The infratemporal fossa is an irregularly shaped, quadrangular cavity in the head and neck, situated deep to the masseter muscle and zygomatic arch, and recognized as one of the most anatomically complex regions due to its dense packing of neurovascular structures.[1][2]It is bounded laterally by the ramus of the mandible (including the coronoid and condylar processes), medially by the lateral pterygoid plate and pharyngeal mucosal space, anteriorly by the posterior border of the maxillary sinus, posteriorly by the mastoid and tympanic parts of the temporal bone, superiorly (roof) by the greater wing of the sphenoid bone, and inferiorly by soft tissues that permit extension of lesions.[1][2]Key contents of the infratemporal fossa include masticatory muscles such as the lateral pterygoid (with superior and inferior heads) and medial pterygoid, as well as the tensor veli palatini and levator veli palatini; nerves comprising the mandibular division of the trigeminal nerve (CN V3) and its branches (including the auriculotemporal, lingual, and inferior alveolar nerves), along with the otic parasympathetic ganglion and chorda tympani; and major vessels like the maxillary artery (with branches such as the middle meningeal, inferior alveolar, deep temporal, masseteric, and buccal arteries) and the pterygoid venous plexus, which drains into the retromandibular vein.[1][2][3]This space communicates with the pterygopalatine fossa and temporal fossa, facilitating the passage of structures involved in mastication, sensation of the lower face, and innervation of the oral cavity.[1][3]Clinically, the infratemporal fossa is notable for its role in the spread of infections from the oral cavity or face via the pterygoid venous plexus to the cavernous sinus, potentially causing life-threatening cavernous sinus thrombosis, and it is a common site for pathologies such as abscesses, tumors (e.g., rhabdomyosarcoma or schwannomas), and surgical approaches to the skull base.[1]
Anatomy
Location and boundaries
The infratemporal fossa is an irregularly shaped cavity located posterior to the maxilla, inferior to the temporal fossa, and medial to the ramus of the mandible on the lateral aspect of the skull base.[4] It extends vertically from the base of the skull to the level of the mandible, forming a space that is not completely enclosed by bone.[5]The superior boundary is defined by the infratemporal surface of the greater wing of the sphenoid bone.[6] The medial boundary consists of the lateral pterygoid plate of the sphenoid bone.[4] Laterally, the fossa is bounded by the ramus of the mandible and the medial aspect of the zygomatic arch.[5] The anterior boundary is formed by the posterior surface of the maxilla.[4]Posteriorly, the boundary includes the tympanic portion of the temporal bone, the mandibular fossa, and the styloid process.[4] The inferior aspect remains open without a bony enclosure, allowing continuity with adjacent spaces such as the submandibular and masticator regions for the passage of soft tissues.[5]
Muscles
The infratemporal fossa primarily houses the lateral pterygoid muscle, the medial pterygoid muscle, and the lower fibers of the temporalis muscle, which collectively contribute to mandibular movements. These muscles are situated deep within the fossa, bounded by bony and fascial structures, and play essential roles in jaw dynamics without the presence of more superficial muscles like the masseter.[1][7]The lateral pterygoid muscle consists of two distinct heads. The superior head originates from the infratemporal surface and inframedial aspect of the greater wing of the sphenoid bone, while the inferior head arises from the lateral surface of the lateral pterygoid plate of the sphenoid. The fibers of the superior head insert into the anterior aspect of the temporomandibular joint capsule and the articular disc, whereas those of the inferior head attach to the pterygoid fovea on the condylar neck of the mandible. This muscle functions primarily to protrude the mandible and facilitate jaw depression during mouth opening.[1][7]The medial pterygoid muscle originates from the medial surface of the lateral pterygoid plate of the sphenoid, the pyramidal process of the palatine bone, and the tuberosity of the maxilla. Its fibers insert onto the medial surface of the mandibular ramus and angle, often blending with a common tendon shared with the masseter muscle. This muscle aids in elevating the mandible and contributes to its protrusion.[1][7]The lower portion of the temporalis muscle, a fan-shaped structure originating broadly from the floor of the temporal fossa and the deep surface of the temporal fascia, passes medial to the zygomatic arch through the infratemporal fossa. These inferior fibers insert onto the apex of the coronoid process and the anterior border of the mandibular ramus. They contribute to elevation of the mandible, with posterior fibers also assisting in retraction.[1][7][8]Notably, the masseter muscle, which elevates the mandible, lies superficially and laterally outside the boundaries of the infratemporal fossa. The muscles within the fossa are innervated by motor branches of the mandibular division of the trigeminal nerve (CN V3).[1][7]
Blood supply
The infratemporal fossa receives its primary arterial supply from the maxillary artery, which is the larger terminal branch of the external carotid artery.[9] Originating posterior to the neck of the mandible, the maxillary artery enters the fossa and is traditionally divided into three parts based on its relation to the lateral pterygoid muscle: the first (mandibular) part lies medial to the muscle, the second (pterygoid) part courses lateral to it, and the third (pterygopalatine) part extends anteriorly into the adjacent pterygopalatine fossa.[9] These first two parts traverse the infratemporal fossa, providing branches to its contents and surrounding structures.[9]Key branches of the maxillary artery within the infratemporal fossa include the middle meningeal artery from the first part, which ascends to enter the cranial cavity through the foramen spinosum to supply the dura mater.[9] The inferior alveolar artery, also from the first part, descends to enter the mandibular foramen, supplying the mandible, teeth, and gums.[9] From the second part arise the deep temporal arteries (anterior and posterior), which supply the temporalis muscle; the pterygoid branches, which vascularize the pterygoid muscles; the masseteric artery, which supplies the masseter muscle; and the buccal artery, which provides blood to the buccinator muscle and buccal mucosa.[9]Venous drainage of the infratemporal fossa occurs primarily through the pterygoid venous plexus, a valveless network of interconnecting veins situated around and within the lateral pterygoid muscle that accompanies the maxillary artery.[9] This plexus collects blood from the infratemporal and pterygopalatine fossae, as well as adjacent regions, and communicates superiorly with the cavernous sinus via emissary veins passing through foramina such as the foramen ovale and foramen Vesalius.[9] Inferiorly, the plexus drains into the maxillary vein, which unites with the superficial temporal vein posterior to the mandible to form the retromandibular vein, ultimately contributing to the external jugular vein.[10]The valveless connections of the pterygoid venous plexus with the cavernous sinus create a potential route for the retrograde spread of infection from facial or infratemporal sources to the intracranial cavernous sinus, which can lead to serious complications such as cavernous sinus thrombosis.[11]
Innervation
The infratemporal fossa is primarily innervated by the mandibular nerve, the third division of the trigeminal nerve (CN V3), which is the largest branch of the trigeminal and serves both sensory and motor functions. It enters the fossa through the foramen ovale, immediately giving off the meningeal branch and the nerve to the medial pterygoid before dividing into anterior and posterior trunks within the space. The anterior trunk provides motor innervation to the muscles of mastication and gives rise to the buccal, masseteric, and deep temporal nerves, while the posterior trunk includes sensory branches such as the auriculotemporal, lingual, and inferior alveolar nerves.[1]Key branches of the mandibular nerve include the meningeal branch, which ascends to supply the dura mater; the buccal nerve, providing sensory innervation to the buccal mucosa and skin over the buccinator muscle; the auriculotemporal nerve, which conveys sensory fibers to the temporomandibular joint, external acoustic meatus, and scalp, while also carrying parasympathetic fibers to the parotid gland; the inferior alveolar nerve, which descends to innervate the mandibular teeth and gums before emerging as the mental nerve for the lower lip and chin; the lingual nerve, supplying general sensation to the anterior two-thirds of the tongue and floor of the mouth; and the nerve to the medial pterygoid, which motors the medial pterygoid muscle and also innervates the tensor veli palatini and tensor tympani muscles.[1][12]The otic ganglion, a parasympathetic relay station, lies inferior to the foramen ovale and medial to the mandibular nerve, receiving presynaptic fibers from the glossopharyngeal nerve (CN IX) via the lesser petrosal nerve and motor root from the nerve to the medial pterygoid; its postsynaptic fibers travel via the auriculotemporal nerve to innervate the parotid gland. Additionally, the chorda tympani, a branch of the facial nerve (CN VII), enters the fossa and joins the lingual nerve, providing special sensory taste fibers to the anterior two-thirds of the tongue and preganglionic parasympathetic fibers that synapse in the submandibular ganglion to stimulate the submandibular and sublingual salivary glands.[1][12]
Communications
The infratemporal fossa communicates superiorly with the middle cranial fossa through the foramen ovale, which transmits the mandibular division of the trigeminal nerve (CN V3), and the foramen spinosum, which allows passage of the middle meningeal artery and vein.[1][13] These foramina in the roof of the fossa provide direct pathways for neurovascular structures between the cranial cavity and the infratemporal space.[14]Anteriorly, the infratemporal fossa connects to the pterygopalatine fossa via the pterygomaxillary fissure, a narrow cleft between the posterior aspect of the maxilla and the pterygoid process of the sphenoid bone.[11][13] This fissure serves as a conduit for branches of the maxillary artery and associated nerves.[1]Medially, the infratemporal fossa communicates with the parapharyngeal space through the region adjacent to the lateral pterygoid plate, where the prestyloid portion of the parapharyngeal space overlaps with the medial aspects of the fossa, including the pterygoid venous plexus.[13]The infratemporal fossa lacks a distinct bony floor and opens inferiorly, allowing communication with the submandibular space and masticator space, particularly through the attachments of the medial pterygoid muscle to the mandible.[13] Laterally, it connects to the temporal fossa via the gap deep to the zygomatic arch, facilitating continuity between the two fossae superior to the mandibular ramus.[14][11]Posteriorly, the infratemporal fossa adjoins the carotid space near the stylomastoid foramen area, bounded by the styloid process and the tympanic portion of the temporal bone, with the carotid sheath forming part of the posterior limit.[11]These interconnecting pathways enable the potential spread of infections or tumors between the infratemporal fossa and adjacent spaces, such as from odontogenic sources to the middle cranial fossa or parapharyngeal space via venous plexuses or fascial planes.[1][13]
Function
Role in mastication
The infratemporal fossa plays a pivotal role in mastication by housing key muscles that coordinate mandibular movements essential for chewing. The medial pterygoid muscle, located within the fossa, synergizes with the temporalis to elevate the jaw and assists in protrusion and lateral excursions, enabling side-to-side grinding motions critical for food breakdown. Meanwhile, the lateral pterygoid muscle, uniquely positioned in the fossa, is the primary depressor of the mandible, allowing jaw opening, and also drives protrusion and contralateral lateral movements when acting unilaterally, thus supporting the full range of masticatory cycles. The temporalis tendon passes through the fossa to insert on the coronoid process, contributing to elevation and retraction of the mandible.[1][15]The lateral pterygoid's insertion into the temporomandibular joint (TMJ) capsule and articular disc integrates the infratemporal fossa directly into TMJ function, stabilizing the joint during dynamic jaw excursions and preventing dislocation during repetitive chewing actions. This attachment allows the muscle to pull the condyle forward and downward, coordinating with the TMJ's synovial mechanics to enable smooth translation and rotation of the mandible.[1][14]Sensory feedback during mastication is provided by branches of the mandibular division of the trigeminal nerve (CN V3) within the infratemporal fossa, particularly the auriculotemporal and masseteric nerves, which convey proprioceptive information from muscle spindles and the TMJ to the mesencephalic nucleus, allowing reflexive adjustments in bite force and jaw position. The auriculotemporal nerve supplies sensory innervation to the TMJ and posterior temporalis, detecting stretch and pressure to modulate muscle activity, while the masseteric nerve, passing through the fossa, carries proprioceptive afferents from the masseter to fine-tune elevation efforts. This neural integration ensures precise coordination and prevents overload during prolonged chewing.[16][17]Vascular support from the maxillary artery and its branches, such as the deep temporal and pterygoid arteries, supplies the infratemporal fossa muscles with oxygenated blood, sustaining endurance during repetitive masticatory contractions by maintaining aerobic metabolism and nutrient delivery. The accompanying pterygoid venous plexus facilitates efficient drainage, preventing fatigue accumulation in the confined space.[1][14]Evolutionarily, the infratemporal fossa represents an adaptation in mammals for efficient grinding, with the repositioning and subdivision of jaw adductor muscles like the pterygoids and temporalis—evident from eucynodont ancestors—enhancing masticatory force and enabling complex food processing through diagonal muscle orientations and dentary attachments finalized in basal mammaliaforms.[18]
Lymphatic and venous drainage functions
The pterygoid venous plexus, situated within the infratemporal fossa between the lateral pterygoid muscle and the skull base, serves as a primary conduit for venous drainage from the facial and pharyngeal regions. It collects blood from tributaries including the deep facial vein, pharyngeal veins, and pterygoid veins, coalescing into the maxillary vein before joining the retromandibular vein.[19] This network of valveless veins enables efficient drainage and helps prevent blood stagnation by accommodating variations in venous pressure during changes in head position, such as tilting or rotation.[19] The extensive anastomoses within the plexus, more pronounced in humans compared to other primates, support this function in the context of upright posture by facilitating multidirectional flow against gravity.[20]A critical aspect of the pterygoid plexus is its direct and indirect connections to the cavernous sinus through emissary veins passing via the foramen ovale, foramen Vesalius, and foramen spinosum. These links allow for potential retrograde flow, which can propagate infections from extracranial sites to the intracranial compartment, as seen in cases of septic cavernous sinus thrombosis originating from facial or pharyngeal infections.[11][1] Such communications highlight the fossa's role in both physiological venous return and pathological spread, necessitating careful consideration in clinical management of head and neck infections.Lymphatic vessels from the infratemporal fossa drain primarily through communications with the adjacent parapharyngeal space, directing flow to the upper deep cervical lymph nodes, including the jugular digastric node.[21] This pathway ensures effective immune surveillance of the masticatory muscles, temporomandibular joint, and surrounding soft tissues by transporting lymph, immune cells, and antigens toward regional nodes for processing.[22] The venous plexus anatomy, including its tributaries and communications, is further detailed in the Blood supply section.
Clinical significance
Associated pathologies
The infratemporal fossa is susceptible to various pathologies due to its proximity to odontogenic structures, neurovascular elements, and communications with adjacent spaces, leading to significant clinical challenges. Infections, tumors, trauma, and temporomandibular disorders are among the primary conditions affecting this region, often presenting with symptoms such as trismus, facial swelling, pain, and neurological deficits.[23]Tumors involving the infratemporal fossa can arise primarily within it or extend from neighboring sites. Squamous cell carcinoma originating in the nasopharynx frequently invades the infratemporal fossa through direct extension, resulting in mass effect on surrounding muscles and nerves.[23] Schwannomas of the mandibular division of the trigeminal nerve (CN V3) are rare benign neoplasms that may present as slowly growing masses causing facial asymmetry and sensory disturbances.[24] Primary tumors such as lipomas are exceptionally uncommon but have been documented, typically manifesting as painless, expansile lesions that displace adjacent structures like the temporalis muscle.[25]Infections in the infratemporal fossa predominantly stem from odontogenic sources and can spread via communications with the pterygopalatine and masticator spaces. Abscesses often originate from mandibular molar infections, leading to severe trismus, fever, and potential airway compromise if untreated; additionally, infections can spread to the cavernous sinus through the pterygoid venous plexus, potentially causing cavernous sinus thrombosis.[26][1]Ludwig's angina, a rapidly progressive cellulitis of the submandibular space, may extend to the infratemporal fossa, exacerbating swelling and risking vascular thrombosis.[27]Traumatic injuries to the infratemporal fossa typically involve fractures that disrupt its contents. Mandibular ramus fractures can displace condylar segments into the fossa, compressing neurovascular structures and causing hematoma formation or nerve injury.[28]Zygomatic arch fractures, while primarily affecting the lateral boundary, may indirectly compromise fossa contents through associated soft tissuetrauma and altered biomechanics.[29]Temporomandibular disorders (TMD) frequently implicate the infratemporal fossa through involvement of its muscular components. Myofascial pain syndrome arising from lateral pterygoid muscle strain is a common manifestation, characterized by localized tenderness, limited jaw opening, and referred pain to the temporomandibular joint, often triggered by parafunctional habits like bruxism.[30]
Surgical relevance
Surgical access to the infratemporal fossa (ITF) is challenging due to its deep location and proximity to critical neurovascular structures, necessitating specialized approaches for tumor resection. The transzygomatic approach, often combined with midfacial degloving, provides wide exposure by sectioning the zygomatic arch and displacing the temporalis muscle, enabling complete resection with minimal facial scarring and short postoperative healing.[31] The preauricular approach, utilizing a coronal incision and orbitozygomatic osteotomy, facilitates anterior transposition of the facial nerve and access to the ITF for both benign and malignant lesions, achieving complete tumor removal in the majority of cases.[32] Endoscopic approaches via the pterygomaxillary fissure, such as the paramaxillary transoral technique, offer minimally invasive access through a sublabial incision, providing direct visualization and gross total resection without external scars, particularly suited for medial or inferior ITF tumors.[33]Key procedures include pterygoidectomy for advanced ITF malignancies, which involves drilling the lateral pterygoid plate and transecting the lateral pterygoid muscle to achieve compartmental clearance and tumor extirpation.[5] Post-resection reconstruction commonly employs microvascular free flaps, such as the anterolateral thigh flap, to restore bulk and function in the defect, reducing complications like fistula formation.[34]Surgical considerations encompass significant risks, including injury to the mandibular branch of the trigeminal nerve (CN V3) during middle fossa drilling or dissection near the pterygoid venous plexus, potentially causing permanent numbness in the lower face and mouth.[5] Vascular injury to the maxillary artery or pterygoid plexus can lead to severe intraoperative hemorrhage, requiring preoperative embolization in select cases to mitigate bleeding.[5]Historically, ITF surgery evolved from open craniotomy techniques in the pre-1960s, pioneered by Conley and Barbosa, to Fisch's posterolateral preauricular approach in 1977, which improved access while preserving the facial nerve; post-2000 advancements shifted toward minimally invasive endoscopic methods, enhancing outcomes for select lesions.[5]Anatomical landmarks, such as the greater wing of the sphenoid bone forming the ITF roof, are essential for surgical orientation, guiding dissection around foramina rotundum and ovale to avoid neurovascular damage.[5]
Diagnostic imaging
Computed tomography (CT) is the preferred initial imaging modality for evaluating the infratemporal fossa due to its superior depiction of bony structures, including the lateral pterygoid plates, mandibular ramus, and temporal bone, which form the fossa's boundaries.[23] Contrast-enhanced CT (CECT) further enhances visualization of calcified vessels and soft tissue interfaces, while multiplanar reconstructions, including coronal and sagittal views, allow assessment of communications with adjacent spaces such as the pterygopalatine fossa and middle cranial fossa.[35] Advances in multidetector CT since the 2010s have integrated 3D volume rendering and CT angiography, providing detailed vascular mapping of branches like the maxillary artery and improving spatial orientation of the fossa's complex anatomy.[36][37]Magnetic resonance imaging (MRI) offers superior soft tissue contrast and is essential for delineating muscles, such as the medial and lateral pterygoids, and neurovascular structures within the fossa, including branches referenced in its innervation.[23] Standard sequences include T1-weighted imaging, which shows intermediate signal intensity for most soft tissues, and T2-weighted imaging, which highlights fluid content and edema; post-contrast T1-weighted fat-suppressed sequences further aid in characterizing tissue interfaces and perineural involvement.[35] MRI's multiplanar capability complements CT by better resolving the fossa's deep extensions and relations to surrounding fat planes.[23]Angiography, including conventional digital subtraction angiography and CT/MR angiography, is utilized for detailed evaluation of vascular anatomy, particularly the maxillary artery and its branches, which course through the fossa.[35] It provides high-resolution images of vessel patency, branching patterns, and flow dynamics, serving as a supplementary tool when non-invasive modalities suggest vascular prominence.[23]Ultrasound has limited application in infratemporal fossa imaging owing to acoustic shadowing from overlying bony structures like the zygomatic arch and mandible, restricting it primarily to superficial extensions or accessible vascular assessments.[35] Doppler ultrasound can evaluate arterial flow in the maxillary and middle meningeal arteries via an acoustic window below the zygomatic arch, with visualization rates of approximately 86% for the maxillary artery at a mean depth of 2.4 cm when the mouth is partially opened.[38]