Fact-checked by Grok 2 weeks ago

Maxilla

The maxilla is a paired, irregularly shaped that forms the central portion of the midface, constituting the and contributing to the structure of the orbits, , and . It consists of a central body and four projecting processes—alveolar, frontal, zygomatic, and —that articulate with multiple cranial bones to support facial architecture and facilitate essential functions. Structurally, the body of the maxilla is pyramidal, with four surfaces: an anterior facial surface featuring the for neurovascular passage, a posterolateral infratemporal surface adjacent to the , a superomedial orbital surface forming the of the , and a medial nasal surface that houses the , the largest paranasal sinus with an adult volume of approximately 15 mL. The extends inferiorly to form the , anchoring the upper teeth via sockets, while the projects medially to form the anterior two-thirds of the in articulation with its counterpart from the opposite maxilla. The extends laterally to join the , reinforcing the cheek's prominence, and the ascends to articulate with the , contributing to the medial orbital rim and . Functionally, the maxilla serves as a critical load-bearing element in the , transmitting masticatory forces from the teeth to the cranium while providing attachment sites for muscles of , mastication, and the levator veli palatini. It also plays a role in and by delineating the boundaries of the oral and nasal cavities, and its aids in air humidification and lightening the skull's weight. Clinically, the maxilla's prominence makes it susceptible to trauma, notably in Le Fort fractures: type I involves horizontal separation of the , type II a pyramidal through the , and type III a craniofacial dysjunction detaching the entire midface. Its proximity to the complicates dental procedures like implants, often requiring augmentation due to , and congenital anomalies such as cleft palate frequently involve maxillary defects, impacting speech and feeding.

Anatomy

Structure

The maxilla is a paired, irregular bone that forms the upper jaw, with the right and left maxillae fusing at the intermaxillary suture along the midline in adults. It exhibits a pyramidal shape, comprising a central body and four main processes that contribute to the midfacial skeleton. The body of the maxilla is the central, pyramidal portion housing the maxillary sinus, also known as the antrum of Highmore, a pyramidal cavity that spans from the premolar region to the third molar area and averages approximately 15 mL in volume in adults. This body features four surfaces: the anterior (or facial) surface, which is convex and marked by the canine fossa—a shallow depression above the canine tooth—and the infraorbital foramen located about 1 cm inferior to the orbital rim; the posterior (or infratemporal) surface, which is concave and forms part of the infratemporal fossa; the medial (or nasal) surface, which contributes to the lateral nasal wall; and the superior (or orbital) surface, which forms the majority of the orbital floor. Extending from the body are the frontal process, a triangular projection that ascends medially to form part of the nasal bridge; the zygomatic process, a short lateral extension that articulates with the zygomatic bone and forms the superolateral border of the maxillary sinus; the alveolar process, a curved, inferior extension bearing the sockets for the upper teeth and terminating posteriorly at the maxillary tuberosity, a bulbous enlargement; and the palatine process, a horizontal plate projecting medially to form about two-thirds of the hard palate, with the greater and lesser palatine foramina located on its posterior border for passage of vessels and nerves. In adults, the maxilla measures approximately 52 mm in complex length (from the anterior nasal spine to the ) and 66 mm in maximum inter-maxillary width, though these dimensions exhibit with males showing greater robusticity and average lengths of 53.8 mm and widths of 67.7 mm, compared to 50.3 mm and 64.0 mm in females. Variations in maxillary structure include extensions of the sinus into the or tuberosity, occasional , and antral septations, which can influence overall robusticity.

Articulations

The maxilla forms articulations with nine bones, including the superiorly via the frontomaxillary suture, the posteriorly through the ethmomaxillary suture, the along the medial orbital wall, the anteriorly on the , the laterally by means of the zygomaticomaxillary suture, the posteriorly at the palatomaxillary suture, the at the spheno-maxillary fissure, the medially within the , and the opposite maxilla medially via the intermaxillary (median ) suture. These articulations are predominantly suture joints, classified as synarthroses or immovable fibrous joints that interlock the irregular bone margins with , ensuring structural integrity of the . Examples include the frontomaxillary suture, which connects the frontal process of the maxilla to the , and the zygomaticomaxillary suture, linking the of the maxilla to the maxillary process of the . The maxilla is also indirectly involved in the (TMJ), a between the and , through its , which anchors the upper teeth that occlude with the mandibular teeth to facilitate movement. Ligamentous supports contribute to the stability of maxillary-related functions, particularly the temporomandibular ligament (lateral ligament of the TMJ), a thickening of the that extends from the articular of the —part of the formed by the of the maxilla—to the neck of the , thereby reinforcing the lateral aspect of the and limiting excessive mandibular protrusion or depression. This ligament indirectly bolsters maxillary stability by securing the masticatory apparatus involving the upper . The suture joints of the maxilla provide essential rigidity to withstand and transmit masticatory forces from the teeth to the cranium during , with the zygomaticomaxillary suture experiencing significant stress under bite loading to maintain . This biomechanical role ensures efficient force distribution without compromising the bone's position relative to adjacent cranial structures.

Vascular and Neural Supply

The arterial supply to the maxilla is derived primarily from the , the larger terminal branch of the , which courses through the before dividing into three parts and giving off key branches that perfuse the maxillary bone and associated structures. Specific branches include the posterior superior alveolar artery, which arises from the third part of the and supplies the , posterior teeth, and adjacent bone; the , a continuation of the that enters the via the and provides blood to the anterior maxilla, including the and floor; and the , originating from the (a branch of the ), which emerges through the to vascularize the and palatal gingiva. These arteries ensure robust to support the bone's role in and function. Venous drainage of the maxilla occurs primarily through the maxillary vein, which accompanies the maxillary artery and collects blood from the pterygoid venous plexus, a network of interconnected veins in the infratemporal fossa that receives tributaries from the maxillary sinus, nasal cavity, and infraorbital region. The pterygoid plexus communicates with the cavernous sinus via emissary veins and drains inferiorly into the maxillary vein, which then merges with the superficial temporal vein to form the retromandibular vein; from there, blood flows into the facial vein and ultimately the internal jugular vein. This pathway facilitates efficient return of deoxygenated blood from the maxillary region. However, the valveless nature of the plexus (valvular incompetence) increases the risk of retrograde spread of infections to the cavernous sinus. Sensory innervation of the maxilla is provided by the maxillary nerve (CN V2), the second division of the trigeminal nerve (CN V), which exits the skull via the foramen rotundum and enters the pterygopalatine fossa to distribute branches throughout the midface. Key branches include the posterior superior alveolar nerves, which arise proximal to the infraorbital fissure and innervate the maxillary molars, premolars, and buccal gingiva; the infraorbital nerve, the terminal continuation of V2 that emerges through the infraorbital foramen to supply the anterior maxilla, including the incisors, canines, upper lip, and cheek; the greater and lesser palatine nerves, which descend through the palatine canal to provide sensation to the hard and soft palate, respectively; and the superior alveolar nerves collectively forming a plexus for the maxillary teeth and periodontium. Motor innervation to the maxilla is indirect, primarily through branches of the mandibular nerve (CN V3) to the medial and lateral pterygoid muscles, which influence mandibular movement relative to the fixed maxilla during mastication. Lymphatic drainage from the maxilla, including the gingiva, sinus mucosa, and palatal tissues, follows pathways to the submandibular lymph nodes (level I) via buccal and inferior collecting trunks, with additional routes to the retropharyngeal nodes for midline and posterior structures. These nodes serve as the primary first-station filters before efferents proceed to deeper cervical chains, aiding in immune surveillance of the upper oral cavity. Understanding these vascular and neural pathways is clinically significant for maxillary procedures, as they guide targeted anesthesia techniques such as maxillary nerve blocks via the greater palatine canal or infraorbital approach, which interrupt sensory transmission from V2 branches to achieve profound hemi-maxillary analgesia for dental extractions or sinus surgeries.

Development

The maxilla originates from the mesenchyme of the first pharyngeal arch during early embryogenesis, with intramembranous ossification initiating around the sixth to seventh week of gestation from two primary centers: one for the body of the maxilla and another for the premaxilla. These centers, located near the developing tooth germs and influenced by neural crest-derived cells, expand and fuse by the eighth week to form a single paired bone, establishing the foundational framework for the upper jaw. During prenatal growth, the maxilla undergoes progressive expansion, particularly in the , which elongates to accommodate emerging tooth buds as dental lamina forms around the seventh week. Concurrently, the begins as a small evagination from the middle at approximately 10 weeks of , gradually pneumatizing the bone and contributing to its lightweight structure by the third . Postnatally, the maxilla experiences rapid growth in childhood through appositional bone deposition at key sutures, such as the fronto-maxillary and zygomatico-maxillary, displacing the bone downward and forward in coordination with cranial base expansion. During , remodeling intensifies with further enlargement of the , which approaches adult volume by ages 12-15, enhancing facial projection and airspace. In adulthood, particularly following edentulism, the undergoes progressive resorption, leading to vertical and horizontal that can reduce ridge height by up to 50% within the first year post-extraction, influenced by pneumatization and lack of functional stimuli. Hormonal factors significantly modulate maxillary advancement during , with stimulating overall sutural growth and bone apposition, while sex steroids—particularly and testosterone—amplify these effects by enhancing insulin-like growth factor-1 expression and accelerating remodeling rates. Developmental anomalies, such as cleft lip and palate, arise from failures in the of the maxillary processes with the medial nasal prominences around the sixth to seventh week, resulting in incomplete separation of the oral and nasal cavities and associated .

Functions

In Mastication and Dentition

The maxillary forms the superior boundary of the oral cavity, housing 16 embedded within the alveolar processes of the maxilla. These teeth are secured in individual alveolar sockets, which are bony depressions lined by a thin layer of compact , providing structural support during . The periodontal ligament, a fibrous , anchors each root to the alveolar socket walls, allowing slight micromovements to absorb occlusal forces while maintaining stability. In mastication, the maxilla plays a critical biomechanical by distributing forces generated during across the . During and , occlusal loads are transmitted from the teeth through the alveolar to the basal maxilla, with the acting as a key posterior to absorb and dissipate , particularly from grinding. The of the maxilla provides for the , enhancing the mechanical efficiency of closure and force application in the posterior region. The maxillary dentition aligns with the to achieve Class I occlusion, characterized by the mesiobuccal cusp of the fitting into the buccal groove of the mandibular first molar, ensuring even force distribution and efficient mastication. This alignment supports an average bite force of 500-700 N in adults, primarily generated at the s, which influences overall occlusal harmony and prevents uneven wear. Functional shifts occur with age, as erupt progressively; for instance, the first permanent molars typically emerge around 6 years, establishing the posterior and guiding subsequent dental alignment. In later life, edentulism leads to progressive resorption of the , compromising maxillary stability and reducing the bone's capacity to support prosthetic restorations or residual .

In Facial Structure and Speech

The maxilla serves as a foundational element of the midface , forming a paired structure that fuses at the midline to support the viscerocranium and overlying soft tissues. Its anterior surface projects forward, contributing to the inferior margin of the and articulating with the via the frontal to establish the central and inferior aspects of the . This projection also provides essential support for the upper , as the maxillary prominences develop into the lateral portions of the lip through with the medial nasal processes during embryogenesis. Laterally, the of the maxilla extends to articulate with the , forming the malar eminence that defines the prominence of the cheeks and enhances the overall width of the face. In terms of aesthetic proportions, the maxilla plays a critical role in achieving facial harmony by influencing the midface profile and balance. Maxillary advancement procedures in reposition the bone anteriorly to correct deficiencies, thereby improving nasolabial angles and lip positioning relative to the E-line, which enhances overall facial esthetics. Such interventions, particularly in maxilla-only or bimaxillary approaches, refine midface proportions and reduce nasal-lip discrepancies, promoting a more balanced and symmetrical appearance without excessive prominence of the . The maxilla contributes to speech mechanics through its formation of the and alveolar ridge, which are vital for articulating specific sounds. The anterior , composed primarily of the maxillary process, and the alveolar ridge provide contact points for the in producing palatolingual such as /s/, /t/, /d/, /n/, and /l/, where elevation and grooving shape airflow for precise . Additionally, the maxilla indirectly supports velopharyngeal closure by anchoring the , which serves as the fixed anterior boundary for the soft palate's elevation during speech; this closure directs airflow orally, preventing hypernasality and ensuring clear production. Developmentally, maxillary growth significantly shapes convexity from infancy through adulthood, with the most pronounced anteroposterior changes occurring during early postnatal periods. Between 0.4 and 5 years, the maxilla exhibits rapid forward and vertical expansion, emphasizing anteroposterior maturation that establishes initial midface and convexity. As growth progresses into childhood and , the maxilla advances more slowly than the , leading to a relative posterior repositioning evidenced by decreases in the angle (up to 2.2° in males) and an overall reduction in profile convexity. By adulthood, minimal further maxillary growth occurs, allowing mandibular dominance to further straighten the profile while changes, such as nasal protrusion, may subtly restore some convexity.

In Respiration and Sinuses

The palatine process of the maxilla forms the anterior two-thirds of the , which constitutes the floor of the , while the posterior third is contributed by the horizontal plate of the . This bony foundation supports the and facilitates the separation between the oral and nasal passages, ensuring efficient airflow during . The medial surface of the maxilla, forming part of the lateral wall of the , includes contributions to the inferior , where the opens to drain tears into the nasal passage. The , the largest paranasal sinus located within the body of the maxilla, plays key roles in by conditioning inspired air through humidification, warming, and , thereby protecting the lower from dry or cold environmental conditions. It also contributes to voice by amplifying sound waves during and provides shock absorption to cushion impacts to the upper teeth and facial structures. In adults, the average volume of the maxillary sinus is approximately 15 mL, expanding from approximately 0.07 mL (70 mm³) at birth through biphasic growth: a rapid phase in (0-3 years) followed by steady enlargement until around age 18, after which it stabilizes or slightly increases with pneumatization. Mucociliary clearance in the maxillary sinus relies on its ciliated pseudostratified columnar epithelium, which propels mucus toward the sinus ostium—a small opening on the medial wall that drains into the middle meatus of the nasal cavity, allowing secretions to enter the nasopharynx for expulsion. This mechanism maintains sinus patency and prevents accumulation of debris or pathogens, with airflow directed through the ethmoidal infundibulum to support overall nasal ventilation. Physiologically, the maxillary sinus is susceptible to pressure imbalances, such as during air travel or , where rapid changes in cause mucosal engorgement or hemorrhage if the is obstructed, leading to in the maxillary region. Its adjacency to the enhances olfaction by modulating airflow toward the in the superior nasal region, improving odorant delivery and sensory perception.

Clinical Significance

Fractures and Trauma

Maxillary fractures, often resulting from high-energy , represent a significant portion of injuries, accounting for 6-25% of all fractures. These injuries are commonly associated with accidents (MVAs), assaults, and falls, with MVAs being the leading cause in up to 50-73% of cases, particularly among males aged 20-30 years who exhibit a 3:1 to 12:1 predominance over females. The maxilla's central position in the midface makes it vulnerable to forces that disrupt its articulations with adjacent bones, leading to immediate functional and aesthetic impairments. The Le Fort classification system categorizes maxillary fractures based on the pattern of midfacial separation from the skull base, originally described through experimental studies on cadavers. Le Fort type I, or horizontal maxillary fracture, involves a transverse break through the lower maxilla, separating the alveolar process and hard palate from the upper face, typically caused by a low-force impact directed upward against the maxillary alveolar rim. Le Fort type II, known as the pyramidal fracture, extends from the nasal bridge through the maxilla and orbital floor to the pterygoid plates, resulting from a midfacial impact that creates a pyramidal detachment. Le Fort type III, or craniofacial dysjunction, represents a complete transverse separation of the midface from the cranium, often involving the zygomatic arches and naso-orbito-ethmoidal complex, and is triggered by high-energy blows to the upper maxilla or nasal bridge. These fractures frequently occur in combination due to the variable nature of trauma. Symptoms of maxillary fractures include facial swelling, ecchymosis (particularly periorbital in types II and III), with an anterior open bite, and midfacial mobility upon . More severe presentations may involve epistaxis, , along the , and () indicating dural violation in types II and III. Diagnosis begins with () protocols to assess airway, , and circulation, followed by a thorough for deformity and neurological deficits. Computed tomography () scanning with fine cuts (≤3 mm) and reconstructions serves as the gold standard for confirming fracture extent, associated injuries, and orbital involvement. Acute management prioritizes airway protection, as midfacial edema or posterior displacement can compromise ventilation, potentially necessitating intubation or tracheostomy. Hemorrhage control and cervical spine stabilization follow per ATLS guidelines. For displaced fractures, initial stabilization involves closed reduction with maxillomandibular wiring (MMF) to restore occlusion, while open reduction and internal fixation using titanium plates and screws provide definitive rigid stabilization, often delayed 3-5 days to allow edema resolution. Undisplaced fractures may be managed conservatively with analgesics, antibiotics, and a soft diet, but surgical intervention is indicated for those threatening vision, airway, or globe position.

Pathologies and Disorders

The maxilla is susceptible to various congenital anomalies, most notably . Cleft lip arises from the failure of fusion between the frontonasal (medial nasal) and maxillary processes during embryonic development between the 4th and 7th weeks of . Cleft palate results from the failure of the palatal shelves derived from the maxillary processes to fuse, typically occurring between the 6th and 12th weeks of . These conditions occur with an incidence of approximately 1 in 1,000 live births globally, though rates vary by ethnicity and region. In cases of cleft lip and palate, —a underdevelopment of the maxillary bone—manifests in 15% to 50% of affected individuals, leading to midfacial retrusion, , and functional impairments in feeding and speech. Infectious pathologies primarily involve maxillary sinusitis, an of the that can be acute or and is triggered by , bacterial, allergic, or fungal agents. Odontogenic origins account for up to 10-40% of maxillary sinusitis cases, often stemming from dental abscesses, apical periodontitis, or periapical infections that extend through the thin bony floor of the , causing symptoms such as pain, , and purulent discharge. forms may persist due to unresolved dental or anatomical predispositions like oroantral fistulas. Neoplastic disorders of the maxilla include odontogenic tumors such as , the second most common odontogenic after , which originates from remnants of dental lamina or and presents as a locally aggressive, radiolucent lesion often in the posterior maxilla. , particularly primary intraosseous variants, represents a rare malignant odontogenic tumor arising from odontogenic , accounting for less than 1% of oral malignancies and exhibiting destructive with potential for regional . Maxillary , though uncommon due to the maxilla's rich vascular supply, occurs rarely as a complication of untreated odontogenic infections or , leading to and sequestration in fewer than 1% of head and neck cases. Degenerative conditions affecting the maxilla encompass osteoporosis-related , where systemic reduction in compromises the trabecular architecture of the maxillary , increasing susceptibility to fractures and failure. , a chronic disorder of accelerated , involves the in approximately 17% of cases, with the maxilla affected more frequently than the at a ratio of 2.3:1, resulting in expanded, cotton-wool-like radiopacities, altered , and potential deformities such as maxillary enlargement. Diagnostic evaluation of maxillary pathologies relies on and histopathological techniques tailored to the suspected . (MRI) excels in assessing involvement, such as in or tumor extension, by differentiating mucosa, secretions, and masses with high contrast resolution. For neoplastic lesions, remains the gold standard for definitive , providing histological confirmation of tumor type and margins through incisional or excisional sampling.

Surgical and Orthodontic Relevance

Orthodontic interventions targeting the maxilla often address transverse deficiencies through appliances such as the rapid maxillary expander (RME), which separates the midpalatal suture to widen the upper arch in growing patients with maxillary constriction. This technique is particularly effective in adolescents with permanent , promoting skeletal while minimizing dental when applied early. For anteroposterior discrepancies, LeFort I enables precise maxillary advancement, typically by 5-8 mm, to correct Class III malocclusions and improve facial harmony. Stability is generally high, with advancements of 1 cm or more showing no increased risk of ischemia or . Surgical approaches to the maxilla include the Caldwell-Luc procedure, a traditional sublabial method providing direct access to the for removal of diseased mucosa or foreign bodies. This technique involves an antrostomy through the , allowing irrigation and drainage, though it has largely been supplanted by less invasive options. Endoscopic sinus surgery (ESS) represents a modern alternative, using nasal endoscopes to widen ostia and restore ventilation in the with minimal external incisions. For patients with cleft palate-related defects, prosthetic obturators seal palatal openings to facilitate speech and mastication, often customized with acrylic bases and clasps for interim or definitive use. Recent advances since 2020 have integrated for patient-specific maxillary implants, enhancing precision in reconstruction after trauma or tumor resection through computer-assisted design and or bioresorbable materials. These custom implants improve fit and reduce operative time in maxillofacial procedures. Minimally invasive fixation of maxillary fractures now employs resorbable plates, such as 1.5-2 mm poly-L/DL-lactic acid systems, which degrade over time without requiring removal and provide adequate stability in pediatric and moderate-displacement cases. Complications in maxillary surgery include neurosensory deficits from infraorbital or alveolar nerve injury, occurring in up to 75% of LeFort I cases temporarily, with most resolving within 1-3 months. Relapse in orthognathic procedures like LeFort I advancement affects 10-20% of patients, often exceeding 2 mm horizontally due to soft tissue tension or skeletal drift. Multidisciplinary care in maxillary interventions coordinates orthodontists, surgeons, prosthodontists, and speech therapists to optimize outcomes, such as integrating obturators with surgical advancements for cleft patients to restore and . This team approach ensures comprehensive , addressing occlusal, aesthetic, and phonetic needs post-procedure.

In Mammals

In mammals, the maxilla consists of paired bones that form the central portion of the upper , featuring prominent alveolar processes that house the roots of teeth in the characteristic diphyodont , where two successive sets of teeth develop over the lifespan. This pattern supports diverse feeding strategies, with the alveolar margins varying in height and contour to accommodate different tooth morphologies. In some , such as , a distinct remains separate from the maxilla, bearing the incisors and contributing to the rostral extension of the . Anatomical variations in the maxilla reflect adaptations to and across mammalian orders. Carnivores exhibit an elongated maxilla that accommodates enlarged canines for seizing and tearing prey. Herbivores, by contrast, possess broad palatine processes of the maxilla that form an expansive , facilitating the lateral grinding motions essential for processing fibrous plant material, as exemplified in equids where the wide palatal shelf supports cheek teeth. In , the maxilla is notably shortened relative to other mammals, reducing the overall rostrum length to align with forward-facing orbits and enhanced ; this trend culminates in hominids, where the maxilla resembles the compact form adapted for varied omnivorous s. Functional adaptations further diversify maxillary . For instance, equids have extensive maxillary sinuses that occupy much of the bone's volume, balancing the demands of a heavy, herbivorous . Representative examples highlight these specializations. feature a prominent —a toothless gap in the maxillary dental between the robust incisors and molars—that enables the cheeks to fold inward, preventing interference during gnawing on hard materials. In cetaceans, the maxillae are disproportionately large relative to body size; odontocetes retain teeth embedded in the for grasping prey, while mysticetes have evolved toothless maxillae that anchor plates for filter-feeding on and . These adaptations underscore the maxilla's role in enabling the ecological diversity of mammals.

In Other Vertebrates

In fish, the maxilla forms a key component of the upper , articulating with the and other cranial elements to enable significant mobility during feeding. This mobility allows the maxilla and to slide forward and protrude, facilitating prey capture by expanding the gape and directing flow over sensory structures. In species like those in the order , the maxilla's ligamentous connections to the palatoquadrate further enhance this protrusible , optimizing feeding in aquatic environments. In amphibians, the maxilla is a distinct, often tooth-bearing that contributes to the upper , remaining separate from adjacent elements like the and nasal throughout development. For instance, in anurans such as , the maxilla supports pedicellate teeth adapted for grasping prey, with its posterior process articulating flexibly with the quadratojugal. Reptiles exhibit a similar configuration, where the maxilla is typically a separate, robust bearing conical or acrodont teeth for piercing and holding ; in squamates like , it integrates into the kinetic apparatus. Crocodilians represent a specialized case among reptiles, with the maxilla housing robust maxillary that extend into the antorbital region, aiding in structural reinforcement and potentially respiratory functions. These sinuses, present in taxa like rhombifer, form part of a complex paranasal system that invades the maxilla anterior to the antorbital sinus. Birds lack a traditional toothed maxilla, instead featuring a reduced maxilla fused with the and bones to form the lightweight upper , or rhamphotheca-covered . The maxillopalatine process contributes to this structure, providing a thin, pneumatic framework that minimizes weight for flight while supporting the beak's keratinous sheath. Unlike mammals, birds possess a single primary paranasal , the infraorbital sinus, located within the maxilla and lacrimal bones, though it differs structurally from mammalian maxillary sinuses and some species exhibit additional pneumatic diverticula for or . Beak adaptations vary phylogenetically and ecologically; raptors like possess a sharply hooked maxilla for tearing flesh, whereas granivores such as finches have a conical, crushing form suited to seed processing. Key differences from mammalian maxillae include the absence of complex dentition in birds and the prevalence of kinetic mechanisms in reptiles like lizards, where the maxilla participates in amphikinesis via loose articulations with the braincase and palate. This streptostylic movement of the quadrate allows independent maxillary excursion, enhancing gape for diverse prey without the rigid fusion seen in mammals.

Evolutionary Aspects

The maxilla originated as one of the dermal bones forming the upper in early gnathostomes, which first appeared approximately 420 million years ago during the Silurian-Devonian transition. These bones evolved from derivatives of the mandibular , a homologous to the gill arches of ancestral jawless vertebrates, enabling the formation of a functional jaw apparatus in stem gnathostomes like placoderms. In these early forms, the maxilla served as a primary dermal element supporting the oral lining and teeth, contributing to the predatory capabilities that defined gnathostome diversification. Key evolutionary transitions in the maxilla occurred within lineages leading to mammals, including the complete loss of the distinct in mammals around 200 million years ago during the . This fusion and reduction streamlined the facial skeleton, enhancing structural efficiency without a separate premaxillary , a shift absent in non- mammals like monotremes. are present in some non-mammalian therapsids and cynodonts, with their further development in early mammals lightening the by pneumatizing the maxillary , reducing overall mass while maintaining rigidity for mastication. These changes reflect adaptations for endothermy and increased metabolic demands in mammalian ancestors. Across clades, the maxilla adapted to diverse ecological pressures, such as dietary shifts in carnivorous dinosaurs where of the maxillary facilitated prey capture and in theropods like abelisaurids. In , the of flight around 150 million years ago drove reductions in maxillary mass through and loss of , resulting in a lightweight, kinetic structure that minimized weight while preserving mobility. These adaptations highlight the maxilla's role in functional trade-offs, from robust for predation to streamlined reduction for aerial locomotion. The genetic underpinnings of maxillary evolution involve Hox genes, which pattern the pharyngeal arches and inhibit jaw formation in anterior regions, establishing the default mandibular identity that the maxilla inherits. Fossil evidence from Australopithecus species, such as A. afarensis dated to about 3.9-2.9 million years ago, reveals a progressive shortening of the maxilla compared to earlier hominins, reflecting reduced facial prognathism and adaptations to terrestrial foraging in early human evolution. Pre-20th-century anatomical views erroneously regarded the human maxilla as solely an "intermaxillary bone," overlooking its broader dermal origins until Goethe's 1784 identification of the premaxilla challenged this distinction between human and animal skulls.

References

  1. [1]
    Anatomy, Head and Neck, Maxilla - StatPearls - NCBI Bookshelf
    Jun 23, 2025 · The maxilla is a paired, pyramidal bone composed of a body and 4 processes: alveolar, frontal, zygomatic, and palatine (see Image. Left Maxilla ...
  2. [2]
    The Maxilla - Landmarks - Articulations - TeachMeAnatomy
    The maxilla is a paired, pyramidal-shaped bone of the midface. It forms the upper jaw, supports the upper teeth, and contributes to the orbits, nasal cavity ...
  3. [3]
    Discriminant function analysis of maxillary bone measurements for ...
    Sexual dimorphism is an important biological factor for sex estimation from skeletal remains in medicolegal identification. This study aimed to determine ...
  4. [4]
    Maxilla | Radiology Reference Article | Radiopaedia.org
    Apr 20, 2017 · The maxillae (or maxillary bones) are a pair of symmetrical bones joined at the midline, which form the middle third of the face.
  5. [5]
    Maxilla: Anatomy, function and clinical notes | Kenhub
    The maxilla, the central bone of the midface, has a body and four processes: palatine, frontal, alveolar and zygomatic. Learn about its anatomy at Kenhub!
  6. [6]
    Maxilla - Anatomy Standard
    Nov 19, 2020 · The maxilla is the most complex viscerocranium bone, joining with all other facial skeleton bones except the mandible.
  7. [7]
    Frontomaxillary suture - e-Anatomy - IMAIOS
    The frontomaxillary suture is a cranial suture between the nasal portion of the frontal bone and the frontal process of the maxilla, laterally to the nasal bone
  8. [8]
    Zygomaticomaxillary suture | Radiology Reference Article
    May 18, 2018 · The zygomaticomaxillary suture is between the zygomatic process of the maxilla and the maxillary process of the zygomatic bone.
  9. [9]
    Anatomy, Head and Neck, Temporomandibular Joint - NCBI - NIH
    The stylomandibular ligament (STML) extends from the styloid process of the temporal bone to the posterior margin of the mandible, including the jaw angle.
  10. [10]
    Structural biomechanics of the craniomaxillofacial skeleton under ...
    The stresses at the zygomatic sutures suggest that two-point fixation of zygomatic complex fractures may be sufficient for fixation under bite force loading.
  11. [11]
    The relationship between skull morphology, masticatory muscle ...
    Our results suggest that the morphology of the maxilla modulates the transmission of forces generated during mastication to the rest of the cranium by deforming ...Missing: sutures rigidity
  12. [12]
    Anatomy, Head and Neck: Internal Maxillary Arteries - StatPearls
    Jun 5, 2023 · The maxillary artery supplies deep structures of the face including the mandible, pterygoid, infratemporal fossa and segments of the pterygopalatine fossa.
  13. [13]
    Neuroanatomy, Pterygoid Plexus - StatPearls - NCBI Bookshelf
    The pterygoid plexus is a complex of veins located in the infratemporal fossa of the skull with comprehensive connections to surrounding veins and anatomical ...Introduction · Structure and Function · Embryology · Surgical Considerations
  14. [14]
    A Case of a Previously Unreported Drainage of the Maxillary Vein
    Feb 21, 2023 · The pterygoid venous plexus drains the nasopharynx, nasal cavity, and paranasal sinuses, and drains from the infraorbital vein anteriorly and ...
  15. [15]
    Anatomy, Head and Neck, Maxillary Nerve - StatPearls - NCBI - NIH
    Jun 5, 2023 · [1] It has three terminal branches, which in descending order are ophthalmic nerve (V1), maxillary nerve (V2), and mandibular nerve (V3). The ...
  16. [16]
    Management of the neck in maxillary sinus carcinomas - PMC - NIH
    Aug 1, 2016 · One drainage pathway runs from the maxillary gingiva to the submandibular nodes (level 1) through the buccal lymphatic vessels or buccinator ...
  17. [17]
    Paranasal Sinus and Nasal Cavity Cancer Treatment (Adult) (PDQ ...
    The major lymphatic drainage route of the maxillary antrum is through the lateral and inferior collecting trunks to the first station submandibular, parotid ...
  18. [18]
    Maxillary nerve block via the greater palatine canal - PubMed Central
    Block of the maxillary nerve through the greater palatine canal is a useful technique providing profound anesthesia in the hemi-maxilla, if practiced properly.
  19. [19]
    Embryology, Bone Ossification - StatPearls - NCBI Bookshelf - NIH
    Bone ossification, or osteogenesis, is the process of bone formation. This process begins between the sixth and seventh weeks of embryonic development.
  20. [20]
    [PDF] A Report of - DigitalCommons@TMC
    May 1, 2020 · cation begins from two ossification centers: one for the premaxilla (incisive bone) and a second for the body of the maxilla. These later ...
  21. [21]
    Development of the skull - Kenhub
    The maxillary process from the first pharyngeal arch contributes to the formation of the maxilla, temporal bone, zygoma (zygomatic bone and arch), the palatine ...Missing: centers | Show results with:centers
  22. [22]
    9. Development of the craniofacial complex | Pocket Dentistry
    Jan 5, 2015 · During the sixth week of development, two lateral palatal shelves develop behind the primary palate from the maxillary processes. A secondary ...Development Of The Palate · Development Of The Jaws · Mandible
  23. [23]
    Understanding the formation of maxillary sinus in Japanese human ...
    Introduction. The maxillary sinus (MS) begins to form at 10 weeks of gestation during the process of primary pneumatisation, with the MS originating in the ...
  24. [24]
    Growth of the maxillary sinus in children and adolescents
    These researchers found that maxillary sinus volume reached nearly adult size between the ages of 12 and 15 years but could continue to enlarge until sometime ...Missing: enlargement | Show results with:enlargement
  25. [25]
    how pneumatization and edentulism contribute to maxillary atrophy
    The aim of this retrospective cohort study was to investigate the role of sinus pneumatization and residual ridge resorption in maxillary bone loss.
  26. [26]
    Effects of estrogen deficiency during puberty on maxillary and ...
    Apr 22, 2021 · Our results suggest that estrogen deficiency during the prepubertal period is associated with alterations in the maxillary and mandibular bone length and ...
  27. [27]
    BGDB Face and Ear - Fetal - UNSW Embryology
    Embryonically formed by the fusion of the frontonasal prominence (FNP) with the two maxillary processes of the first pharyngeal arch. Cleft palate (primary ...
  28. [28]
    Maxillary Dental Arch | Complete Anatomy - Elsevier
    The maxillary dental arch consists of the sixteen superiorly located teeth that are embedded in the alveolar processes of the maxilla.
  29. [29]
    https://teachmeanatomy.info/head/other/child-adult-dentition/
  30. [30]
    Anatomy, Head and Neck, Primary Dentition - StatPearls - NCBI - NIH
    The primary dentition should not be confused with the permanent dentition, composed of 32 teeth with 16 teeth in each arch. Each of the primary molars is ...Missing: housing | Show results with:housing
  31. [31]
    Anatomy, Head and Neck, Mastication Muscles - StatPearls - NCBI
    The arterial supply to the muscles of mastication is via the maxillary artery, a branch of the external carotid artery.
  32. [32]
    Anterior Hyperfunction Syndrome: Literature Review and ... - MDPI
    Aug 18, 2024 · The maxillary tuberosity has been identified as the main site of maxillary growth. ... maxilla, better withstands the impact of mastication. An ...
  33. [33]
    Anatomy, Head and Neck, Zygomatic - StatPearls - NCBI Bookshelf
    The zygomatic bone works with the masticatory muscles to control the mastication process and aesthetic function of the face.[12] The zygomatic bones ...
  34. [34]
    Malocclusion (Misaligned Bite): Types & Treatment - Cleveland Clinic
    Class I malocclusion. Description. Your upper teeth stick out slightly beyond your lower teeth. Your jaw aligns properly.
  35. [35]
    THE INFLUENCE OF GENDER AND BRUXISM ON THE HUMAN ...
    The mean maximum bite force was statistically higher for males (587.2 N) when compared to females (424.9 N) (p<0.05), regardless of the presence of bruxism.
  36. [36]
    Eruption Charts | MouthHealthy - Oral Health Information from the ADA
    By age 21, all 32 of the permanent teeth have usually erupted. Download the following eruption charts: Baby Teeth Eruption Chart (PDF). Permanent Teeth Eruption ...
  37. [37]
    The Impact of Edentulism on Oral and General Health - PMC - NIH
    Edentulism was found to have a significant effect on residual ridge resorption [22], which leads to a reduction in the height of alveolar bone and the size of ...
  38. [38]
    Reconstruction of the Midface and Palate - PMC - NIH
    May 6, 2020 · The maxilla is the keystone of the facial skeleton supporting the overlying soft tissue of the face and contributing heavily to one's appearance ...
  39. [39]
    Facial Bone Anatomy: Overview, Mandible, Maxilla
    Dec 11, 2024 · In adults, the average dimensions reach 2.4 mm high, 2.9 cm to either side from the midline, and 2 cm in the anteroposterior dimension. The ...
  40. [40]
    Comparison of aesthetic outcomes of maxilla-only, mandible-only ...
    Jan 15, 2025 · Maxilla-only surgery improves midface proportions, while mandible-only surgery enhances lower facial balance. Bimaxillary surgery provides the most ...
  41. [41]
    A Contemporary Review of Clinical Factors Involved in Speech ...
    Jul 18, 2023 · The tongue makes contact with the teeth, alveolar ridge, or hard palate in order to form each consonant during speech.
  42. [42]
    Velopharyngeal Insufficiency - StatPearls - NCBI Bookshelf - NIH
    Jan 12, 2023 · This closes the velopharyngeal port and separates the nasal and oral cavities during speech, swallowing, vomiting, blowing, and sucking. During ...
  43. [43]
    Maxillary growth and maturation during infancy and early childhood
    The maxilla undergoes its greatest postnatal growth change during infancy and early childhood, when relative AP growth and maturation are emphasized.
  44. [44]
    Age Changes of Jaws and Soft Tissue Profile - Wiley Online Library
    Nov 20, 2014 · The maxilla tends to be positioned in a forward direction much more slowly than does the mandible, resulting in a decrease in the convexity of ...
  45. [45]
    Anatomy, Head and Neck, Nasal Cavity - StatPearls - NCBI Bookshelf
    The floor of the Nasal Cavity. The floor of the nasal cavity is broader than that of the roof.[1]. Anterior: the palatine process of the maxilla. Posterior ...
  46. [46]
    The maxillary sinus: physiology, development and imaging anatomy
    The nose can turn dry, cold air into moist, warm air in under a second and this process of air conditioning is essential for the function and health of the ...
  47. [47]
    [PDF] Human Maxillary Sinus Development, Pneumatization, Anatomy ...
    Humidify, warm, and filters the inspired air due to the slow air turnover process in the area. 3. Increase the mucosal surface area. 4. Absorption of the shock ...
  48. [48]
    Maxillary Sinus - an overview | ScienceDirect Topics
    The volume can expand from 6 mL at birth up to 15 mL during adulthood, and sinus pneumatization occurs with advancing age. The maxillary sinus is innervated by ...
  49. [49]
    Factors for Maxillary Sinus Volume and Craniofacial Anatomical ...
    Jun 21, 2010 · The average volume of a developed maxillary sinus at maturity varies between 15 and 20 mL, and these dimensions remain relatively stable once ...
  50. [50]
    Development of the maxillary sinus from birth to age 18 ... - PubMed
    The maxillary sinus, present at birth, increases in size until the end of the 18th year. The growth pattern includes changes in vertical, horizontal and antero ...
  51. [51]
    https://emedicine.medscape.com/article/1899145-overview
  52. [52]
    Barosinusitis: Practice Essentials, Pathophysiology, Epidemiology
    These pressure changes most often result from travel through mountainous regions, flying, or diving. Computed tomography (CT) scans are considered the ...
  53. [53]
    Sinus Barotrauma - Divers Alert Network
    Sharp pain beside your nose and below your eyes (upper maxillary region) is often a sign of maxillary sinus barotrauma. With changes in depth the pain might ...
  54. [54]
    A literature review of the maxillary sinus with special emphasis on its ...
    Nov 17, 2023 · Maxillary sinus increases moisture content and temperature of inspired air, helps to regulate pressure inside the nasal cavity, enhances the ...
  55. [55]
    Olfaction | Proceedings of the American Thoracic Society
    May 5, 2010 · Factors that affect human olfaction included structural aspects of the nasal cavity that can modulate airflow and therefore odorant access to ...
  56. [56]
    Maxillary and Le Fort Fractures - Medscape Reference
    Jul 7, 2022 · Le Fort I fractures (horizontal) may result from a force of injury directed low on the maxillary alveolar rim in a downward direction. · Le Fort ...
  57. [57]
    Le Fort Fractures - StatPearls - NCBI Bookshelf
    Dec 11, 2024 · Le Fort fractures are classified patterns of midfacial fractures involving the pterygoid plates of the sphenoid bone.
  58. [58]
    Maxillary Fracture - StatPearls - NCBI Bookshelf
    Maxillary fractures are common in patients sustaining facial trauma and may be caused by road traffic accidents, sports, or assault.Epidemiology · History and Physical · Evaluation · Treatment / Management
  59. [59]
    Maxillary and Le Fort Fractures Treatment & Management
    Jul 7, 2022 · Fixation of unstable fracture segments to stable structures is the objective of definitive surgical treatment of maxillary fractures.
  60. [60]
    Cleft of lip and palate: A review - PMC - PubMed Central
    ... cleft lip and cleft palate can be defined as: Cleft lip: The failure of fusion of the frontonasal and maxillary processes, resulting in a cleft of varying ...
  61. [61]
    Prevalence of Cleft Lip & Cleft Palate | Data & Statistics
    The annual prevalence of infants born with cleft lip with or without or cleft palate is 10 in 10,000. Table 1 provides annual prevalence statistics for ...
  62. [62]
    A retrospective analysis of complications associated with tooth ...
    From 15% to 50% of individuals born with cleft lip and palate (CLP) develop maxillary hypoplasia as a secondary deformity (Liao and Mars, 2005). The reasons ...
  63. [63]
    Odontogenic maxillary sinusitis: A comprehensive review - PMC - NIH
    Maxillary sinusitis (acute or chronic) is defined as a symptomatic inflammation of the maxillary sinus, usually caused by viral, bacterial, allergic or fungal ...
  64. [64]
    Maxilla Sinusitis - an overview | ScienceDirect Topics
    As the maxillary sinus is in close proximity to the maxillary posterior teeth, 10% of maxillary sinusitis cases may result from odontogenic sources, including ...
  65. [65]
    Bacterial odontogenic infections
    Apr 28, 2020 · The most frequent causes of odontogenic maxillary sinusitis are apical periodontitis, marginal periodontitis and oroantral fistulas following ...
  66. [66]
    Odontogenic Tumors of the Jaws - StatPearls - NCBI Bookshelf - NIH
    Jul 10, 2023 · Ameloblastoma is the second most common odontogenic tumor after odontoma. It can originate from any of the following: remnants of the dental ...Missing: osteomyelitis | Show results with:osteomyelitis
  67. [67]
    Primary intraosseous squamous cell carcinoma - A rare odontogenic ...
    Primary intraosseous squamous cell carcinoma (PIOSCC) is a rare epithelial odontogenic malignancy affecting the jaws, especially in elderly population.
  68. [68]
    The Rarity of Maxillary Osteomyelitis: Insights From a Unique Case ...
    May 27, 2024 · Maxillary osteomyelitis is a rare bone infection and is rarer to come across with the advent of advanced antibiotic therapies.
  69. [69]
    Jaw osteoporosis: Challenges to oral health and emerging ...
    The pathogenesis of osteoporosis involves an imbalance between bone formation and resorption during the process of bone remodeling [1].
  70. [70]
    Paget's disease with craniofacial and skeletal bone involvement - NIH
    Involvement of maxilla and mandible has been seen in 17% of cases with slight predilection for maxilla compared to mandible, the ratio being 2.3:1. Most ...
  71. [71]
    MRI of the Paranasal Sinuses - The Radiology Assistant
    Feb 25, 2009 · MRI is extremely helpful in complicated sinonasal disease. MRI can discern secretions and mucosa from masses.
  72. [72]
    Tests for Nasal Cavity and Paranasal Sinus Cancers
    Apr 19, 2021 · This test is very useful in finding cancers of the nasal cavity and paranasal sinuses, measuring the size of the tumor, showing if it is growing into nearby ...
  73. [73]
    Evolution, current status, and future trends of maxillary skeletal ...
    Dec 22, 2023 · Currently, rapid maxillary expansion (RME) has become a widely accepted and established treatment modality for correcting maxillary constriction ...<|separator|>
  74. [74]
    Rapid Maxillary Expansion on the Adolescent Patient
    Jul 14, 2022 · The purpose of this review was to assess how palatal expansion is performed in adolescent patients with permanent dentition. Furthermore, it was ...
  75. [75]
    LeFort I Osteotomy - PMC - PubMed Central - NIH
    LeFort I is used to realign the maxilla with the facial midline, correct the cant, and allow for advancement. Patients suffering from vertical maxillary excess ...
  76. [76]
    Le Fort I advancement osteotomies of 1 cm or more. How safe or ...
    Le Fort I maxillary advancement of 1 cm or more is safe and stable with no evidence of increased ischaemia, aseptic necrosis, or serious complications.
  77. [77]
    Caldwell Luc Surgery: Revisited - PMC - NIH
    Jul 31, 2015 · The logic behind this surgery is to replace the diseased and scarred mucosa from maxillary sinus with new mucosa.
  78. [78]
    Caldwell-Luc operation | Radiology Reference Article
    May 30, 2022 · The Caldwell-Luc operation uses an external approach for surgical treatment of the severely diseased maxillary sinus.
  79. [79]
    Sinus Endoscopic Surgery - StatPearls - NCBI Bookshelf
    12 sept 2022 · Endoscopic sinus surgery targets sinus pathology and is the gold standard for treating chronic rhinosinusitis (CRS).Introduction · Anatomy and Physiology · Indications · Technique or Treatment
  80. [80]
    Palatal obturators in patients after maxillectomy - PMC - NIH
    The obturators are prosthesis used to close palatal defects after maxillectomy, to restore masticatory function and to improve speech.
  81. [81]
    Innovative 3D printing technologies and advanced materials ... - NIH
    Feb 11, 2025 · We highlight how these technologies and materials are employed to fabricate patient-specific implants, surgical guides, prosthetics, and ...
  82. [82]
    Full article: The Impact of 3D Printing on Oral and Maxillofacial Surgery
    This review highlights how 3D printing is used in trauma management, surgery to align the jaw and teeth, restoration of large oral and facial defects, surgical ...
  83. [83]
    Efficacy of bioresorbable plating system in the treatment of pediatric ...
    1.5- and 2-mm resorbable plating system along is a good treatment modality for moderately displaced maxillary fractures in pediatric patients.
  84. [84]
    [The complications of nerve injury after the Le Fort I osteotomy]
    Aug 5, 2025 · The incidence of the temporary nerve impairment was 75% (45 of 60) and the obvious recovery was found after 1 to 3 months after the operation.
  85. [85]
    Prosthodontic Management in Conjunction with Speech Therapy in ...
    Patients with CLP have to be rehabilitated by a multidisciplinary team approach is an established protocol. Yet, it is seen routinely that the prosthodontic ...Missing: orthognathic | Show results with:orthognathic
  86. [86]
    Multidisciplinary Planning in Orthognathic Surgery for Prosthetic ...
    The purpose of this study is to show a complete multidisciplinary approach and the planning involved (pre-, intra-, and post-operative) for a patient with a ...Missing: speech | Show results with:speech
  87. [87]
    Current Perspectives on Tooth Implantation, Attachment, and ...
    Implantation geometry illustrated by 3D portions of maxilla ... As a consequence, a vast majority of currently living mammals are fully or incompletely diphyodont ...
  88. [88]
    On the Maxillofacial Development of Mice, Mus musculus
    Feb 28, 2025 · Generally, the rostralmost tooth-bearing bone is termed the premaxilla, while the main upper jaw bone, the maxilla, is located caudolaterally to ...
  89. [89]
    Canine Fossa - an overview | ScienceDirect Topics
    The canine fossa is defined as a hollow of variable extent located on the facial surface of the maxilla, situated just below the infraorbital foramen, where the ...
  90. [90]
    Maxilla bone of Ox, Horse, Dog and Fowl | Veterinary Anatomy
    The two palatine processes do not meet, but join the palatine and vomer posteriorly. The maxilla joins the pre-maxilla and nasal anteriorly while it is ...Maxilla bone of animals · Maxilla bone of Ox · Maxilla bone of horse
  91. [91]
    Cranial Anatomical Integration and Disparity Among Bones ...
    Nov 10, 2021 · Results show that primates have a greater anatomical integration of their skulls and a greater disparity among bones than other non-primate mammals.
  92. [92]
    Anatomy and computed tomography of the nasal cavity, nasal ...
    Apr 21, 2023 · It is known that pneumatization of the bones fulfills a role in reducing the weight of the skull (Nickel et al., 1979), or it is a site of ...
  93. [93]
    Sinusitis in Horses - American College of Veterinary Surgeons
    The maxillary sinus is the largest paranasal sinus and is divided into two parts (rostral and caudal) by a thin septum.
  94. [94]
    Anatomy and Disorders of the Oral Cavity of Rat-like and Squirrel ...
    All rodent species have 2 well-developed maxillary and mandibular aradicular incisor teeth, which represent the most distinguishable dental feature of this ...
  95. [95]
    Mammal Skulls – Morphology of the Vertebrate Skeleton
    Maxillae – Tooth-bearing bones that make up a large part of the rostrum and palate. The maxillae are especially large in cetaceans.Missing: carnivores variations
  96. [96]
    Actinopterygii: More on Morphology
    The skull is a complex assemblage of bones. Teleost fish -- the majority of ray-finned fishes -- have upper jaw bones (the maxilla and premaxilla) that are free ...
  97. [97]
    The Jaw Adductor Muscle Complex in Teleostean Fishes
    Most teleosts have the adductor mandibulae associated directly or indirectly with the buccal membrane. In addition to lining the entirety of the oropharyngeal ...
  98. [98]
    The Skull of Phyllomedusa sauvagii (Anura, Hylidae)
    Feb 24, 2016 · The septomaxilla is a tiny, paired bone, encapsulated within the cartilages of the nasal capsule and thereby having no articulation with other ...
  99. [99]
    Anatomical network analyses reveal evolutionary integration and ...
    Sep 5, 2022 · The lizard skull morphology is extremely diverse. For instance, the group ranges in cranial architecture from amphikinetic skulls in varanids ...
  100. [100]
    Paranasal sinus system and upper respiratory tract evolution in ...
    Aug 16, 2021 · A maxillary sinus is also present in the secondary palate of the maxilla anterior to the antorbital sinus, but differs from Gavialis by ...
  101. [101]
    Vascular patterns in the heads of crocodilians: blood vessels and ...
    Sep 28, 2016 · In crocodilians, the maxillary artery is a ... sinus, allowing the sinus and the maxillary neurovascular bundle to come into contact.
  102. [102]
    [PDF] AVIAN ANATOMY:
    The osseous walls of the Fossa are variable; often the palatine process of the maxilla, the palatine bone, and the ectethmoid contribute to its walls ...
  103. [103]
    Evolution of a multifunctional trait: shared effects of foraging ecology ...
    Dec 18, 2019 · We found that both climate and foraging behaviour were significantly correlated with the beak shape and size. However, foraging ecology had a greater effect on ...
  104. [104]
    Cranial kinesis in lizards (Lacertilia): Origin, biomechanics, and ...
    Dec 17, 2011 · Movable connections of the maxillo-buccal segments with the axial skull persisted in the amphikinetic skull and were completed by the ...Missing: maxilla | Show results with:maxilla
  105. [105]
    4 - The Evolution of Vertebrate Dermal Jaw Bones in the Light of ...
    Dec 31, 2018 · Under the current consensus of gnathostome phylogeny, the dermal jaw bones are present from the origin of jaws.
  106. [106]
    Evolution of the vertebrate jaw: homology and developmental ...
    In gnathostomes, both the upper and lower jaws are direct derivatives of the mandibular arch. In the shark, for example, the mandibular arch of an early ...
  107. [107]
    A well-preserved 'placoderm' (stem-group Gnathostomata) upper ...
    Feb 22, 2023 · There is now a growing consensus that the last common ancestor of crown gnathostomes possessed dermal jaw bones, a trait potentially extending ...
  108. [108]
    Evolution of the therian face through complete loss of the premaxilla
    Aug 26, 2022 · The present findings indicate that the true premaxilla was completely lost during the evolution of the therian mammals, resulting in the establishment of the ...
  109. [109]
    Mammalian face as an evolutionary novelty - PNAS
    Oct 29, 2021 · The rostral tip of the nasal cartilage, where the nontherian premaxilla occurs, does not produce any bony elements in the mouse.Missing: rodents | Show results with:rodents
  110. [110]
    Nasal Anatomy of the Non‐mammaliaform Cynodont Brasilitherium ...
    Oct 14, 2014 · The first important aspect of skull morphology in Brasilitherium riograndensis is the shape of the outer nasal openings of the skull.Missing: lighter | Show results with:lighter<|separator|>
  111. [111]
    Morphology of the maxilla informs about the type of predation ...
    Mar 6, 2025 · They represented the most abundant predatory dinosaurs in Gondwana during the Cretaceous. Bolstered by biomechanical studies, the morphology of ...
  112. [112]
    Bone density and the lightweight skeletons of birds - Journals
    Mar 17, 2010 · The skeletons of birds are universally described as lightweight as a result of selection for minimizing the energy required for flight.Missing: maxilla | Show results with:maxilla
  113. [113]
    Evolution of the vertebrate jaw: comparative embryology and ...
    A specific class of homeobox-containing genes, called Hox genes, are expressed sequentially along the anteroposterior axis of the embryonic pharynx, thereby ...
  114. [114]
    Morphological variation of the Australopithecus afarensis maxilla
    The main findings are that 1) A. afarensis has high degrees of size and shape variation compared with extant hominines, potentially linked with sexual ...
  115. [115]
    The human premaxilla and Goethe - PMC - NIH
    Aug 20, 2019 · Contradicting this theory, Goethe (1749–1832) found the intermaxillary bone in the human skull in 1784 [3]. Goethe hoped to present this ...