In dynamic situations the foot is required to act as both a shock absorber, to cushion the impact of contact of the foot with the ground, and as a propulsive mechanism to propel the body in the desired direction (Blackwood et al 2005). The foot often performs these functions on a variety of support surfaces. Whereas floor surfaces tend to be firm and level, there are many other situations, such as in cross-country running, where the surface of the ground is neither firm nor level, but continually changes in terms of slope, evenness and hardness. The ability of the foot to function effectively in relation to such diverse environmental constraints is due to its structure, in particular to its arched shape and complex movement capability (Holowka & Lieberman 2018).

The inferior aspect of the talus articulates with the anterior half of the superior aspect of the calcaneus by means of two or, in some cases, three articular facets, which together constitute the subtalar joint (talocalcaneal joint). The anterior aspect (head) of the talus articulates with the posterior aspect of the navicular, on the medial aspect of the foot, to form the talonavicular joint. The anterior aspect of the calcaneus articulates with the posterior aspect of the cuboid, on the lateral aspect of the foot, to form the calcaneocuboid joint. The calcaneocuboid and talonavicular joints are continuous with each other and constitute the midtarsal joint, also referred to as the transverse tarsal joint (Czerniecki 1988). The anterior aspect of the navicular articulates with the posterior aspects of the three cuneiforms (medial, middle, lateral), which lie side by side and articulate with each other. The posterior-superior-lateral aspect of the lateral cuneiform articulates with the superior-medial aspect of the cuboid. The anterior aspects of the medial, middle and lateral cuneiforms articulate with the bases of the first, second and third metatarsals, respectively. The anterior aspect of the cuboid articulates with the bases of the fourth and fifth metatarsals. The joints between the four anterior tarsals and the metatarsals are referred to as the tarsometatarsal joints. The lateral four metatarsals are similar in length, but tend to increase in girth from the second to the fifth. In comparison, the first metatarsal is usually shorter, but has a greater girth than the other four. The metatarsals are collectively referred to as the metatarsus. The heads of the metatarsals articulate with the proximal phalanges of the toes to form the metatarsophalangeal (MTP) joints. The great toe (also referred to as the big toe or the hallux) is composed of two phalanges and each of the other toes is composed of three phalanges. The phalanges of the toes become progressively shorter from proximal to distal.

In addition to the tarsals, metatarsals and phalanges, a number of small accessory bones and sesamoid bones occur during fetal life (Anwar et al 2005, Williams et al 1995 ). There are normally about 10 irregular-shaped accessory bones distributed around the tarsus; most of these bones fuse with one of the tarsal bones prior to skeletal maturity. There are normally about 12 sesamoid (seed-shaped) bones. Each sesamoid bone is partially embedded in a tendon or ligament, with the free surface of the bone forming a synovial joint with a bone over which the tendon or ligament slides during normal function. In addition to preventing the tendon or ligament from rubbing on the adjacent bone, sesamoid bones tend to increase the mechanical efficiency (leverage) of the associated musculotendinous unit or ligament. The two most important sesamoid bones of the foot, which contribute significantly to stabilising the foot during propulsion (see the section on the windlass mechanism later in this chapter), are the sesamoids in the plantar aponeurosis (see later section on arches of the foot) beneath the base of the first MTP joint; the medial sesamoid is shown in Fig. 1.1A.