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Pterygoid plexus
Pterygoid plexus
Pterygoid plexus
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Pterygoid plexus
Veins of the head and neck.
Details
Drains toMaxillary vein
ArteryMaxillary artery
Identifiers
Latinplexus venosus pterygoideus,
plexus pterygoideus
TA98A12.3.05.036
TA24836
FMA50944
Anatomical terminology

The pterygoid plexus (/ˈtɛrɪɡɔɪd/;[1] from Greek pteryx, "wing" and eidos, "shape") is a fine venous plexus upon and within the lateral pterygoid muscle. It drains by a short maxillary vein.[2]

Anatomy

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It is a venous plexus of considerable size, situated between the temporalis muscle and lateral pterygoid muscle, and partly between the two pterygoid muscles.[citation needed]

The plexus features venous valves. The contractions of the lateral pterygoid muscle promote venous drainage.[2]

Tributaries

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The plexus drains all veins that correspond to the branches of the maxillary artery (however, much of the blood delivered by the maxillary artery is returned by other routes), as well as two additional veins.[2]

It receives the following veins:[citation needed]

Anastomoses

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The plexus is connected with the intercranial cavernous sinus by emissary veins passing through the foramen ovale and foramen lacerum.[2]

Relations

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This plexus communicates freely with the anterior facial vein; it also communicates with the cavernous sinus, by branches through the foramen Vesalii, foramen ovale, and foramen lacerum. Due to its communication with the cavernous sinus, infection of the superficial face may spread to the cavernous sinus, causing cavernous sinus thrombosis. Complications may include edema of the eyelids, conjunctivae of the eyes, and subsequent paralysis of cranial nerves which course through the cavernous sinus.[citation needed]

The pterygoid plexus of veins becomes the maxillary vein. The maxillary vein and the superficial temporal vein later join to become the retromandibular vein. The posterior branch of the retromandibular vein and posterior auricular vein then form the external jugular vein, which empties into the subclavian vein.[citation needed]

References

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Pterygoid plexus

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The pterygoid plexus is a valveless network of interconnected veins located in the of the , serving as a primary drainage pathway for blood from the , , nasopharynx, and adjacent structures in the head. Positioned between the medial and lateral pterygoid muscles and in close association with the , the plexus facilitates venous return through a pumping mechanism driven by contractions of the during jaw movement. Key tributaries to the pterygoid plexus include the superior and inferior alveolar veins, sphenopalatine vein, descending palatine vein, infraorbital vein, posterior superior alveolar vein, anterior and posterior deep temporal veins, middle meningeal vein, masseteric vein, buccal vein, and inferior alveolar vein, collectively draining regions such as the , , and oral cavity. The plexus primarily drains posteriorly via the maxillary vein, which joins the to form the retromandibular vein and ultimately contributes to the . It also maintains extensive communications with surrounding venous structures, including the facial vein through the deep facial vein, the inferior ophthalmic vein via the , and the through emissary veins passing via the foramen ovale and foramen Vesalius, as well as connections to the pharyngeal venous plexus. Clinically, the pterygoid plexus's valveless design and direct linkage to the enable bidirectional blood flow but increase the risk of retrograde infection spread from facial or oral sources, potentially resulting in with complications such as cranial nerve palsies (affecting nerves III, IV, V1, V2, and VI) or involvement. Additionally, inadvertent puncture of the plexus during procedures like blocks can lead to formation.

Anatomy

Location and Composition

The pterygoid plexus is defined as a complex network of interconnected veins situated within the of the , primarily surrounding the and the pterygoid portion of the . This venous structure occupies a space bordered anteriorly by the posterior surface of the , posteriorly by the tympanic plate and styloid process, laterally by the ramus of the , medially by the lateral pterygoid plate of the , inferiorly by the attachment of the to the medial ramus surface, and superiorly by the infratemporal surface of the greater wing of the . As such, the plexus typically extends vertically from the to the level of the mandibular ramus, filling much of the infratemporal fossa's depth. In terms of , the pterygoid plexus comprises numerous small, interconnecting veins that form a diffuse, three-dimensional network rather than a unified trunk, paralleling the branches of the within the fossa. It lies partly deep to the lower head of the and between the temporal and pterygoid muscles superiorly, as well as between the medial and lateral pterygoid muscles inferiorly, embedded amid the loose areolar tissue of the region. The overall configuration lacks prominent valves in its primary channels, contributing to its role as a low-pressure collecting system.

Tributaries

The pterygoid plexus, situated within the , receives venous drainage from multiple tributaries that parallel the branches of the , collecting blood from adjacent muscles, dental structures, and soft tissues. These tributaries form a network that ensures efficient drainage from the masticatory apparatus and surrounding areas. The deep temporal veins are prominent tributaries originating from the deep surface of the temporalis muscle, where they accompany the and converge to enter the anterior aspect of the pterygoid plexus. Typically, anterior and posterior deep temporal veins are distinguished, with the posterior pair draining the posterior temporalis and joining near the muscle's insertion. Pterygoid veins arise directly from the venous drainage of the medial and lateral pterygoid muscles, forming small channels that intertwine with the plexus around the lateral pterygoid muscle in the infratemporal fossa. These veins provide essential outflow for the masticatory muscles, with their origins embedded within the muscle bellies. The masseteric vein collects blood from the masseter muscle, traveling alongside the masseteric artery to unite with the pterygoid plexus laterally. This tributary is consistent in its contribution to the venous network supporting jaw elevation. Posterior superior alveolar veins drain the upper molar and teeth and associated gingiva, emerging from the alveolar processes to join the posterior portion of the . These veins accompany the posterior superior alveolar arteries through foramina in the . The inferior alveolar vein originates from the lower teeth and , coursing through the with the inferior alveolar artery and nerve before emptying into the pterygoid medially. It provides drainage for the mandibular and associated structures. Buccal veins drain the buccal mucosa and region, passing superficially through the buccinator muscle to connect with the plexus. These veins often accompany the buccal artery and contribute to the overall venous return. Sphenopalatine vein drains the and joins the plexus. Descending palatine vein (also known as greater palatine vein) drains the palate and region. Infraorbital vein drains the infraorbital region and lower eyelid area. Middle meningeal vein drains the dura mater and enters the plexus, providing a connection between intracranial and extracranial venous systems. Tributary patterns exhibit variability across individuals, including occasional direct communications from other regional veins. Such variations are noted in anatomical dissections but do not alter the primary drainage role of the core tributaries.

Anastomoses and Drainage

The pterygoid venous primarily drains posteriorly through the maxillary , which unites with the to form the retromandibular ; the retromandibular then bifurcates, with its anterior division joining the common facial to drain into the , while its posterior division contributes to the . This pathway integrates the into the broader extracranial venous network, facilitating the return of venous blood from the to the central venous system. Key anastomoses of the pterygoid plexus include connections with the via passing through the foramen ovale, as well as the vein of Vesalius through the foramen of Vesalius when present. It also anastomoses with the facial vein through the deep facial vein, allowing bidirectional exchange between extracranial facial drainage and the pterygoid network. The plexus communicates with the pharyngeal venous plexus, providing a pathway for venous return from pharyngeal structures, and with the ophthalmic veins via the inferior ophthalmic vein through the , which can enable potential retrograde flow under certain conditions. The absence of valves in the pterygoid plexus veins permits this bidirectional flow, directing primary outflow toward the while preventing significant backflow through coordinated muscular compression during jaw movement.

Relations to Surrounding Structures

The pterygoid plexus occupies a central position within the , bordered superiorly by the , medially by the , and laterally by the mandibular ramus. This venous network lies in close proximity to the , positioning superficially to its fibers while intermingling with them, which facilitates interactions during masticatory movements. The plexus also relates to the branches of the (cranial nerve V3), which traverse the fossa after emerging from the foramen ovale, with some venous tributaries paralleling these neural structures. The passes through the in intimate relation to the pterygoid plexus, with the second (pterygoid) portion of the artery embedded within and surrounded by the venous network, allowing for shared pathways with its branches. Additionally, the plexus maintains positional relations to key foramina in the greater wing of the , including the foramen ovale and foramen spinosum; traverse the foramen ovale to connect the plexus to the , while the middle meningeal vein links it via the foramen spinosum, providing potential extracranial-intracranial communications. The pterygoid plexus interacts with the , as the maxillary vein—formed by coalescence of the plexus—courses posteriorly between this ligament and the mandibular neck, influencing the spatial constraints in the medial aspect of the fossa. Furthermore, the plexus is embedded within the loose areolar and adjacent of the , which envelops the surrounding masticatory muscles and neurovascular elements, thereby defining boundaries for surgical approaches to the region.

Function

Mechanism of Venous Drainage

The mechanism of venous drainage in the pterygoid plexus relies on a biomechanical pumping action generated by contractions of the , which surrounds and compresses the plexus to propel blood posteriorly toward the maxillary vein. This muscular compression mimics a peripheral , facilitating the return of deoxygenated blood in the low-pressure venous system. The valveless veins within the plexus allow bidirectional flow, directing blood primarily toward the maxillary vein for eventual drainage into the retromandibular vein. These work in concert with the muscle-induced compression to maintain efficient forward propulsion. Additionally, muscle activity during contractions establishes localized gradients that overcome the inherent low pressure of venous return, compensating for the absence of arterial pulsations. Jaw movements, such as mastication and yawning, drive cyclic compression and decompression of the plexus through repeated contractions of the . During mastication, the coordinated action of masticatory muscles enhances drainage by rhythmically squeezing the venous network. Similarly, yawning involves significant jaw opening mediated by the , promoting plexus expansion and subsequent blood propulsion upon relaxation. The plexus maintains anastomotic connections to the via .

Role in Head and Neck Circulation

The pterygoid plexus integrates into the valveless venous network of the head and neck, serving as a critical conduit that connects extracranial and intracranial circulations through . Specifically, it communicates with the via an emissary vein passing through the foramen ovale, allowing bidirectional flow between the deep facial veins and the without valvular restriction. This arrangement facilitates the exchange of venous blood between superficial and deep compartments, contributing to the overall efficiency of cerebral and facial venous drainage. In scenarios of obstruction in major veins such as the internal jugular, the pterygoid plexus supports collateral drainage pathways, primarily by emptying into the maxillary vein, which joins the retromandibular vein and ultimately the . This collateral route helps maintain venous return from the head and when primary pathways are compromised, preventing potential venous in the intracranial compartment. The plexus's connections thus enhance circulatory resilience in the region. The pterygoid plexus plays a vital role in supporting venous return from deep facial structures, including the , , nasopharynx, and , as well as from surrounding muscles like the pterygoids and indirectly from the via dural sinus linkages. By efficiently channeling this blood toward the heart, it helps prevent in these enclosed spaces, promoting steady circulation and reducing the risk of localized congestion. Muscle contractions, such as those of the lateral pterygoid, assist this drainage process. Additionally, the pterygoid plexus contributes to adaptive functions in the head and by influencing dynamics through changes in venous volume, which can aid in adjusting pressures during postural changes.

Clinical Significance

Risk of Infection Propagation

The pterygoid plexus poses a significant for the propagation of due to its valveless venous structure, which allows bidirectional flow and facilitates the retrograde spread of pathogens from extracranial sites to intracranial spaces. This plexus communicates with the through passing via the foramen ovale, enabling bacteria or thrombi to disseminate rapidly without valvular barriers impeding progression. Such connections heighten the vulnerability to severe complications like septic when originate in adjacent regions. Odontogenic infections, such as those arising from dental abscesses, commonly exploit the pterygoid plexus as a conduit to the , potentially leading to life-threatening (CST). Pathogens from untreated dental sources can enter the plexus directly through its proximity to the masticatory muscles and oral cavity, traveling via to form infected thrombi in the . This pathway accounts for a notable portion of septic CST cases, with odontogenic origins implicated in up to 10% of severe instances, emphasizing the need for prompt dental intervention to prevent intracranial extension. Infections within the masticator space, often stemming from mandibular or maxillary odontogenic foci, can similarly propagate through the pterygoid plexus to the , bypassing anatomical barriers due to the absence of valves in these venous channels. This spread may result in dural sinus involvement, meningitis, or cerebral abscesses, as the plexus's connections allow direct access to intracranial venous systems. The infratemporal and pterygomandibular subspaces, integral to the masticator region, serve as initial reservoirs where infections accumulate before venous dissemination. Case reports illustrate the perilous potential for septic emboli originating from pterygoid plexus infections, including historical examples tied to odontogenic sources. In one instance, a 65-year-old man developed CST from a buccal space abscess linked to a denture-related laceration, with spreading via the pterygoid plexus, resulting in periorbital and before resolution with drainage and antibiotics. Another case involved a 50-year-old with a maxillary molar abscess that progressed to bilateral CST and a cerebellar , disseminating septic emboli through the valveless plexus and causing ophthalmoplegia and facial palsy, ultimately managed with multidisciplinary . A third report described a 49-year-old man with third molar caries leading to bilateral CST via the plexus from masticator space involvement, complicated by and septicemia. These examples underscore the historical pattern of such emboli causing multifocal intracranial pathology. Contributing factors to this infection risk include the pterygoid plexus's anatomical proximity to the oral cavity, which exposes it to polymicrobial flora from dental procedures or abscesses, and poor , which fosters chronic bacteremia and untreated odontogenic foci conducive to venous invasion. Immunocompromised states or delayed treatment further amplify the likelihood of progression from local to systemic septic events via these routes.

Implications in Surgery and Procedures

The pterygoid plexus poses a significant risk of hemorrhage during (TMJ) surgeries, such as release or condylar procedures, due to its proximity to the deep condylar head and potential for disruption by surgical instruments. In these interventions, injury to the plexus can lead to troublesome, uncontrolled bleeding that is difficult to arrest without advanced hemostatic measures. Similarly, in maxillary osteotomies like Le Fort I procedures, separation of the pterygomaxillary junction often risks damaging the plexus, resulting in profuse venous bleeding from the . This complication occurs in up to 0.2–2.2% of orthognathic cases, potentially requiring transfusion or conversion to open approaches. Precautions are essential in endoscopic sinus surgery to avoid plexus injury, particularly during subperiosteal elevation near the pterygoid process or resection of tumors like (JNA), where venous bleeding can obscure visualization. Surgeons employ meticulous and preoperative to identify venous connections, minimizing inadvertent damage to communicating branches. In dental extractions, especially of maxillary molars involving aggressive tuberosity removal, care must be taken to prevent penetration into the , as this can lacerate the plexus and cause life-threatening hemorrhage. Management of plexus disruption in procedures includes ligation of the maxillary vein to isolate venous outflow and reduce bleeding volume, often performed intraorally or endoscopically for access. Hemostatic agents such as oxidized cellulose () or gelatin sponges (Gelfoam) are applied to venous oozing, while bipolar electrocautery targets focal points without spreading current to adjacent . Packing with vasoconstrictive agents provides temporary control in endoscopic settings. Postoperative monitoring focuses on detecting hematoma formation through serial clinical exams and imaging, as expanding collections in the can compromise airway patency or cause facial swelling. Vigilance for is critical due to the plexus's open connections to intracranial veins like the ; symptoms such as sudden neurological changes warrant immediate CT angiography and hyperbaric therapy if confirmed. Patients are observed in a controlled setting for at least 24–48 hours to identify delayed bleeding or embolic events.

References

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