The anterior cranial fossa is the shallowest and most anterior of the three cranial fossae, forming the forward portion of the floor of the cranial cavity and accommodating the inferior aspects of the frontal lobes of the brain.[1][2] It is primarily composed of the frontal bone, ethmoid bone, and parts of the sphenoid bone, extending superiorly over the nasal and orbital cavities.[3][4]The fossa's boundaries are well-defined: anteriorly and laterally by the orbital plates of the frontal bone; posteriorly by the lesser wings of the sphenoid bone and the sphenoidal limbus; and its floor by the orbital portion of the frontal bone centrally, the cribriform plate of the ethmoid bone, and the planum sphenoidale posteriorly.[1][5] Midline structures include the frontal crest and crista galli of the ethmoid bone, which serve as attachments for the falx cerebri, a dural fold dividing the cerebral hemispheres.[3][4]Key contents of the anterior cranial fossa encompass the basal surfaces of the frontal lobes, the olfactory bulbs and tracts, and associated dura mater coverings, with the fossa's convex, grooved floor imprinting gyral patterns from the overlying brain.[1][2] Notable foramina include the cribriform plate, which transmits filaments of the olfactory nerve (cranial nerve I) to the nasal mucosa; the anterior and posterior ethmoidal foramina for the respective ethmoidal arteries, nerves, and veins; and the foramen cecum, which may convey an emissary vein linking the nasal cavity to the superior sagittal sinus.[5][4] These features underscore the fossa's role in olfaction and vascular communication, while its thin bony structure renders it susceptible to fractures that can lead to cerebrospinal fluid leakage or anosmia.[1][3]
Anatomy
Structure
The anterior cranial fossa forms the foremost portion of the cranial base floor, primarily composed of the orbital plates of the frontal bone, the cribriform plate of the ethmoid bone, and the lesser wings of the sphenoid bone. These elements create a shallow, concave depression that accommodates the anterior aspects of the brain, with the frontal bone contributing the largest anterolateral expanse, the ethmoid bone providing the central midline structure, and the sphenoid bone forming the posterior margins.[6][7][3]Key morphological features include the frontal crest, a midline ridge on the frontal bone that projects posteriorly; the crista galli, a midline perpendicular projection arising from the ethmoid bone's cribriform plate; and bilateral olfactory grooves flanking the crista galli on the ethmoid bone, which are shallow longitudinal depressions. Additionally, the fossa's floor exhibits numerous shallow impressions corresponding to the gyri of the cerebral cortex, providing a molded surface for neural support. These features contribute to the fossa's overall irregular contour when viewed superiorly.[6][2][7]The fossa is delineated by several sutures that articulate its contributing bones: the frontoethmoidal suture joining the frontal and ethmoid bones medially, the sphenoethmoidal suture connecting the ethmoid and sphenoid bones posteriorly, and the sphenofrontal suture linking the frontal and sphenoid bones laterally. These sutures traverse the fossa's floor and margins, facilitating the integration of its bony architecture.[6][8][9]In the midline, the anterior cranial fossa aligns directly with the nasal cavity, where the ethmoid bone's structures separate the intracranial space from the nasal vault. Laterally, the orbital plates of the frontal bone and the lesser wings of the sphenoid bone extend to form the roof of the orbital cavities, integrating the fossa with the bony orbits. This configuration supports the overlying frontal brain regions while maintaining structural continuity with adjacent facial skeletal elements.[6][1][10]
Boundaries
The anterior cranial fossa is delimited anteriorly by the posterior margins of the supraorbital ridges and the orbital parts of the frontal bone, which form a rounded elevation separating it from the frontal sinus and orbital roof.[11][12]Posteriorly, it is bounded by the posterior edges of the lesser wings of the sphenoid bone and the anterior aspects of the chiasmatic groove, marking its adjacency to the middle cranial fossa.[5][12]The lateral boundaries consist of the sloping inner surfaces of the lesser wings of the sphenoid bone, which contribute to the posterior lateral extent, while the anterior lateral margins align with the medial orbital walls formed by the frontal bone's orbital plates.[5][11][1]Inferiorly, the fossa approximates the nasal cavity through the cribriform plate of the ethmoid bone, which serves as its floor and allows for limited separation between the intracranial and nasal spaces.[5][12]Along the midline, the medial extent runs from the foramen cecum anteriorly to the ethmoidal spine posteriorly, defining the central axis of the fossa.[5][11]
Contents
The anterior cranial fossa primarily houses the frontal lobes of the cerebrum, which rest upon its bony floor and conform to its contours, with the inferior surface featuring the orbital gyri that overlie the orbital plates of the frontal bone.[5] These gyri are positioned medially and laterally, contributing to the cognitive functions associated with the prefrontal cortex while maintaining close apposition to the fossa's shallow depression.[12] The floor of the fossa bears subtle impressions from the overlying cerebral convolutions, reflecting this intimate relationship between the bony structure and neural tissue.[13]Olfactory-related structures occupy the midline region of the fossa, where the olfactory bulbs are seated directly upon the cribriform plate of the ethmoid bone, receiving sensory filaments from the nasal mucosa through its perforations.[5] The olfactory tracts then extend posteriorly from these bulbs along the inferior surface of the frontal lobes, directing olfactory information toward the temporal and insular cortices while traversing the subarachnoid space above the fossa.[13] This positioning integrates the olfactory pathway with the basal frontal cortex, facilitating the processing of smell in relation to adjacent neural networks.[14]Vascular elements within the fossa include the anterior cerebral arteries, which course along the midline within the longitudinal fissure between the frontal lobes, supplying the medial and superior aspects of these hemispheres. The dural venous sinuses, such as the superior sagittal sinus, run superiorly along the midline attachment of the falx cerebri, draining blood from the cerebral hemispheres and maintaining venous return in proximity to the fossa's roof.[15] These vessels relate spatially to the neural contents, with the arteries embedded in the cisterns and the sinus positioned to avoid direct compression by the expanding frontal lobes.[5]The meningeal layers envelop the contents of the anterior cranial fossa, with the dura mater forming a tough, fibrous lining directly adherent to the bony floor and providing a protective barrier for the underlying braintissue.[5] The falx cerebri, a prominent dural fold, attaches anteriorly to the crista galli—a midline projection of the ethmoid bone—extending posteriorly to separate the left and right frontal lobes while housing the superior sagittal sinus along its superior free edge.[16] This arrangement stabilizes the frontal lobes and compartmentalizes the intracranial space, ensuring efficient cerebrospinal fluid circulation around the olfactory structures and cerebral arteries.[12]
Foramina and Openings
Anterior Ethmoidal Foramen
The anterior ethmoidal foramen is a small opening situated on the medial wall of the orbit, specifically along the frontoethmoidal suture where the frontal and ethmoid bones meet.[17] This foramen serves as a conduit linking the anterior cranial fossa superiorly to the medial orbital wall inferiorly, traversing the orbital plate of the ethmoid bone.[17] It is positioned lateral to the cribriform plate and corresponds to the anterior boundary of the ethmoid bone's orbital component.[17]The primary structures transmitted through the anterior ethmoidal foramen include the anterior ethmoidal neurovascular bundle. The anterior ethmoidal artery, a branch of the ophthalmic artery (itself derived from the internal carotid artery), passes through the foramen to supply the anterior ethmoidal air cells, nasal septum, and lateral nasal wall before emerging as the external nasal artery on the skin of the nose.[17][18] The anterior ethmoidal nerve, originating from the nasociliary nerve (a branch of the ophthalmic division of the trigeminal nerve), traverses the foramen to provide sensory innervation to the anterior ethmoidal sinuses, frontal sinus mucosa, and anterior nasal cavity, ultimately terminating as the external nasal nerve.[17][18] Accompanying these is the anterior ethmoidal vein, which drains blood from the nasal region and orbits into the superior ophthalmic vein.[19]Anatomically, the anterior ethmoidal foramen lies superior to the ethmoidal air cells within the ethmoid labyrinth, facilitating the neurovascular supply to the orbital contents and adjacent nasal structures.[20] It is embedded in the thin bony plate separating the intracranial space from the orbit, often running in close apposition to or within the skull base, which underscores its role in bridging the anterior cranial fossa with the extracranial orbital compartment.[20] This positioning contributes significantly to the vascular and sensory supply of the medial orbit, distinct from its posterior counterpart that handles additional ethmoidal distributions.[17]
Cribriform Plate Foramina
The cribriform plate foramina comprise multiple small perforations within the cribriform plate of the ethmoid bone, creating a sieve-like (Latin: cribrum, meaning sieve) horizontal structure that forms part of the floor of the anterior cranial fossa.[21] These openings typically number approximately 15 to 20 on each side, totaling 30 to 40 foramina, each less than 1 mm in diameter, and vary slightly with age and individual anatomy.[14][22]The foramina primarily transmit the fila olfactoria, which are delicate bundles of unmyelinated axons constituting the olfactory nerve (cranial nerve I); these filaments originate from the olfactory receptor neurons in the nasal mucosa's superior region and extend superiorly to synapse with the olfactory bulbs.[14] This arrangement enables the direct sensory pathway for olfaction, bridging the nasal cavity and intracranial space without interruption by bone.[22]Positioned inferior to the olfactory bulbs and superior to the nasal cavity, the cribriform plate's foramina lie in close relation to the subarachnoid space, with the dura mater covering their intracranial openings to provide a protective barrier.[14] Laterally, the plate is flanked by the ethmoidal labyrinths, which house the ethmoidal air cells.[21]
Development
Embryonic Formation
The anterior cranial fossa develops from the cranial base during early embryogenesis, primarily through the ossification of the frontal, ethmoid, and sphenoid bones. The frontal bone, forming the roof and anterior portions of the fossa, arises via intramembranous ossification from multiple mesenchymal centers that appear around the eighth week of gestation. These centers, initially located near the supraorbital margins, progressively expand and fuse by the end of the embryonic period, contributing to the smooth orbital plates and frontal crest that define the fossa's superior boundaries. In contrast, the ethmoid bone, which forms the central floor including the cribriform plate, originates from endochondral ossification within the cartilaginous nasal capsule. Chondrification of the nasal capsule begins around weeks 6 to 7, with the cartilaginous precursor to the cribriform plate forming around weeks 6-8 and perforations for olfactory nerve fila developing from week 5, while ossification centers emerge in the labyrinths during the fifth lunar month (approximately 20 weeks) and in the perpendicular plate later in gestation, with much of the ossification occurring postnatally.[21][23] The sphenoid bone's lesser wings, forming the posterior boundary, also undergo intramembranous ossification from centers adjacent to the optic canal, integrating with the presphenoid body that develops endochondrally.Key milestones in the formation include the initial appearance of the cribriform plate by week 10, as cartilage encapsulates the olfactory nerve fila, creating perforations for their passage and shaping the sieve-like floor of the fossa, though its ossification is largely postnatal (around 1-3 years). By week 12, the lesser wings of the sphenoid ossify more fully, extending laterally to articulate with the frontal bone and enclose the anterior aspects of the middle cranial fossa. These bony elements integrate through developing sutures, such as the frontoethmoidal suture, which allow for coordinated growth and fusion, ensuring the fossa's cohesive architecture by the end of the first trimester.[24]The expansion of the forebrain, specifically the prosencephalon, plays a critical role in molding the fossa's depth and surface impressions during weeks 4 to 8, as rapid neural growth exerts mechanical forces on the overlying mesenchyme and cartilage, influencing the curvature and accommodation for the frontal lobes. This neurocranial interaction establishes the fossa's shallow, concave profile, adapting to the enlarging cerebral hemispheres while maintaining separation from the nasal cavity.[25][26][9]
Postnatal Changes
Following birth, the anterior cranial fossa expands primarily through appositional bone growth at its sutures, including the frontoethmoidal and sphenofrontal sutures, with length increasing more substantially than width or height due to contributions from the nasal capsule cartilage and presphenoid synchondroses. This expansion is most active in early childhood, largely completing by age 7 years, though some sutural growth and remodeling persist into late adolescence.[27]Concomitant with brain expansion, the endocranial surface of the anterior cranial fossa undergoes remodeling, resulting in the deepening of gyral and dural impressions on the orbital plates of the frontal bone and cribriform plate of the ethmoid, which are minimal in infancy but become more pronounced during adolescence as the brain achieves 90% of its adult volume by age 5 and continues maturing.[28]The cranial base angle, which flexes prenatally from approximately 143° in early gestation (around 10 weeks) to about 126° by birth, experiences further postnatal flexion, particularly in the clivus-sphenoidale angle, reducing significantly from an average of 127° in late fetal life to 114° by 18 months, after which it stabilizes with minimal changes through adulthood; this angle is a key metric in cephalometric analysis for assessing craniofacial posture and growth.[29][30]Age-related pneumatization of the ethmoid sinuses, which are rudimentary at birth, progresses postnatally with increasing aeration of air cells, achieving substantial development by age 12 and final adult configuration after puberty, thereby influencing the depth and contour of the fossa floor. Minor asymmetries may arise in sutural alignment and ethmoidal crest positioning, reflecting normal morphological variation among the three adultfossa types observed in populations.[31][27]
Clinical Significance
Fractures and Trauma
Fractures of the anterior cranial fossa typically result from high-impact blunt trauma to the frontal region, such as motor vehicle accidents, falls from height, or assaults, which transmit force through the cranium and often involve associated midfacial injuries like Le Fort fractures extending superiorly to the skull base.[32][33] These mechanisms are prevalent in up to 24% of severe head injuries, with the thin bony architecture of the fossa—comprising the frontal bone, ethmoid, and sphenoid—predisposing it to disruption under such forces.[34]Common fracture types include linear fractures traversing the orbital plate of the frontal bone or the cribriform plate of the ethmoid, depressed fractures of the orbital roof, and comminuted patterns involving the anterior and posterior walls of the frontal sinus.[32][34] These can be classified as type A (limited to the anterior frontal sinus wall), type B (involving both sinus walls), or type C (frontobasal without sinus extension), with linear and depressed variants accounting for the majority in high-energy impacts.[33] Anterior skull base fractures often coexist with these, branching across multiple bones and potentially displacing fragments inward by more than 3 mm.[34]Immediate anatomical consequences frequently involve dural tears, which occur in a significant proportion of cases and lead to cerebrospinal fluid (CSF) rhinorrhea through cribriform plate disruptions, manifesting as clear nasal discharge in up to 45% of patients and increasing the risk of intracranial infection.[32][34] Orbital roof involvement may result in blow-in fractures, causing enophthalmos due to intraorbital volume expansion and periorbital ecchymosis (raccoon eyes), which typically appears 1-3 days post-injury and signals underlying base disruption.[33][32] These effects underscore the fossa's vulnerability to contiguous injuries affecting the dura, orbits, and nasal cavity.[34]
Pathological Conditions
Congenital anomalies of the anterior cranial fossa often arise from disruptions in cranial suture development or neural crest migration during embryogenesis. Premature fusion of the frontoethmoidal suture, a form of craniosynostosis, restricts transverse growth of the anterior fossa, leading to trigonocephaly characterized by a ridged metopic suture, hypotelorism, and compensatory frontal bossing where the forehead protrudes prominently to accommodate brain expansion.[35][36] This condition is frequently syndromic, as seen in Apert or Crouzon syndromes, where multiple sutures including the frontoethmoidal are involved, resulting in shortened anterior and middle cranial fossae and midfacial hypoplasia.[36]Another congenital abnormality is ethmoidal bonehypoplasia or agenesis, commonly associated with genetic disorders such as Kallmann syndrome or CHARGE syndrome. In Kallmann syndrome, specific ethmoid bone malformations correlate with olfactory bulb aplasia or hypoplasia, disrupting the migration of gonadotropin-releasing hormone neurons and leading to lifelong olfactory deficits including complete anosmia.[37] Similarly, in CHARGE syndrome, ethmoidal deficiencies contribute to midfacial anomalies like choanal atresia and are linked to absent or hypoplastic olfactory bulbs in up to 100% of affected individuals, exacerbating olfactory impairment through structural instability in the anterior cranial base.[38]Acquired pathological conditions in the anterior cranial fossa encompass neoplastic and inflammatory processes that progressively alter its structure and function. Olfactory groove meningiomas, arising from arachnoid cap cells along the cribriform plate, represent about 10% of intracranial meningiomas and often remain asymptomatic until reaching diameters exceeding 4 cm, at which point they compress the olfactory nerves and frontal lobes.[39] These benign tumors can cause extensive perilesional edema and mass effect, potentially leading to splaying of the frontal horns of the lateral ventricles.[39]Frontal sinus mucoceles develop from obstruction of the nasofrontal duct, resulting in mucus accumulation and cystic expansion that erodes the bony floor of the anterior cranial fossa.[40] This erosion may expose the dura, allowing intracranial extension and visible brain pulsations, as observed in cases with significant orbital roof involvement.[40] Metastatic lesions to the frontal bone, comprising roughly 10% of skull base metastases, typically originate from breast, lung, or thyroid primaries and infiltrate the anterior fossa, causing local bony destruction and neurological compromise.[41]Pathologies in the anterior cranial fossa frequently impair olfactory function through direct compression of the olfactory nerve filaments traversing the cribriform plate. Tumors such as meningiomas or esthesioneuroblastomas exert mechanical pressure on these nerves, resulting in progressive hyposmia or anosmia, often as an early but overlooked symptom.[42] Mass lesions also generate pressure on the overlying frontal lobes, particularly the ventromedial prefrontal cortex, disrupting executive functions including value-based decision-making and adaptive behavior.[43] For instance, preoperative deficits in cognitive flexibility and inhibitory control are common in patients with frontal meningiomas, reflecting the region's role in higher-order processing.[43]
Surgical Approaches
The anterior cranial fossa is accessed surgically through a variety of transcranial and endoscopic endonasal techniques, selected based on lesion location, size, and patient factors to minimize morbidity while achieving effective resection or repair. Common transcranial approaches include the bifrontal craniotomy, which involves a bicoronal incision and removal of frontal bone flaps above the orbital rims, providing wide bilateral exposure for midline tumors such as olfactory groove meningiomas.[44] This method is indicated for large tumor resections, allowing gross total removal in up to 80% of cases when combined with microsurgical techniques, though it requires careful management of the superior sagittal sinus to avoid postoperative edema.[45] Alternatively, the supraorbital keyhole approach uses a small eyebrow incision and limited craniotomy to access anterior fossa lesions with minimal brain retraction, ideal for smaller or laterally placed tumors like frontal encephaloceles or biopsies.[44]Endoscopic endonasal approaches, often performed collaboratively by neurosurgeons and otolaryngologists, offer minimally invasive access from below the skull base, particularly for cribriform plate lesions. The transcribriform trajectory involves ethmoidectomy and dural opening through the nasal cavity, indicated for repairing cerebrospinal fluid (CSF) leaks or resecting tumors involving the cribriform plate, such as esthesioneuroblastomas, with success rates exceeding 90% for leak closure when using multilayer reconstruction.[44] Techniques include the nasoseptal flap for dural closure and bone grafts for skull base reinforcement, reducing the need for external incisions and preserving cosmesis.[44] For broader anterior fossa access, the extended endonasal approach may incorporate transplanum transtuberculum elements, suitable for planum sphenoidale meningiomas, though it carries a 10-40% risk of postoperative CSF leakage if reconstruction is inadequate.[45]Anatomical considerations are paramount across all approaches to safeguard neurovascular structures. Preservation of the olfactory nerves is prioritized by gentle retraction and avoiding aggressive dissection near the cribriform plate, though sacrifice may be necessary in up to 50% of olfactory groove meningioma cases to achieve complete resection, potentially leading to anosmia.[45] Management of dural sinuses, such as the superior sagittal sinus, involves ligation or reconstruction in bifrontal procedures to prevent thrombosis, while ethmoidal arteries are coagulated during endonasal access to control bleeding.[44] Orbital roof reconstruction, often using pericranial flaps or titanium mesh in transcranial routes, ensures structural stability and prevents enophthalmos or pulsatile exophthalmos, particularly after osteotomies for extended exposures.[45] These considerations, informed by cadaveric and clinical studies, underscore the shift toward multidisciplinary, tailored strategies that balance radicality with functional preservation.[44]