is only that movement from these joints is less critical.)
Table 1: Joint Function in the Foot
Mobile Joints of the Foot and Ankle (Essential Joints):
Ankle joint (tibiotalar joint)
Talonavicular joint (TN joint)
Metatarsophalangeal (MTP) joints
Joints that Move a Moderate Amount:
Cuboid-metatarsal joint for the fourth and fifth metatarsal.
Proximal interphalangeal joint (PIP)
Distal interphalageal joint (DIP)
Joints with Minimal Movement (Non-Essential Joints):
Tarsometatarsal (TMT) joint “Lisfranc” Joint (a.k.a. midfoot joint)
Bones of the lower leg and hindfoot: Tibia, Fibula, Talus, Calcaneus.
Joints of the hindfoot: Ankle (Tibiotalar), Subtalar.
Tibia and Fibula (long bones)
The foot is connected to the body where the talus articulates with the tibia and fibula. In a typical foot the tibia is responsible for supporting about 85% of body weight. The fibula accepts the remaining 15%; its main role is to serve as the lateral wall of the ankle mortise (Figure 4). The tibia and fibula are held together by the tibiofibular syndesmosis, a collection of 5 ligaments. The prominence on the medial side of the distal tibia is known as the medial malleolus; the distal aspect of the fibula is known as the lateral malleolus.
Figure 4: Ankle Joint Anatomy
Talus
The talus is the top (most proximal) bone of the foot. Because it articulates with so many other bones, 70% of the talus is covered with hyaline cartilage (joint cartilage). The talus connects to the calcaneus on the underside through the subtalar joint, and distally it connects to the navicular through the talonavicular joint. These articulations allow the foot to rotate smoothly around the talus. Owing primarily to the fact that no tendons attach to it and that most of its surface is cartilage, the talus has a relatively poor blood supply. The lack of a robust blood supply means that injuries to this bone take greater time to heal than might be the case with other bones—and some injuries will not heal at all.
The talus is generally thought of as having three parts: the body, the head, and the neck (Figure 5). The talar body, which is roughly square in shape and is topped by the dome, connects the talus to the lower leg at the ankle joint. The talar head is adjacent to the navicular bone to form the talonavicular joint. The talar neck is located between the body and head of the talus. The talar neck is one of the few areas of the talus not covered with cartilage, and is thus the point of entry for the blood vessels supplying the talus.
Figure 5: Talus Anatomy
Calcaneus
The calcaneus is commonly known as the heel bone. The calcaneus is the largest bone in the foot, and along with the talus, it makes up the area of the foot known as the hind-foot. There are three protrusions (anterior, middle, and posterior facet) on the superior surface of the calcaneus that allow the talus to sit on top of the calcaneus, forming the subtalar joint (Figure 6). The calcaneus also connects to the cuboid bone to form the calcaneal-cuboid joint.
Subtalar Joint
The talus rests above the calcaneus to form the subtalar joint (Figure 6) slightly offset laterally, towards the 5th metatarsal/small toe. This lateral positioning allows greater flexibility in inversion/eversion (tilting). The subtalar joint moves in concert with the talonavicular joint and the calcaneocuboid joint, two joints located near the front of the talus.
Figure 6: Calcaneal Anatomy
Bones of the midfoot: Cuboid, Navicular, Cuneiform (3).
Joints of the midfoot: talonavicular, calcaneocuboid, intercunneiform, tarsometatarsal (TMT).
Cuboid
The cuboid bone is a square-shaped bone on the lateral aspect of the foot. The main joint formed with the cuboid is the calcaneocuboid joint, where the distal aspect of the calcaneus articulates with the cuboid.
Navicular
The navicular is distal to the talus and connects with it through the talonavicular joint. The distal aspect connects to each of the three cuneiform bones. Like the talus, the navicular has a poor blood supply. On its medial side (closest to the middle of the foot) the navicular tuberosity is the main attachment of the posterior tibial tendon.
Transverse Tarsal Joint
The transverse tarsal joint is not a true joint, but the combination of the calcaneocuboid and talonavicular joints. When these two joints are aligned in parallel, the foot is flexible yet when their axes are divergent, the foot becomes stiff. The shift from a flexible state to a stiff one allows the foot to serve as a shock absorber and as a rigid level in different phases of gait.
Cuneiforms
There are three cuneiform bones in the foot: the medial, medial (intermediate), and lateral cuneiforms (Figure 7). These bones, along with the strong plantar and dorsal ligaments that connect to them, provide a good deal of stability for the foot.
Bones of the forefoot: Metatarsals (5), Phalanges (14), Sesamoid Bones (2)
Metatarsals
Each foot contains five metatarsals, numbered 1-5 medial (great toe) to lateral. The first three metatarsals medially are more rigidly held in place than the lateral two. The metatarsals articulate with the mid-foot at their base, a joint called the tarsal-metatarsal (TMT) joint, or Lisfranc joint. The TMT joint is made stable not only by strong ligaments connecting these bones, but also because the second metatarsal is recessed into the middle cuneiform in comparison to the others (Figure 7). The metatarsal heads are the main weight bearing surface and the site where the phalanges attached at the metatarsal-phalangeal (MTP) joint.
Figure 7: Lisfranc (Tarsometatarsal) Joint
Phalanges
The first toe, also known as the great toe or hallux, is the only one to have two phalanges; the other lesser toes have three. These are known as the proximal phalanx (closest to the ankle) and the distal phalanx (farthest from the ankle). The phalanges form interphalangeal joints between themselves: a proximal interphalaneal joint (PIP) and the distal interphalangeal joint (DIP) (Figure 8).
Figure 8: Joints of the Toes
Sesamoid Bones
In the foot, there are two sesamoid bones located directly underneath the first metatarsal head, embedded in the medial (tibial) side and lateral (fibular) aspect of the flexor hallucis brevis tendon.
Common Ossicles of the Foot
Some feet contain accessory ossicles or accessory bones (Figure 9). These extra bones are developmental variants. Over 40 different ossicles of the foot have been reported. The most common accessory bones include:
Os Trigonum: Found at the posterior aspect of the talar body, this ossicle is connected to the talus via a fibrous union that failed to unite (ossify) between the lateral tubercle of the posterior process. An os trigonum is present in about 10% of the population.
Os Naviculare (Os Tibiale Externum or Accessory Navicular): This bone represents a failure to unite the ossification center the navicular tuberosity (where the tibialis posterior tendon inserts) to the main center of the bone. It is present in about 15% of the population.
Os Peroneum: This extra bone is found within the peroneus longus tendon sheath at the point where it wraps around the cuboid. It has been reported in about 20% of patients.
Bipartite Sesamoid: This condition occurs when one of the sesamoids associates with the great toe fails to ossify resulting in two bone segments connected by a fibrous union. It can be mistaken for a sesamoid fracture. Bipartite sesamoids are seen in about 20% of the population with more than 90% of them occurring in the tibial sesamoid.
Os Subfibulare: This extra bone is seen at the type of the fibula. It can be mistaken for an avulsion fracture. It is seen in 1-2% of the population.
Figure 9: Common Accessory Ossicles of the Foot
Ligaments
The Anterior TaloFibular Ligament (ATFL)
The anterior talofibular ligament (Figure 10) is the most commonly injured ligament when an ankle is sprained. The ATFL runs from the anterior aspect of the distal fibula (lateral malleolus) down and to the outer front portion of the ankle in order to connect to the neck of the talus. It stabilizes the ankle against inversion, especially when the ankle is plantar-flexed.
The CalcaneoFibular Ligament (CFL)
The calcaneofibular ligament (Figure 10) is also on the lateral side of the ankle. It starts at the tip of the fibula and runs along the lateral aspect of the ankle and into the calcaneus. It too resists inversion, but more when the ankle is dorsiflexed.
Posterior TaloFibular Ligament
The posterior talofibular ligament runs from the back lower part of the fibula and into the outer back portion of the calcaneus (Figure 10). This ligament functions to stabilize the ankle joint and subtalar joint.
Figure 10: Lateral Ankle Ligaments
The Deltoid Ligament
The deltoid ligament is a fan shaped band of connective tissue on the medial side of the ankle (Figure 11). It runs from the medial malleolus down into the talus and calcaneus. The deeper branch of the ligament is securely fastened in the talus, while the more superficial, broader aspect runs into the calcaneus. This ligament functions to resist eversion.
Figure 11: Medial Deltoid Ligament
Spring Ligament
The spring ligament (Figure 11) is a strong ligament that originates on the sustentaculum tali – a bony prominence of the calcaneus on the medial aspect of the hindfoot. The spring ligament inserts into the plantar medial aspect of the navicular and serves to cradle and support the talar head.
Lisfranc Ligaments
The Lisfranc joint complex is a series of ligaments that stabilize the tarsometatarsal joints. These ligaments prevent the joints of the midfoot from moving much, and as such provide considerable stability to the arch of the foot. The plantar ligaments are stronger than those on the dorsal side (Figure 12 & 13). The Lisfranc ligament is a strong band of tissue that connects the medial cuneiform to the base of the second metatarsal.
The Inter-Metatarsal Ligaments
These ligaments run between the metatarsal bones at the base of the toes (Figure 12). They connect the neck region of each metatarsal to the one next to it, and bind them together. This keeps the metatarsals moving in sync. While it is possible to tear these ligaments, it is also possible for them to irritate the digital nerve as it crosses the ligaments creating a Morton’s neuroma.
The 1st MTP joint Capsule of the Great Toe
The connective tissue of this ligament takes the form of a capsule (Figure 12). It goes from the medial portion of the first metatarsal head and stretches to the distal phalanx on the same side. This allows this ligament to stabilize the great toe on the medial side. In the situation where a person develops a bunion, this band gets stretched out, and the great toe changes position and becomes angulated outward.
Figure 12: Plantar Ligaments
Anterior Inferior TibioFibular Ligament (AITFL)
The anterior inferior tibiofibular ligament (Figure 4) is positioned on the anterolateral aspect of the ankle joint and serves to helps keep the tibia and fibula together. Injuries to this ligament, so called high ankle sprains, occur when the foot is stuck on the ground while the leg rotates inwards.
The Interosseous Membrane
The interosseous membrane is composed of strong fibrous tissue and runs along the tibia and fibula, and keeps the two bones moving as one unit (Figure 4).
The syndesmosis
The ligament group formed by the AITFL and the interosseous membrane, joined by the posterior inferior tibiofibular ligament, the transverse ligament and the interosseous ligament is known as the syndesmosis. The function of the syndesmosis is to hold the tibia and fibula together at the appropriate distance, thereby forming the mortise into which the talus sits
Muscles and Tendons
There are four muscle compartments in the lower leg (Figure 13) each separated by strong fascia:
- the superficial posterior compartment;
- the deep posterior compartment;
- the anterior compartment and;
- the lateral compartment
Collectively the muscles in these four compartments are referred to as the extrinsic muscles of the foot because they originate above the foot in the leg, but insert within the foot.
Figure 13: Muscle Compartments of the Lower Leg
Superficial Posterior Compartment
The superficial posterior compartment of the leg holds the two large muscles of the calf, the gastrocnemius and the soleus, which both run along the length of the leg joining to form the Achilles tendon. Both gastrocnemius and soleus muscles are innervated by the tibial nerve. The gastrocnemius is the more superficial of the posterior calf muscles. It originates above the knee joint, off the posterior femur, and inserts into the calcaneus. The soleus is the deeper of the two muscles of the calf and does not cross the knee. There is a smaller third muscle of the superficial posterior compartment called the plantaris. It is very small and not functionally important in most people (but is subject to injury nonetheless).
Deep Posterior Compartment
This muscle compartment is located on the backside of the leg deep to the soleus muscle. There are three muscles in this compartment, the flexor hallucis longus, the flexor digitorum longus, and the tibialis posterior. All three of these muscles cross the ankle and insert on bones of the foot, the hallux, the lessor toes and the navicular, respectively. They are innervated by the tibial nerve.
Anterior Compartment
The anterior compartment is comprised of four muscles that extend (dorsiflex) the foot and ankle (Figure 14). The Tibialis Anterior, the Extensor Hallucis Longus, the Extensor Digitorum Longus and the Peroneus Tertius. The deep peroneal nerve innervates all the muscles of the anterior compartment.
Figure 14: Dorsiflexors of the Foot and Ankle
Lateral Compartment
The last of the muscle compartments of the lower leg is the lateral compartment (Figure 15) is comprised of two muscles, the peroneus longus and the peroneus brevis. Both cross the ankle, but the peroneus longus wraps underneath the cuboid crossing the plantar aspect of the foot as well, and inserts at the base of the first metatarsal. The peroneus brevis inserts at the base of the fifth metatarsal on the lateral aspect of the foot. These two muscles work together to evert the foot – move it towards the lateral side. The peroneus longus also functions to plantarflex the first metatarsal. Both of these muscles are controlled by the superficial peroneal nerve.
Figure 15: Lateral Compartment Muscles
Muscles within the Foot
There are a large number of smaller muscles deep inside the foot. They help move the toes and stabilize the foot. Collectively they are referred to as the intrinsic muscles of the foot because they are entirely contained within the foot. Only two of these muscles are located on the dorsal aspect (top) of the foot: the extensor hallucis brevis, and the extensor digitorum brevis. They are both innervated by the deep peroneal nerve. Their primary purpose is to help extend the toes. This is in contrast to the flexor hallucis brevis and flexor digitorum brevis. These muscle tendon units are located deep in the plantar arch and respectively assist in flexing the great toe and the four lesser toes. They are innervated by the medial plantar nerve.
Plantar Fascia
The plantar fascia is not a nerve, tendon or muscle, but rather a strong fibrous tissue (Figure 16). This tissue originates deep within the plantar surface of the calcaneus (heel bone) and covers the distance to the base of each of the five toes. When the foot rolls off the ground during walking, the toes dorsiflex and pull on the plantar fascia. This motion tends to tighten the plantar fascia, and thereby supports the arch of the foot, by maintaining the distance between the calcaneus and the metatarsal heads – a phenomenon known as the windlass mechanism. This stiff and relatively impermeable covering helps to protect the muscles of the sole of the foot.
Figure 16: Plantar Fascia
Nerves
Nerves of the Foot
There are five main nerves that run past the ankle into the foot (Figure 17). All five of these are derived from two nerves that originate from the lumbar spine. The sciatic nerve branches into four of the five primary nerves of the foot. Two segments of the sciatic nerve branch before the knee joint: the tibial nerve and peroneal nerve. The tibial nerve gives off a branch called the sural nerve. Near the level of the knee the peroneal nerve splits into the deep peroneal nerve and the superficial peroneal nerve. The fifth nerve of the foot originates from the femoral nerve and is called the saphenous nerve.
Figure 17: Major Nerves of the Foot and Ankle
The Deep Peroneal Nerve
The deep peroneal nerve is one of two parts of the peroneal nerve (Figure 17). The deep peroneal nerve runs directly under the head of the fibula. It is responsible for controlling the muscles of the anterior compartment of the leg, and continues down the front of the ankle to the dorsal surface of the foot. It is responsible for the sensation in the small area between the first and second toes, an area known as the first web space. If this nerve doesn’t function, there will be no sensation in this area. If motor function is lost, it becomes impossible to lift the foot upwards, a symptom known as a “drop foot”.
The Superficial Peroneal Nerve
The superficial peroneal nerve is the partner of the deep peroneal nerve (Figure 17). It runs on the lateral side of the leg below the knee under the head of the fibula and innervates the lateral compartment muscles. It runs down over the anterolateral aspect of the ankle and splits into several branches on the dorsal aspect of the foot. The superficial peroneal nerve has both motor and sensory neurons for most of its length, but below the ankle is made entirely of sensory nerves. If motor function of this nerve is lost, it becomes impossible to evert the foot but there is no motor function lost distal to the ankle.
Tibial Nerve
The tibial nerve controls all the muscles behind the tibia and fibula in the back part of the calf (deep and superficial posterior compartment muscles). The tibial nerve continues down into the deep inner part of the ankle and splits into two branches, the medial plantar nerve and the lateral plantar nerve (Figure 17). These two branches provide sensation to the entire sole of the foot, and innervate all the tiny muscles of the sole of the foot.
Sural Nerve
The fourth nerve of the foot is another branch of the tibial nerve, known as the sural nerve (Figure 17). This nerve runs from slightly below the knee to the lateral aspect of the foot. It becomes a very superficial nerve at the level of the posterolateral ankle and continues distally to provide sensation to the outside of the foot. It has no motor function.
Saphenous Nerve
The fifth and last nerve is the only one to branch off from the femoral nerve (Figure 17). It runs from medial aspect of the knee and runs over the anteromedial aspect of the ankle joint to provide sensation to the inside of the foot.
Although the positions of these nerves are generally as described, there is a certain amount of variability in nerve position. They can be located lower or higher than described. These variations must be considered while performing surgery.