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Cuboid bone

The cuboid bone is one of the seven tarsal bones of the human foot, situated in the lateral aspect of the midfoot as part of the distal row of the tarsus, forming the central portion of the lateral column between the posteriorly and the fourth and fifth metatarsals anteriorly. It exhibits a roughly cubical with a prominent tuberosity on its plantar surface, providing structural support and serving as an attachment site for key ligaments and muscles. Anatomically, the cuboid bone features six surfaces: a posterior articular surface for the , an anterior surface divided into facets for the bases of the fourth and fifth metatarsals, a medial surface with articulations to the lateral and navicular bones, a lateral surface containing the peroneal sulcus (or groove) that accommodates the of the peroneus longus muscle, a superior () surface that is rough for ous attachments, and an inferior (plantar) surface marked by the aforementioned tuberosity. These surfaces enable the cuboid to participate in three primary joints: the posteriorly, the cuboido-navicular and cuboido-cuneiform joints medially, and the cubo-metatarsal joints anteriorly, all stabilized by ligaments such as the long plantar , plantar calcaneocuboid , and bifurcate . Its blood supply primarily derives from branches of the lateral plantar , a continuation of the , while muscles like the tibialis posterior insert on its medial aspect and the flexor hallucis brevis originates from its plantar tuberosity. Functionally, the cuboid bone contributes to the and propulsion of the lateral midfoot during , acting as a for the peroneus longus to evert the foot and flex the first metatarsal, while also facilitating the transverse arch and overall foot mobility. Clinically, it is implicated in conditions such as , characterized by subluxation or dysfunction at the often due to inversion injuries, and rare fractures like the "nutcracker" type resulting from compressive forces during forefoot , which may require or surgical intervention depending on displacement. Additionally, congenital anomalies such as tarsal coalitions involving the cuboid are uncommon, occurring in less than 1% of cases.

Anatomy

Location and gross features

The cuboid bone is one of the seven tarsal bones, situated on the lateral side of the foot within the distal row of the tarsus. It forms a key component of the lateral column of the foot, connecting the hindfoot to the forefoot. Positioned anterior to the and posterior to the bases of the fourth and fifth metatarsals, the lies lateral to the lateral bone and contributes to the overall stability of the midfoot. This arrangement places it at the center of the lateral foot, facilitating load transmission during weight-bearing activities. The cuboid exhibits a roughly cuboidal prism shape, characterized by a dorsal surface and a plantar surface, which accommodates the arch of the foot. In adults, its dimensions typically range from 2 to 3 cm in length, with reported averages including a medial length of approximately 33.4 mm, lateral length of 19.7 mm, and height of 26.2 mm, though these vary by and individual factors. Prominent external features include a plantar tuberosity on the inferior surface, serving as an attachment site for ligaments, and a groove on the inferior aspect that accommodates the tendon of the peroneus longus muscle.

Surfaces and borders

The cuboid bone, resembling a cube, features six distinct surfaces that contribute to its role in the lateral midfoot. The dorsal surface is convex and roughened, providing attachment sites for the dorsal cubo-metatarsal ligaments. The plantar surface is concave overall, marked by a deep peroneal sulcus (or groove) that runs obliquely forward and medially, forming a fibro-osseous tunnel with the inferior calcaneus for the passage of the peroneus longus tendon; laterally, it bears a prominent tuberosity that projects downward and serves as the primary attachment for the long plantar ligament. The medial surface is broad and irregularly quadrilateral, presenting an anterior articular facet for the lateral cuneiform bone and a smaller posterior facet for the navicular bone in some individuals, separated by a narrow non-articular strip. The lateral surface is smooth and largely non-articular, featuring a shallow notch at its posterior-inferior margin where the peroneus longus tendon emerges from the peroneal groove. The anterior surface is obliquely oriented and divided by a central ridge into two articular facets: a smaller medial quadrilateral facet for the base of the fourth metatarsal and a larger lateral triangular facet for the base of the fifth metatarsal. The posterior surface is large, saddle-shaped, and concavo-convex, forming the primary articular facet for the anterior aspect of the calcaneus at the calcaneocuboid joint. The borders of the cuboid bone define its irregular pyramidal shape, with the superior border corresponding to the dorsal margin, the inferior to the plantar margin, the medial border concave to accommodate adjacent tarsals, the lateral border convex for lateral stability, the anterior border oblique and irregular to match metatarsal bases, and the posterior border rounded for calcaneal articulation. Morphometric variations in the cuboid bone include average dimensions such as a medial length of approximately 33.9 mm, lateral length of 17.9 mm, and height of 22 mm, with articular facet areas averaging 124.9 mm² for the calcaneal surface and 91.9 mm² for the metatarsal surfaces; the plantar surface area has been estimated around 4-5 cm² in imaging studies of joint congruency. In South Indian populations, the cuboid exhibits a mean length of 33.69 mm, which is relatively longer compared to some other ethnic groups, alongside variations in facet presence such as a navicular facet in 26.2% of cases and an os peroneum facet in 74.76%.

Articulations

The cuboid bone forms several synovial with adjacent tarsal and , contributing to the lateral column of the foot and enabling limited mobility for adaptation to terrain. These articulations include the posterior , anterior cubometatarsal joints, medial cuboid-cuneiform joint, and an occasional cuboid-navicular joint, each characterized by specific articular surfaces and ligamentous support that enhance stability without direct muscular insertions across the joints themselves. The calcaneocuboid joint is a saddle-type synovial joint located posteriorly, where the anterior quadrilateral surface of the calcaneus articulates with the concave posterior surface of the cuboid, allowing limited flexion-extension (dorsiflexion-plantarflexion) and inversion-eversion movements essential for foot pronation and supination. This joint is reinforced by the bifurcate ligament (specifically its calcaneocuboid portion), the long plantar ligament spanning from the calcaneus to the metatarsal bases, and the short plantar (plantar calcaneocuboid) ligament, which provide tensile strength against excessive eversion and maintain the longitudinal arch. The saddle morphology, with reciprocal convex-concave curvatures, confers inherent stability through bone interlock, supplemented by these ligaments that limit excessive translation. Anteriorly, the articulates with the bases of the fourth and fifth metatarsals via two plane synovial joints, known as the cubometatarsal or lateral , which permit slight motions to accommodate foot flexibility during . These planar interfaces feature relatively flat articular facets on the cuboid's anterior surface, enabling minimal dorsal-volar and medial-lateral shifts while being stabilized by interosseous ligaments and the overarching long plantar ligament, preventing significant dislocation. Medially, the forms a small synovial with the lateral through a narrow articular facet on its medial border, contributing to the transverse tarsal (midtarsal) arch by linking the medial and lateral midfoot columns. This cubocuneiform articulation allows limited inter-tarsal gliding, reinforced by dorsal, plantar, and interosseous cuneocuboid ligaments that integrate it into the broader ligamentous network of the midfoot. An occasional cuboid-navicular exists via a small posterior medial facet on the articulating with the inferolateral navicular, present in approximately 20-50% of individuals depending on population studies, though full is (<1%). When present, this syndesmotic-like adds minor medial but is and often absent, with ligaments such as the cuboideonavicular bridging any gap. Overall, the stability of these cuboid articulations relies on a combination of osseous contours for congruence, extensive ligamentous reinforcements that resist shear forces, and indirect influence from nearby peroneal tendons passing through the 's plantar groove, without direct muscular crossings. Anatomically, the 's lateral aspect lies adjacent to the sinus tarsi and inferior peroneal retinaculum, positioning these joints within the lateral midfoot framework for load transmission.

Ligaments and muscle attachments

The cuboid bone serves as an attachment site for several key ligaments that contribute to the stability of the lateral midfoot. The long plantar ligament originates from the plantar surface of the calcaneus, passes over the plantar aspect of the cuboid where it adheres to a prominent ridge behind the peroneal sulcus, and extends to the bases of the second through fifth metatarsal bones. The short plantar ligament, also known as the plantar calcaneocuboid ligament, arises from the anterior tubercle of the calcaneus and inserts onto the lateral aspect of the cuboid's plantar surface, providing reinforcement to the calcaneocuboid joint. Additional ligaments connecting the cuboid include the bifurcate ligament, whose lateral calcaneocuboid band extends from the anterolateral to the medial surface of the cuboid, forming part of the Y-shaped structure that stabilizes the talonavicular and calcaneocuboid joints. Dorsal cubometatarsal ligaments attach to the rough dorsal surface of the cuboid, linking it to the fourth and fifth metatarsals, while the plantar calcaneocuboid ligament directly reinforces the inferior aspect of the cuboid-calcaneus articulation. Interosseous ligaments, such as the cuneocuboid and cubonavicular varieties, bind the medial surface of the cuboid to adjacent tarsal bones like the lateral and navicular. Anatomical variations may include accessory bands or extensions of these ligaments, such as supplemental fibers of the long plantar ligament observed in certain populations, which can enhance lateral foot stability. Regarding muscle attachments, the tibialis posterior tendon provides the primary direct muscular insertion onto the , with its plantar branch attaching to the medial aspect of the bone's inferior surface, aiding in foot inversion. The originates in part from the medial plantar tuberosity and adjacent plantar surface of the , splitting into medial and lateral heads that insert onto the proximal of the great . Tendon interactions with the are notable for the peroneus longus, whose glides through the oblique peroneal sulcus on the plantar surface of the without direct attachment, utilizing the bone as a for its course to the first metatarsal and medial . The peroneus brevis passes anteriorly over the after emerging inferior to the lateral , en route to its insertion on the fifth metatarsal base. Nearby, the extends from the lateral to the , positioned posterior to the and contributing to overall ankle stability without direct attachment to the bone.

Development and ossification

Embryonic development

The cuboid bone originates as part of the lateral tarsal mesenchyme within the developing limb bud, derived primarily from the with contributions from somitic mesoderm during the 5th to 6th week of . This mesenchymal tissue arises from condensations along the ectodermal ridge in the postaxial (fibular) region of the foot plate, establishing the foundational elements of the hindfoot. By the end of the 6th week, these condensations differentiate into a cartilaginous precursor, marking the initial formation of the cuboid anlage in the distal row of tarsal elements. The develops within the hindfoot , a mesenchymal mass that segments into discrete skeletal precursors under the influence of key genetic regulators. , particularly HoxD13, play a critical role in autopodal patterning, ensuring proper distal limb segmentation and preventing transformations of metatarsal elements into tarsal-like structures. Complementing this, signaling pathways such as Wnt and guide chondrogenesis and proximodistal axis formation, promoting the differentiation of the alongside adjacent tarsals. By the 8th week, the positions laterally to the navicular and , solidifying its role in the lateral column of the foot skeleton. Congenital anomalies during this embryonic phase can disrupt cuboid formation, leading to rare associations with tarsal coalition, such as calcaneocuboid coalition, which arises from failed segmentation of mesenchymal precursors. Tarsal coalitions occur in approximately 1-2% of the population, with calcaneocuboid coalitions being rare and accounting for less than 3% of cases. These disruptions highlight the precision required in early mesenchymal differentiation for normal hindfoot architecture.

Ossification process

The primary of the cuboid bone emerges within the cartilaginous anlage during the ninth fetal month, marking the onset of for this tarsal bone. This center typically becomes radiographically visible around birth, though it can appear as late as the first 6 months of postnatal life in some individuals. Unlike certain other tarsal bones such as the or talus, which have more established prenatal centers, the cuboid's single primary center initiates a process that rapidly replaces the surrounding with bone tissue, driven by and vascular invasion. Postnatally, the expands swiftly, achieving substantial mineralization of the body by 1 to 2 years of age, with the assuming much of its mature form through continued activity at the articular surfaces. This growth phase is notably influenced by mechanical loading, which intensifies after the onset of independent walking around 1 year of age, promoting adaptive remodeling and density increases without the involvement of secondary centers—a rarity among tarsals that typically ossify from one site only. Secondary centers are uncommon in the , distinguishing it from long bones or even some neighboring tarsals that may exhibit foci. Maturation proceeds without distinct epiphyses, as the cuboid functions as a with integrated growth zones, culminating in complete and fusion by the late teens. Average adult dimensions are attained by 15 to 18 years, aligning with overall skeletal maturity. Variations in timing include delays in premature infants, where overall skeletal maturation lags, potentially postponing the primary center's and expansion.

Function

Biomechanical role

The cuboid bone plays a crucial role in maintaining the structural integrity of the foot's lateral column, preventing collapse under loads through its position and articulations. As the primary in the lateral tarsal row, it supports the length of the lateral column, with its height directly correlating to the overall integrity of the foot's arches; disruptions in alignment can lead to shortening of this column, compromising stability. This keystone function ensures the foot remains rigid and stable during static loading, distributing compressive forces across the midfoot without excessive deformation. The cuboid contributes to arch support by forming key components of both the lateral longitudinal arch and the transverse tarsal arch, facilitated by its articulations with the calcaneus, navicular, and lateral cuneiform, as well as supporting ligaments such as the calcaneocuboid and bifurcate ligaments. The saddle-shaped calcaneocuboid joint allows for controlled motion that aids in shock absorption, dissipating vertical forces transmitted from the heel to the forefoot while minimizing peak pressures. Finite element models of foot loading demonstrate that peak stresses occur at the calcaneocuboid interface, where the cuboid bears a significant portion of the lateral foot's load, helping to balance forces across the midfoot. The plantar tuberosity further anchors ligaments under tension, enhancing this dissipative capacity during weight-bearing. Additionally, the serves a pulley function via its plantar sulcus, which redirects the peroneus longus to facilitate eversion and plantarflexion of the first ray, thereby supporting medial arch elevation indirectly through lateral column mechanics. Anatomical variations, such as shortening of the lateral column observed in flatfoot deformities, reduce its length and lead to diminished stability, increasing vulnerability to overload at the midfoot joints.

Role in gait and movement

The cuboid bone plays a critical role in the phase of by facilitating push-off through the cubometatarsal joints, which connect it to the fourth and fifth metatarsals. These joints allow for controlled plantarflexion and flexion of the lateral forefoot, enabling efficient energy transfer from the hindfoot to the toes during toe-off. This mechanism contributes to the foot's function as a rigid , optimizing forward while minimizing energy loss. During mid-stance, the cuboid contributes to stability by participating in the locking of the , which includes the calcaneocuboid articulation. As the inverts, the axes of the calcaneocuboid and talonavicular joints converge, reducing midfoot mobility and creating a rigid platform for weight transfer across the foot. This locking enhances the lever arm's efficiency, supporting body weight progression without excessive deformation. In movements involving eversion and inversion, the facilitates the action of the peroneus longus muscle, whose grooves along its plantar surface to produce eversion of the foot at the . This eversion helps maintain foot alignment during dynamic activities and resists excessive inversion forces, thereby reducing the risk of lateral ankle sprains by countering varus stresses. In running and other high-impact activities, the cuboid experiences increased loading compared to walking, particularly in athletes engaging in repetitive forefoot propulsion. This elevated stress heightens the risk of cuboid fractures, with notable incidence in sports like that involve jumping and rapid directional changes. Pathological conditions affecting the cuboid, such as subluxation or syndrome, lead to alterations in gait patterns, including an antalgic limp that shortens the stance phase on the affected side and disrupts overall gait symmetry. These changes compensate for pain during weight-bearing and push-off, potentially leading to compensatory overuse in contralateral structures.

Clinical significance

Common injuries and disorders

Cuboid syndrome involves subluxation of the cuboid bone at the calcaneocuboid joint, commonly resulting from inversion ankle sprains during activities like running or jumping. Symptoms typically include lateral midfoot pain that worsens with weight-bearing, difficulty with push-off during gait, and occasional swelling or tenderness over the plantar aspect of the cuboid. This condition accounts for approximately 4% of all foot injuries and up to 7% of cases following plantar flexion-inversion ankle sprains, with higher rates observed in athletes. Isolated fractures of the bone are rare, comprising about 2.7% of foot and ankle fractures, and most often present as stress fractures from repetitive loading or avulsion injuries due to ligamentous pulls. In contrast, cuboid fractures frequently occur in conjunction with other midfoot injuries, particularly calcaneal fractures, and are associated with high-energy such as accidents or falls from height in roughly 70% of cases. These injuries are more prevalent in active populations, with midfoot fractures overall having an annual incidence of approximately 3.6 per 100,000. Cuboid whip, a form of overuse injury in runners, arises from cumulative micro-stresses on the due to repetitive , leading to stress reactions or early fractures. Risk factors include elevated , which increases mechanical load on the foot, and inadequate that fails to provide sufficient cushioning or stability. represents a congenital fusion anomaly affecting the cuboid, with calcaneocuboid coalitions, which are rare and comprise approximately 1% of all tarsal coalitions, having an overall of up to 13% in the population though many are . This fusion restricts subtalar motion, often resulting in a rigid flatfoot and peroneal spasm, with symptoms emerging in due to progressive on adjacent joints. Osteoarthritis of the cuboid bone typically develops as post-traumatic degeneration at its articulations, such as the calcaneocuboid or cubometatarsal joints, following prior injuries like fractures or sprains. rises significantly with age, affecting about 12% of individuals over 50 and increasing to higher rates in those over 75, particularly in weight-bearing joints of the midfoot. Other disorders include peroneus longus tendinopathy, where irritation in the cuboid's peroneal sulcus causes inflammation and pain along the lateral foot due to friction on the tendon. Os peroneum syndrome involves pathology of the sesamoid bone within the peroneus longus tendon adjacent to the cuboid, leading to lateral plantar pain from fracture, degeneration, or impingement. Epidemiologically, cuboid bone injuries are more common in athletes, with 2019 analyses indicating roughly twice the risk in dancers compared to the general population due to repetitive high-impact demands. Recent 2024 anthropometric studies link variations in cuboid morphology, such as groove depth and facet dimensions, to increased susceptibility to these injuries in South Indian populations, highlighting biomechanical vulnerabilities.

Diagnosis and treatment

Diagnosis of cuboid bone-related issues typically begins with a thorough clinical , including of the cuboid tuberosity for tenderness and specific maneuvers such as the midfoot squeeze to elicit pain indicative of . Imaging plays a crucial role; plain X-rays are initial studies for detecting fractures, though their sensitivity is limited to approximately 60% for cuboid fractures due to overlapping structures. Computed (CT) serves as the gold standard for confirming tarsal coalitions involving the cuboid, providing detailed visualization of bony bridges. (MRI) is preferred for evaluating involvement, such as peroneal pathology or fractures, with near 100% sensitivity for the latter. Differential diagnosis must exclude conditions like Lisfranc joint injuries or metatarsal stress fractures, which present with similar lateral midfoot and require careful assessment to avoid misdiagnosis. Treatment for primarily involves conservative measures, including the cuboid whip manipulation to reposition the bone, followed by low-dye taping, , and padding to stabilize the lateral column; 80-90% of cases resolve within 4-6 weeks with these approaches. For non-displaced cuboid fractures, management consists of immobilization in a short cast or for 6-8 weeks, with non-weight-bearing initially to promote . Displaced fractures necessitate surgical via open and internal fixation (ORIF) using screws or plates, as recommended in 2019 orthopedic guidelines, to restore alignment and prevent complications like non-union, which occurs in 5-10% of cases. Tarsal coalitions involving the cuboid are managed conservatively with orthoses and activity modification for asymptomatic or mild cases; symptomatic coalitions require surgical resection of the coalition bar, while degenerative changes may warrant . Surgical considerations for cuboid pathologies include arthroscopic techniques for issues to minimize invasiveness, followed by protocols focused on peroneal muscle strengthening and proprioceptive training to restore function. is generally favorable with early intervention, though persistent pain may necessitate ongoing orthotic support.