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Foramen

A foramen (plural: foramina) is a natural opening or hole in a bone that permits the passage of structures such as nerves, blood vessels, ligaments, or tendons between adjacent regions of the body.^[1]^[2]^[3] In human anatomy, foramina are essential components of the skeletal system, facilitating communication and connectivity across bony structures while maintaining structural integrity.^[4] They are particularly numerous in the skull, where they enable the transmission of cranial nerves, arteries, veins, and lymphatic vessels from the brain and cranial cavity to the extracranial spaces.^[5] For instance, the skull base contains multiple foramina organized into fossae: the anterior cranial fossa features the cribriform plate with foramina for olfactory nerve fibers (cranial nerve I); the middle cranial fossa includes the optic canal for the optic nerve (cranial nerve II) and the foramen ovale for the mandibular division of the trigeminal nerve (cranial nerve V); and the posterior cranial fossa houses the large foramen magnum, through which the spinal cord and vertebral arteries pass.^[4] Beyond the cranium, foramina occur throughout the axial and appendicular skeletons, such as the intervertebral foramina in the vertebral column, which allow spinal nerve roots to exit the spinal canal and innervate the body's periphery.^[6] These openings are critical for sensory perception, motor function, vascular supply, and overall homeostasis, with their precise locations and sizes varying by bone and species to accommodate evolutionary adaptations.^[7] Pathologies affecting foramina, such as narrowing (stenosis) or abnormal enlargement, can lead to conditions like nerve compression syndromes, underscoring their clinical significance in neurology and orthopedics.^[4]

Definition and Terminology

Definition

A foramen is a natural, rounded or oval opening, or complete perforation, through bone tissue that typically serves as a passageway for structures such as blood vessels, nerves, or ligaments.^[8]^[9] This distinguishes a foramen from related bone markings: a fissure represents a slit-like or narrow cleft in the bone, often elongated and accommodating similar structures; a notch is an incomplete indentation or V-shaped depression typically at the edge of a bone, which may articulate with or stabilize adjacent bones without fully perforating; and a canal is an elongated, tunnel-like passage that extends through the bone, differing from the more discrete, non-extended nature of a foramen.^[8]^[9]^[10] In human anatomy, foramina exhibit a range of sizes and shapes, from small rounded apertures measuring approximately 1-2 mm in diameter, such as those permitting nutrient vessel passage, to larger oval or circular openings exceeding 10 mm, as seen in major skeletal perforations.^[11]^[12]

Etymology and Classification

The term "foramen" originates from Latin forāmen, meaning "hole," "opening," "aperture," or "orifice," derived from the verb forāre ("to bore" or "to pierce"), which traces back to the Proto-Indo-European root bhoro- signifying a hole.^[13]^[14]^[15] This linguistic root entered English in the 1670s as a medical term, reflecting its adoption in anatomical descriptions of natural openings in bone. Historical usage built on earlier Greek concepts of bodily apertures, with the Latin nomenclature formalized during the Renaissance.^[13] Foramina are classified systematically based on several criteria to facilitate anatomical study and clinical application. By location, they are grouped into categories such as cranial (in the skull), spinal (in the vertebral column), or those in other bones like the pelvis or long bones.^[4] By content or function, classifications distinguish neurovascular foramina (transmitting nerves and blood vessels) and nutrient foramina (for blood supply to bone marrow).^[4] Shape-based schemes identify foramina as circular, oval, triangular, or irregular, influencing their biomechanical roles.^[5] Additionally, developmental classifications differentiate those arising from membranous ossification (intramembranous, often in flat bones) versus endochondral ossification (in long bones or the skull base).^[4] The classification of foramina has evolved from rudimentary descriptions in antiquity to structured modern systems. In the 2nd century CE, Galen employed limited Greek terms for skeletal openings, focusing on their observational anatomy without formal taxonomy, as part of his broader humoral physiology.^[16] This approach persisted through the Renaissance, with anatomists like Vesalius introducing ordinal numbering for structures, including apertures, in his 1543 De Humani Corporis Fabrica.^[16] By the 19th century, systematic classifications emerged in comprehensive texts; Henry Gray's Anatomy, Descriptive and Surgical (1858) organized foramina by skeletal region and transmitted contents, establishing a foundational scheme still influential in contemporary anatomy.^[4] Modern refinements, as in Nomina Anatomica (now Terminologia Anatomica), integrate developmental and functional criteria for precision in imaging and surgery.^[16]

Functions and Physiology

General Functions

Foramina are natural openings in bones that primarily facilitate the passage of neurovascular structures, including nerves for sensory and motor transmission, arteries and veins for blood supply to tissues, and ligaments for structural stabilization.^[4] These openings ensure the connectivity of the nervous system with peripheral regions and maintain circulatory integrity throughout the body.^[8] Foramina are often classified by the content they transmit, such as neurovascular types that accommodate multiple tissue elements.^[4] In the intervertebral foramina of the spine, for instance, ligaments like the superior and inferior corporotransverse ligaments divide the space into subcompartments, protecting traversing nerves and vessels while contributing to segmental stability.^[17] A specialized subset, nutrient foramina, provides vascular access to the bone marrow and internal bone tissues, supporting osteogenesis and remodeling processes.^[18] These foramina allow nutrient arteries to enter the medullary cavity, delivering oxygen and essential nutrients to osteoblasts for bone formation and to osteoclasts for resorption during maintenance and repair.^[18] This vascular supply is critical for sustaining bone health and adapting to physiological demands without compromising structural integrity.^[18] Biomechanically, foramina can influence stress distribution in bones, often acting as sites of stress concentration that the bone adapts to through remodeling, and they enhance joint mobility by serving as passageways or nearby attachment points for ligaments.^[8] Ligament attachments through or around foramina further stabilize joints, facilitating controlled motion while protecting enclosed structures.^[17]

Developmental Aspects

The formation of foramina begins during embryonic development through intricate processes involving mesenchymal tissue differentiation. Around weeks 6 to 7 of gestation, mesenchymal cells condense and undergo chondrification to form cartilaginous models of future bones, particularly in endochondral ossification pathways that predominate in the axial and appendicular skeleton.^[19] Ossification centers emerge within these models, where hypertrophic chondrocytes undergo apoptosis, creating voids in the cartilage matrix that are subsequently invaded by blood vessels and osteoprogenitor cells; these voids establish the foundational spaces for foramina, allowing passage for neurovascular structures while bone matrix is deposited around them.^[19] In intramembranous ossification, relevant to flat bones, mesenchymal cells directly differentiate into osteoblasts at multiple ossification centers, leaving persistent openings where vascular or neural elements penetrate the forming bone tissue.^[19] This phase of foramen development typically progresses through weeks 6 to 12, coinciding with the rapid expansion of the skeletal primordia and integration of nutrient supply pathways essential for ongoing growth.^[19] Postnatally, foramina undergo growth and remodeling in response to systemic and local influences, adapting to the increasing demands of body size and function. Hormones such as growth hormone and estrogen play pivotal roles in this process, stimulating osteoblast activity and matrix deposition that progressively enlarge foramina to accommodate expanding neurovascular bundles.^[20] Mechanical loading from weight-bearing and muscle activity further modulates this remodeling by activating mechanosensitive pathways in osteocytes, which signal bone apposition at foramen margins to prevent compression while maintaining structural integrity.^[21] During puberty, these changes accelerate, with foramina notably enlarging due to the surge in sex steroids and heightened mechanical stresses, ensuring alignment with the overall skeletal maturation and supporting functions like nutrient delivery to avascular bone regions.^[22] Developmental variations in foramina arise from genetic and environmental factors that disrupt normal patterning and fusion processes. Such variations can lead to congenital anomalies, including absence or abnormal closure of foramina due to disruptions in ossification or apoptosis, potentially affecting neurovascular pathways. These highlight the interplay between genetic programming and developmental events in shaping foraminal architecture.

Foramina in the Skull

Foramina of the Neurocranium

The neurocranium, or braincase, encloses the brain and contains several critical foramina that serve as passageways for cranial nerves, blood vessels, and other structures connecting the intracranial cavity to extracranial regions. These openings are primarily located in the bones of the occipital, temporal, sphenoid, and ethmoid, contributing to the posterior, middle, and anterior cranial fossae. While most foramina exhibit bilateral symmetry, variations such as duplication or accessory openings occur in a small percentage of individuals, influencing surgical approaches in neurosurgery.^[23] The foramen magnum, the largest foramen in the skull, is situated at the base of the occipital bone in the posterior cranial fossa, forming the primary conduit between the cranial cavity and the vertebral canal. It transmits the medulla oblongata, vertebral arteries, and the spinal root of the accessory nerve (CN XI), with surrounding dura mater providing meningeal continuity to the spinal dura. Anatomically, it lies adjacent to the alar and apical ligaments of the dens and the occipital condyles, with typical dimensions including an anteroposterior diameter of approximately 3.1 cm and a transverse diameter of 2.7 cm.^[24]^[25] Common variations include minor asymmetries or accessory foramina in 5-10% of cases, potentially affecting cerebrospinal fluid dynamics.^[11] The jugular foramen, located at the junction of the occipital and temporal bones in the posterior cranial fossa, is divided into a pars nervosa and pars vascularis by dural septa, facilitating the passage of the glossopharyngeal nerve (CN IX), vagus nerve (CN X), accessory nerve (CN XI), and the internal jugular vein. It is positioned inferior to the sigmoid sinus, which drains into its vascular compartment, and lies near the hypoglossal canal medially and the carotid canal anteriorly. This foramen typically shows right-sided dominance due to a larger jugular bulb, with overall dimensions varying but often asymmetric; accessory partitions or foramina are reported in up to 10% of skulls.^[26]^[11] The optic canal, formed by the lesser wings of the sphenoid bone within the middle cranial fossa, extends from the optic chiasm to the orbit, transmitting the optic nerve (CN II) and ophthalmic artery enveloped by dura mater extensions. It is situated superolateral to the sphenoid sinus and anterior to the cavernous sinus, with average dimensions of 6.25 mm (intracranial width) by 3.70 mm (height), a length of 8-12 mm, and an orbital opening of 4.75 mm by 5.46 mm. Bilateral symmetry is the norm, though duplication occurs in about 2.57% of cases, which may predispose to compressive neuropathies.^[11] Other notable foramina in the neurocranium include the hypoglossal canal in the occipital bone, which conveys the hypoglossal nerve (CN XII) and a meningeal branch of the ascending pharyngeal artery near the dura of the posterior fossa, and the foramen rotundum in the sphenoid, passing the maxillary nerve (CN V2) adjacent to the pterygoid canal. These structures generally align with the broader physiological roles of foramina in permitting neurovascular transit while maintaining dural integrity across cranial fossae.^[23]

Foramina of the Viscerocranium

The viscerocranium, comprising the facial skeleton including the maxilla, mandible, and associated bones, features several foramina that facilitate the passage of neurovascular structures essential for facial sensation and blood supply. These openings primarily transmit branches of the trigeminal nerve (cranial nerve V) and accompanying arteries and veins, supporting innervation to the skin, mucosa, and deeper tissues of the midface and lower face. Unlike the larger foramina of the neurocranium, those in the viscerocranium are generally smaller and more peripherally located, reflecting their role in distributing sensory input from the face rather than central cranial pathways.^[23] A prominent example is the infraorbital foramen, situated on the anterior surface of the maxilla approximately 6 to 7 mm inferior to the infraorbital margin and often aligned with the buccal cusp of the maxillary second premolar. This foramen transmits the infraorbital nerve—a terminal branch of the maxillary division of the trigeminal nerve (V2)—along with the infraorbital artery and vein, providing sensory innervation to the lower eyelid, lateral nose, upper lip, and anterior cheek. It lies in close relation to the maxillary sinus superiorly and the levator labii superioris muscle inferiorly, making it vulnerable during midfacial surgical procedures.^[27]^[28] The mental foramen, located on the anterolateral aspect of the mandibular body, exemplifies foramina in the lower viscerocranium. Positioned typically below the apex of the second premolar or between the first and second premolars, and midway between the alveolar crest and the inferior mandibular border, it allows passage of the mental nerve—a branch of the mandibular division of the trigeminal nerve (V3)—as well as the mental artery and vein. These structures supply sensory innervation to the skin of the chin, lower lip, and buccal mucosa anterior to the first molar, with the nerve often dividing into incisive, buccal, and labial branches beneath the depressor anguli oris muscle. The foramen's proximity to the mandibular canal and anterior digastric muscle underscores its clinical relevance in dental anesthesia and implantology.^[29]^[30] The superior orbital fissure, bridging the viscerocranium and neurocranium at the orbital apex, is formed between the greater and lesser wings of the sphenoid bone and the orbital plate of the maxilla. This elongated, comma-shaped opening transmits multiple critical structures, including the oculomotor nerve (III), trochlear nerve (IV), abducens nerve (VI), the ophthalmic division of the trigeminal nerve (V1) with its frontal, lacrimal, and nasociliary branches, and the superior and inferior ophthalmic veins. These pathways enable motor control of extraocular muscles, proprioception, and venous drainage from the orbit, while the fissure's position relates it to the levator palpebrae superioris muscle and the surrounding orbital fat.^[31]^[32] Anatomical variations in viscerocranial foramina are common and can impact surgical planning. For instance, accessory or supernumerary infraorbital foramina occur in approximately 7.4% of cases, potentially altering nerve distribution patterns. Similarly, supernumerary mental foramina arise in about 1% of individuals due to bifurcation of the mandibular canal. Asymmetry in size and position is also prevalent; asymmetrical mental foramina are observed in over 50% of cases, with one side occasionally larger, as seen in up to 20% of certain populations where the right foramen exceeds the left in dimension. Such variations, including irregular shapes or medial deviations in the superior orbital fissure, highlight the need for preoperative imaging to avoid iatrogenic injury.^[27]^[29]^[33]

Foramina in the Spine

Vertebral Foramen

The vertebral foramen, also known as the spinal foramen, is the central opening within each vertebra that collectively forms the vertebral canal, a continuous bony passageway extending from the atlas (C1) to the sacral hiatus. This canal is formed anteriorly by the vertebral body and posteriorly by the vertebral arch, which includes the pedicles, laminae, and articular processes. In the cervical and lumbar regions, the foramen typically exhibits a triangular shape to accommodate the spinal cord's enlargement, while in the thoracic region, it is more circular. The sacral canal represents the terminal continuation of this structure, tapering inferiorly and housing the lower spinal nerve roots.^[34]^[35] The primary contents of the vertebral canal include the spinal cord, which extends from the foramen magnum to the conus medullaris at approximately the L1-L2 level, where it tapers and gives way to the cauda equina. Surrounding the spinal cord are the meninges—dura mater, arachnoid mater, and pia mater—and cerebrospinal fluid (CSF), which provides cushioning and nourishment. Below the conus medullaris, the canal contains the cauda equina nerve roots, filum terminale, and associated vasculature, with the sacral portion enlarged to accommodate these structures as they descend to their respective foramina. The canal also briefly references nutrient pathways for spinal vasculature, supporting overall spinal health.^[34]^[36] Regional variations in the vertebral foramen's dimensions and configuration adapt to the spinal cord's changing cross-sectional area and functional demands. In the cervical spine, the foramen is the largest, averaging about 17 mm in diameter, reflecting the cervical enlargement for upper limb innervation. The thoracic foramen is narrower, starting at approximately 16 mm at T1 and decreasing to 14-15 mm mid-thorax before widening to 18 mm at T12, suiting the relatively uniform thoracic cord. Lumbar foramina are progressively larger, reaching up to 17.5 mm at L5, to house the lumbar enlargement. In the sacrum, the canal diminishes in size but expands laterally for the cauda equina, ending at the sacral hiatus.^[34]^[35]^[37]

Intervertebral Foramina

The intervertebral foramina are paired lateral openings located between consecutive vertebrae, serving as conduits for spinal nerves and associated vasculature to exit the spinal column. These foramina are formed by the inferior vertebral notch of the superior vertebra and the superior vertebral notch of the inferior vertebra, with the pedicles of adjacent vertebrae forming the primary bony boundaries. Additional anterior limits include the posterolateral aspects of the intervertebral disc and vertebral bodies, while posteriorly, they are delimited by the zygapophyseal joint capsules and ligamentum flavum. The resulting apertures are typically oval in shape, with dimensions varying by spinal region; for instance, in the lumbar spine, the foraminal height measures approximately 20-23 mm and width 8-10 mm.^[38]^[39]^[40] Each intervertebral foramen contains the spinal nerve formed by the union of dorsal (sensory) and ventral (motor) roots, along with the dorsal root ganglion in the distal portion. Accompanying structures include segmental spinal arteries and veins, which supply the nerve roots and contribute to the internal and external vertebral venous plexuses, as well as meningeal branches and elements of the sympathetic trunk. There are 31 pairs of these foramina corresponding to the 31 pairs of spinal nerves, distributed across the cervical (8 pairs), thoracic (12 pairs), lumbar (5 pairs), sacral (5 pairs), and coccygeal (1 pair) regions. The neurovascular contents occupy a significant portion of the foraminal space, typically 20-50% in the lumbar area, emphasizing the foramina's role in protecting peripheral neural elements while contrasting with the central vertebral foramina that enclose the spinal cord.^[41]^[39]^[42] Regional variations in intervertebral foramina reflect the functional demands of innervated structures. In the cervical region, the foramina are oriented at approximately 45 degrees anteriorly from the sagittal plane and are relatively larger in the lower cervical levels (C5-T1) to accommodate precursors of the brachial plexus, which carry extensive motor and sensory fibers to the upper limbs. Thoracic foramina are smaller and more circular, suiting the segmental innervation of the trunk. Lumbar foramina, prone to stenosis due to degenerative changes, exhibit an oblique exit angle for spinal nerves, typically 45-60 degrees posteriorly, with the nerve roots curving anterolaterally around the pedicle base; this angulation increases caudally, reaching more pronounced obliquity at L5-S1. Such variations influence susceptibility to compression, particularly in the lumbar spine where foraminal narrowing can impinge on nerve roots.^[39]^[38]^[42]

Foramina in Other Bones

Foramina in the Pelvis

The pelvis contains several key foramina that facilitate the passage of neurovascular structures between the pelvic cavity and the lower limbs, contributing to weight-bearing support and mobility. These openings are primarily located in the hip bones (ilium, ischium, and pubis) and are modified by surrounding ligaments to protect vital structures while allowing necessary conduits.^[43]^[44] The obturator foramen is a large oval or triangular opening situated anteroinferior to the acetabulum, formed by the convergence of the superior and inferior pubic rami with the inferior ramus of the ischium. It serves as a conduit for the obturator nerve, artery, and vein, which supply the medial thigh and adductor muscles, enabling lower limb stability and movement. The foramen is largely covered by the obturator membrane, a fibrous sheet that attaches to its margins except at the acetabular notch, where it forms the obturator canal for these structures' passage. Sexual dimorphism is evident in its shape, with males typically exhibiting a more oval form and females a triangular one, reflecting broader pelvic adaptations for weight-bearing in males versus obstetric demands in females.^[44]^[45]^[43]^[46] The greater sciatic foramen, located posteriorly in the pelvic wall, is a wide passageway bounded superiorly by the greater sciatic notch of the ilium, inferiorly by the sacrospinous ligament and ischial spine, laterally by the ischium, and medially by the sacrum and coccyx. It transmits major structures including the piriformis muscle, which partially divides it into suprapiriform and infrapiriform portions; the sciatic nerve emerges infrapiriform to innervate the posterior thigh and leg; and additional elements such as the superior and inferior gluteal nerves and vessels, pudendal nerve, and posterior femoral cutaneous nerve. This foramen plays a critical role in supporting lower body propulsion by allowing these neurovascular bundles to connect the sacral plexus to the gluteal region. The sacrotuberous ligament further bounds it posteriorly, enhancing structural integrity.^[47]^[48]^[43]^[49] The lesser sciatic foramen lies inferior to the greater sciatic foramen, providing a smaller conduit between the pelvis and gluteal region, bounded superiorly by the sacrospinous ligament and ischial spine, anteriorly by the lesser sciatic notch and ischial tuberosity, and posteriorly by the sacrotuberous ligament. It primarily accommodates the tendon of the obturator internus muscle, which laterally rotates the thigh, along with the nerve to the obturator internus, the pudendal nerve, and the internal pudendal artery and vein, which supply the perineum. These ligaments stabilize the foramina, preventing excessive widening while permitting tendon and nerve passage essential for pelvic floor and hip function.^[47]^[50]^[43]^[51]

Foramina in the Extremities

Foramina in the extremities primarily consist of nutrient foramina located in the diaphyses of long bones, serving as entry points for nutrient arteries that supply the medullary cavity with blood, facilitating endosteal circulation essential for bone growth and maintenance.^[52] These foramina are typically small, with diameters ranging from less than 1 mm to about 2 mm, and their oblique orientation allows the nutrient artery to penetrate the cortical bone without disrupting structural integrity.^[53] In the appendicular skeleton, they support the vascular network that nourishes osteocytes in the spongy bone and marrow, contributing to the overall metabolic activity of the limbs.^[18] The directionality of nutrient foramina is influenced by bone growth patterns, generally pointing toward the more active epiphyseal plate during development; in the upper limb, foramina in bones like the humerus, radius, and ulna are directed toward the elbow joint^[54], while in the lower limb, those in the femur, tibia, and fibula point away from the knee.^[53] For example, in the humerus, the primary nutrient foramen is often located on the anteromedial surface at approximately 57.6% of the bone's length from the proximal end, with about 93.8% of humeri featuring a single foramen.^[55] Similarly, the femur typically has one to three nutrient foramina on the linea aspera or medial surface, positioned at around 38.9% of its length, enabling entry of the medullary artery to support the bone's role in weight-bearing and mobility.^[52] Other notable foramina in the extremities include the suprascapular foramen, formed by the suprascapular notch on the superior border of the scapula and bridged by the superior transverse scapular ligament, which transmits the suprascapular nerve to innervate the supraspinatus and infraspinatus muscles.^[56] In the ulna, the nutrient foramen is typically located on the anterior surface in the proximal half of the diaphysis and accommodates a branch of the ulnar artery, contributing to the bone's endosteal nutrient distribution.^[57]^[58] These structures highlight the extremities' reliance on precise vascular access for sustaining the dynamic demands of movement, with multiple foramina per bone (e.g., 2-3 in the femur) ensuring redundant pathways for circulation.^[52]

Clinical and Pathological Considerations

Common Pathologies

Foraminal stenosis refers to the narrowing of the neural foramina, most commonly affecting the intervertebral foramina in the spine, which can compress exiting nerve roots and lead to radiculopathy characterized by radiating pain, weakness, and paresthesia in the affected dermatomes or myotomes.^[59] In lumbar spondylosis, degenerative changes such as osteophyte formation and disc herniation contribute to this narrowing, often presenting with unilateral leg pain exacerbated by walking or extension, though bilateral symptoms are rare.^[60]^[61] Cervical variants similarly cause neck pain radiating to the shoulders or arms due to compression of cervical nerve roots.^[62] Etiologically, degenerative processes predominate in older adults through age-related spondylosis, while traumatic causes include vertebral fractures or disc disruptions that alter foraminal dimensions, potentially leading to delayed neurologic deficits.^[63]^[64] Congenital anomalies of foramina encompass agenesis, where a foramen fails to form, or duplication, resulting in extra openings that may alter neurovascular pathways. Agenesis can disrupt normal nerve or vessel passage, as seen in rare cases of absent mental foramina detected on imaging, potentially complicating dental or trigeminal nerve procedures.^[65] Duplication, such as double transverse foramina in cervical vertebrae, occurs with a prevalence ranging from approximately 5% to 25% across studies, and up to 48.9% in specific cohorts; it may predispose to anomalous vertebral artery routing, increasing stroke risk during neck manipulations.^[66] A notable vascular variant is the persistent trigeminal artery, an embryonic remnant traversing the carotid canal or a duplicated pathway, with an incidence of approximately 0.3% on angiography; it can cause trigeminal neuralgia or aneurysms due to altered hemodynamics.^[67]^[68] Infections and tumors directly impact foramina through erosion or obstruction, leading to neurovascular compromise. Osteomyelitis of the skull base, often originating from otitis externa in immunocompromised patients, erodes bony margins of foramina like the jugular foramen, resulting in lower cranial nerve palsies including dysphagia, hoarseness, and shoulder weakness.^[69]^[70] Metastatic tumors, commonly from lung, breast, or prostate primaries, infiltrate and obstruct foramina such as the jugular foramen, manifesting as jugular foramen syndrome with paralysis of cranial nerves IX, X, and XI, presenting with unilateral glossopharyngeal dysfunction, vagal-mediated autonomic issues, and accessory nerve weakness.^[71]^[72] These pathologies highlight the foramina's vulnerability to local spread, emphasizing early recognition to mitigate progressive neuropathies.^[73]

Diagnostic and Surgical Relevance

Computed tomography (CT) scanning provides detailed visualization of bony structures in foramina, enabling precise measurement of foraminal dimensions and assessment of stenosis severity, particularly useful when magnetic resonance imaging (MRI) is contraindicated.^[74] Multiplanar reformatted and three-dimensional CT images enhance evaluation of neuroforaminal spaces, with sensitivity ranging from 70% to 100% for detecting lumbar foraminal stenosis.^[75] MRI excels in depicting soft tissue contents within foramina, such as nerve root compression in lumbar intervertebral foramina, using sagittal T1- and T2-weighted sequences to grade stenosis from mild (perineural fat obliteration without nerve changes) to severe (nerve root collapse).^[76] This grading system demonstrates high interobserver agreement (κ = 0.905–1.0), aiding reproducible diagnosis of foraminal narrowing.^[76] Foraminotomy is a surgical decompression procedure that widens the neural foramen by removing bone or disc material, commonly performed to alleviate nerve compression from herniated discs in the lumbar or cervical spine.^[77] Conducted under general anesthesia via a posterior approach, it typically lasts about two hours and may involve laminotomy or fusion for stability, with 76% of patients reporting leg pain reduction below 25/100 postoperatively in moderate to severe cases.^[77]^[75] Transforaminal epidural steroid injections deliver anti-inflammatory medication directly into the foramen under fluoroscopic guidance, targeting radicular pain from foraminal stenosis or disc herniation, with evidence of significant pain relief at three months.^[78] The technique uses an oblique needle approach to the intervertebral foramen, confirmed by contrast spread, and is recommended for short- to medium-term symptom management (two weeks to 36 months) when combined with conservative therapies.^[78]^[75] In cranial procedures involving foramina, such as those accessing the skull base, vascular injury poses a critical risk due to proximity to major arteries like the carotid, with transient neurological deficits occurring in up to 7% of cases during test occlusions and delayed ischemic complications in 22% of permanent occlusions.^[79] Endoscopic foraminoplasty emerged in the 1990s as a minimally invasive advancement, with Kambin defining the transforaminal safe zone in 1990 and reporting arthroscopic foraminotomy for lateral recess stenosis by 1996.^[80] Current guidelines from the North American Spine Society endorse cross-sectional imaging like MRI for preoperative planning of foraminal decompression and fluoroscopically guided injections for accuracy in treating lumbar foraminal stenosis, emphasizing clinical correlation due to imaging's limited specificity for symptoms.^[75]

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Sternal foramina (SF) represent a developmental defect, appearing as a result of the incomplete fusion of the sternal bars in the midline. During embryonic life ...
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Anatomy, Head and Neck, Skull - StatPearls - NCBI Bookshelf
Other key foramina that may or may not be associated with nerves include the foramen spinosum (middle meningeal artery), carotid canal (internal carotid ...
[26]
Anatomy, Head and Neck: Foramen Magnum - StatPearls - NCBI
The foramen magnum functions as a passage of the central nervous system through the skull connecting the brain with the spinal cord. On either side of the ...
[27]
Morphometric analysis of the foramen magnum: an anatomic study
We found that the mean surface area of the foramen magnum was 558 mm, the mean anteroposterior diameter was 3.1 cm, and the mean horizontal diameter was 2.7 cm.Missing: dimensions | Show results with:dimensions
[28]
Anatomy, Head and Neck: Jugular Foramen - StatPearls - NCBI - NIH
The jugular foramen is a cavity formed by the petrous part of the temporal bone anteriorly and the occipital bone posteriorly.Missing: definition | Show results with:definition
[29]
Morphometric Analysis of the Infraorbital Foramen - PubMed Central
The infraorbital foramen (IOF) is located on the maxillary bone about 1 cm inferior to the infraorbital margin [1]. The infraorbital nerve and vessels are ...
[30]
Anatomy, Head and Neck, Maxilla - StatPearls - NCBI Bookshelf
Jun 23, 2025 · After exiting the cranium via the foramen rotundum, the maxillary nerve enters the pterygopalatine fossa and gives rise to multiple branches.
[31]
Anatomy, Head and Neck, Mental Nerve - StatPearls - NCBI - NIH
May 29, 2023 · The orifice of exit of the mental nerve, mental foramen, is most commonly located halfway between the alveolar crest and the inferior border ...
[32]
Anatomical characteristics and visibility of mental foramen and ... - NIH
The mental foramen (MF) is a small foramen located in the anterolateral region of the mandible through which the mental nerve and vessels emerge.
[33]
EyeRounds.org: Superior Orbital Fissure Syndrome
Jan 26, 2024 · The superior orbital fissure lies between the greater and lesser wings of the sphenoid bone. Multiple structures run through this area, and they ...
[34]
CHAPTER 45: THE ORBIT
The superior orbital fissure lies between the greater and lesser wings of the sphenoid bone. It communicates with the middle cranial fossa and transmits cranial ...
[35]
Mental Foramen Size, Position and Symmetry in a Multi ... - PubMed
Dec 30, 2018 · Asymmetrical mental foramina were seen in 164 subjects (51.3%) while 156 subjects had symmetrical mental foramina (48.7%).
[36]
Anatomy, Back, Vertebral Canal - StatPearls - NCBI - NIH
The vertebral canal comprises the vertebral foramen located in the cervical, thoracic, and lumbar vertebrae. The vertebral or spinal cord typically ends at the ...
[37]
Vertebral foramen: Anatomy and function - Kenhub
In the cervical region the vertebral foramen is large and triangular shaped, in the thoracic region it is circular and smaller, whilst in the lumbar region it ...
[38]
https://www.kenhub.com/en/library/anatomy/intervertebral-foramen
[39]
Lumbar Vertebrae - Physiopedia
The vertebral foramen is triangular in shape and is larger than in the thoracic vertebrae but smaller than in the cervical vertebrae.
[40]
Intervertebral foramen: Anatomy and function - Kenhub
The foramina are smallest in the cervical region and progressively increase in size as they descend through the thoracic and upper lumbar regions.Missing: variations | Show results with:variations
[41]
Radiographic anatomy of the intervertebral cervical and lumbar ...
At the lumbar level, the foramen has an oval shape with a large vertical axis. The L5-S1 foramen is the roundest and the smallest of the lumbar intervertebral ...
[42]
Changes in L4/5 Intervertebral Foramen Bony Morphology with Age
May 16, 2018 · The foraminal height was reported as 11–23 mm and the foraminal width as 8–10 mm. ... demonstrated the dynamic changes of dimensions in the lumbar ...
[43]
Anatomy of the Spinal Cord (Section 2, Chapter 3) Neuroscience ...
The spinal cord extends from the foramen magnum where it is continuous with the medulla to the level of the first or second lumbar vertebrae. It is a vital link ...
[44]
intervertebral foramen anatomy of the lumbar spine: an overview
This article reviews the anatomy of the lumbar intervertebral foramen, emphasizing crucial anatomical variations for the safety and efficacy of the ...
[45]
Bony pelvis: Ilium, ischium, pubis | Kenhub
The obturator foramen serves as the communication between pelvic and thigh regions through which neurovascular structures pass.
[46]
The Hip Bone - Ilium - Ischium - Pubis - TeachMeAnatomy
### Summary of Pelvic Foramina
[47]
https://teachmeanatomy.info/pelvis/areas/sciatic-foramen/
[48]
Oval in males and triangular in females? A quantitative evaluation of ...
Among the numerous pelvic traits presenting sex differences, the obturator foramen is classically described as being oval in males and triangular in females.
[49]
The Greater Sciatic Foramen and Lesser Sciatic ... - TeachMeAnatomy
The greater sciatic foramen provides a passageway for structures to pass from the pelvis into the gluteal region. Borders. The greater sciatic foramen is ...
[50]
https://teachmeanatomy.info/encyclopaedia/o/obturator-internus/
[51]
Sacrotuberous ligament - Kenhub
The fibers of the sacrotuberous ligament transform the sciatic notch of the hip bone into a large sciatic foramen. This foramen is further divided by the ...
[52]
https://pmc.ncbi.nlm.nih.gov/articles/PMC3562873/
[53]
Sacrospinous ligament: Anatomy, attachments and function - Kenhub
Mar 14, 2024 · The sacrospinous ligament is one of the two main accessory ligaments of the sacroiliac joint, along with the sacrotuberous ligament.
[54]
Morphological and topographical anatomy of nutrient foramina in the ...
Knowledge regarding nutrient foramina of bones is useful in surgical procedures such as microvascular bone transfer in order to preserve the circulation.Missing: function | Show results with:function
[55]
Study of diaphyseal nutrient foramina in human long bones - PubMed
Three and four nutrient foramina have also been observed in few femora, clavicles and ulnae. Absence of a foramen has been observed in few humeri and radii.
[56]
Morphological and topographical anatomy of nutrient foramina in ...
Objectives: To study the morphology and topography of nutrient foramina and to determine the foraminal index of the upper limb long bones.
[57]
Anatomy, Thorax, Scapula - StatPearls - NCBI Bookshelf - NIH
The suprascapular nerve runs through this foramen while the suprascapular artery runs just above the ligament.
[58]
Location, number and clinical significance of nutrient foramina in ...
This study provides additional and important information on the location and number of nutrient foramina in the long bones of the upper and lower limbs.
[59]
Lumbar Spinal Stenosis - StatPearls - NCBI Bookshelf
Jan 30, 2024 · Lateral recess and foraminal stenosis present with radiculopathy. Radiating leg pain exacerbated by walking is the most sensitive clinical ...
[60]
Lumbar spondylosis: clinical presentation and treatment approaches
If protruding within the spinal canal or intervertebral foramina, these bony growths may compress nerves with resulting radiculopathy or spinal stenosis.
[61]
Foraminal Stenosis at L5–S1 as an Overlooked Pathology of ...
The classical symptom of foraminal stenosis is unilateral radiculopathy. Bilateral radiculopathy caused purely by foraminal stenosis is rare.
[62]
Cervical Spondylosis - StatPearls - NCBI Bookshelf - NIH
Aug 2, 2025 · In upper and lower cervical spine disease, patients may report radiating pain into the back of the ear or occiput versus radiating pain into the ...
[63]
Lumbar foraminal neuropathy: an update on non-surgical ...
Jul 1, 2019 · Lumbar foraminal neuropathy is a common source of radicular symptoms causing pain, weakness and paresthesia.
[64]
Delayed Neurologic Deficit due to Foraminal Stenosis following ...
In our case, the foraminal stenosis was not related to lowered disc height and may have been caused by collapse of the caudal part of the vertebral body.
[65]
A rare case of an anatomical variant of nonexistent mental foramen
Nov 28, 2024 · This case report documents a rare case of nonexistent mental foramina on the left side of the jaw, which was detected incidentally using cone-beam computed ...Missing: duplication | Show results with:duplication
[66]
Double Transverse Foramina—An Anatomical Basis for Possible ...
Sep 23, 2023 · Cervical vertebrae may exhibit the anomalous presence of a double transverse foramen (DTF) that may impact the anatomy of related structures ...
[67]
Prevalence and Clinical Implications of the Primitive Trigeminal ...
Individually, PTA was present in 0.3% of patients and PTAV in 0.2%. Both arteries most often originated from the C4 internal carotid artery and took a course ...Missing: incidence | Show results with:incidence
[68]
Trigeminal neuralgia caused by a new variant of persistent ... - NIH
This rare anomaly was detected on MRI, supplemented by CT angiography while evaluating for cause trigeminal neuralgia in a 37-year-old woman. The aberrant ...Missing: foramina incidence
[69]
Osteomyelitis of the Craniofacial Skeleton - PMC - PubMed Central
Jugular foramen syndrome is described by the development of multiple lower nerve palsies occurring when skull-based osteomyelitis involves the jugular foramen.
[70]
Skull Base Osteomyelitis: A Comprehensive Imaging Review - PMC
Inferomedial spread of infection to the jugular foramen and carotid space can result in multiple lower cranial neuropathies (cranial nerves IX–XII). ...
[71]
Jugular Foramen Syndrome - StatPearls - NCBI Bookshelf
The jugular foramen syndrome (JFS) (Vernet syndrome) refers to paralysis of the IX, X, and XI cranial nerves traversing the jugular foramen.
[72]
Differential Diagnosis of Jugular Foramen Lesions - PMC - NIH
Osteomyelitis around the JF may be unilateral and caused by otitis externa or a deep fascial abscess, or it may be bilateral and secondary to systemic ...
[73]
Skull base osteomyelitis: factors implicating clinical outcome - PMC
Mar 6, 2019 · Skull base osteomyelitis is a serious disease with a high risk of complications including neuroinfection.
[74]
Spinal Stenosis Imaging - Medscape Reference
Nov 30, 2022 · CT scanning of the spine should be followed by multiplanar reformatted images and 3-dimensional (3D) imaging techniques in selected patients. ...
[75]
None
Below is a merged summary of the diagnostic imaging and surgical treatments for foraminal stenosis in the lumbar spine, consolidating all information from the provided segments into a comprehensive response. To maximize detail and clarity, I will use tables in CSV format where appropriate (e.g., for diagnostic imaging and surgical treatments) and provide a narrative summary for guidelines and useful URLs. This ensures all information is retained while maintaining a dense and organized representation.
[76]
A Practical MRI Grading System for Lumbar Foraminal Stenosis | AJR
Sagittal T1-weighted imaging was the main sequence evaluated with T2-weighted imaging also used as an additional tool to exclude false-positive findings ...
[77]
Foraminotomy: What It Is, Purpose, Procedure & Recovery
A foraminotomy is surgery to widen the opening of your spine for your nerve roots. It treats nerve compression.Overview · What Is A Foraminotomy? · Procedure Details
[78]
Epidural Steroid Injections - StatPearls - NCBI Bookshelf - NIH
Epidural steroid injections have been used for pain relief since 1952. When indicated, they are an invaluable nonsurgical treatment for low back pain.
[79]
Vascular Considerations and Complications in Cranial Base Surgery
Consideration of potential cerebrovascular complications is paramount to successful outcome and implementation of cranial base surgery.Missing: foramina injury
[80]
Evolution of Spinal Endoscopic Surgery - PMC - PubMed Central
Mar 31, 2019 · In 1990, Kambin [13] introduced the anatomical understanding of the transforaminal approach and triangular safe zone where a lesion can be ...