The labyrinthine artery, also known as the internal auditory artery or auditory artery, is a slender vessel, typically measuring about 0.20 mm in diameter, that serves as the primary blood supply to the inner ear, including the cochlea and vestibular apparatus, as well as the facial (cranial nerve VII) and vestibulocochlear (cranial nerve VIII) nerves.[1][2] It originates most frequently from the anterior inferior cerebellar artery (AICA) in approximately 75-85% of cases, or directly from the basilar artery in 15-28% of cases, with rarer origins from the vertebral or superior cerebellar arteries.[2][1] The artery accompanies the vestibulocochlear nerve through the internal acoustic meatus into the inner ear, where it divides into the anterior vestibular artery and the common cochlear artery, the latter further branching into the proper cochlear artery and vestibular rami to perfuse the basilar membrane, spiral lamina, stria vascularis, utricle, saccule, and semicircular ducts.[2][4]Due to its small size and lack of collateral circulation, the labyrinthine artery is highly vulnerable to ischemia; even brief occlusion, such as 15 seconds of blood flow cessation, can abolish nerve excitability, leading to sudden sensorineural hearing loss, vertigo, and balance disturbances.[5] Clinically, it is often implicated in labyrinthine infarction, which frequently accompanies AICA territory strokes, and its preservation is critical during cerebellopontine angle surgeries, where it typically lies superior to the cochlear nerve (90.5% of cases), inferior to the vestibular nerve (89.4%), and inferior to the facial nerve (88%).[5][1] Variations in its origin and branching—such as single versus double branches (noted in about 51% of cases)—can influence surgical risks and are best assessed preoperatively via high-resolution MRI sequences like FIESTA.[1][2]
Anatomy
Origin and Course
The labyrinthine artery, also known as the internal auditory artery, typically originates as a single branch from the meatal loop of the anterior inferior cerebellar artery (AICA) near the pontomedullary junction, accounting for approximately 75-90% of cases.[1][6] In rarer instances, it arises directly from the basilar artery, with prevalence ranging from 10-28% across studies, though this direct origin is less common and often debated due to variations in anatomical classification.[1][6]From its origin, the artery follows a short cisternal or precanalicular segment, traveling parallel and in close proximity to the facial nerve (cranial nerve VII) and vestibulocochlear nerve (cranial nerve VIII), typically positioned inferior to these nerves or along their ventral aspect.[1][6] It enters the internal auditory canal via the anteroinferior rim of the porus acusticus and courses through the canal for a mean length of 8-12 mm, corresponding to the typical dimensions of the canal itself.[7] The vessel is notably slender, with an average diameter of 0.2 mm (range 0.15-0.27 mm), and lacks significant anastomotic collaterals, rendering it a true end-artery.[1][8]Upon reaching the fundus of the internal auditory canal, the labyrinthine artery divides into its main branches, which penetrate the inner ear structures: the common cochlear artery enters via the bony canal of the modiolus in the cochlea, while the anterior vestibular artery passes through the cribriform areas of the vestibule.[6][7] This trajectory ensures direct vascular access to the labyrinthine contents without extensive branching along the canal.[1]
Branches and Relations
The labyrinthine artery bifurcates into two primary branches within the internal auditory canal: the anterior vestibular artery, which supplies the utricle as well as the superior and lateral semicircular canals, and the common cochlear artery, which further divides into the proper cochlear artery and the posterior vestibular artery.[5] This branching pattern is observed in the majority of cases, with the anterior vestibular artery coursing superiorly and the common cochlear artery directing toward the cochlea and posterior vestibular structures.[1]In the cerebellopontine angle cistern, the labyrinthine artery travels inferior to the facial nerve (cranial nerve VII) and the vestibulocochlear nerve (cranial nerve VIII).[6] Upon entering the internal auditory canal, it maintains close spatial relationships with these nerves, typically positioned inferior to the facial nerve in approximately 88% of cases and inferior to the vestibular division of the vestibulocochlear nerve in about 89%, while superior to the cochlear division in roughly 90%; it may also lie between the facial and vestibulocochlear nerves in around 41% of specimens.[1]The artery courses through the internal auditory canal within the petrous portion of the temporal bone, running adjacent to the dura mater that lines the canal.[7] Vascularly, it arises most commonly from the anterior inferior cerebellar artery (in about 75% of cases) and maintains proximity to the anterior inferior cerebellar artery, though as an end-artery with minimal collateral circulation, significant anastomoses are rare.[1][5]
Function
Blood Supply to the Inner Ear
The labyrinthine artery serves as the primary and exclusive source of arterial blood to the inner ear, delivering oxygenated blood to both the cochlea and the vestibular apparatus without significant contributions from other vessels.[9] Upon entering the internal acoustic meatus, it typically divides into the anterior vestibular artery and the common cochlear artery, with the latter further dividing into the proper cochlear artery and the vestibulocochlear artery, and the proper cochlear branch further ramifying into the spiral modiolar artery.[2] This artery penetrates the modiolus of the cochlea, branching radially to form extensive capillary beds that perfuse critical structures such as the stria vascularis—responsible for endolymph production—and the organ of Corti, where hair cells enable auditory transduction.[10] The vestibular branches, including the anterior vestibular artery and vestibular rami of the vestibulocochlear artery, extend to nourish the cristae ampullares within the ampullae of the semicircular canals and the maculae of the utricle and saccule.[11]The vascular territories of the labyrinthine artery encompass the entirety of the cochlear blood flow, providing 100% of the nutrient supply to this structure and rendering it entirely dependent on this single end-artery.[12] For the vestibular system, the artery predominantly supplies the superior and lateral semicircular canals, along with the utricle and saccule, while the posterior semicircular canal receives its input via the posterior vestibular artery, a consistent branch of the labyrinthine system.[9] These territories ensure precise perfusion of the membranous labyrinth's sensory epithelia, supporting the maintenance of endolymphatic and perilymphatic fluid homeostasis essential for inner ear function.Microcirculation within the inner ear arises from dense capillary networks distributed across the perilymphatic and endolymphatic compartments, featuring specialized fenestrated capillaries in the stria vascularis (diameter 12–16 µm) and narrower vessels in the spiral ligament (9–12 µm).[13] These networks lack substantial anastomoses or external collaterals, resulting in an "end-organ" vulnerability where even brief interruptions can lead to ischemia; for instance, flow cessation for as little as 15 seconds diminishes auditory nerve excitability.[10]Pericytes along these capillaries actively regulate local flow, with blood velocities ranging from 0.03–0.18 mm/s, underscoring the system's sensitivity to hemodynamic changes.[13]Quantitatively, the labyrinthine artery's contribution represents a minute fraction of total cerebral blood flow—estimated at approximately 1/1,000,000 of cardiac output in humans, or roughly 0.005 mL/min—highlighting its disproportionate importance relative to volume.[13] In animal models, cochlear blood flow rates have been measured at 0.3–0.6 µL/min under controlled conditions, aligning with the overall low-flow profile that amplifies ischemic risk despite minimal absolute demand.[14]
Role in Auditory and Vestibular Systems
The labyrinthine artery provides essential perfusion to the hair cells within the cochlea, enabling the mechanotransduction process that converts mechanical sound waves into electrical neural signals transmitted via the cochlear nerve.[9] This blood supply ensures the metabolic support required for hair cell function, as these specialized sensory cells rely on continuous oxygen and glucose delivery to maintain their responsiveness to basilar membrane vibrations.[15]In the vestibular system, the labyrinthine artery nourishes the sensory epithelia of the semicircular canals and otolith organs (utricle and saccule), facilitating the detection of angular acceleration and linear motion essential for balance and spatial orientation.[9] The anterior vestibular artery, a branch of the labyrinthine artery, supplies the superior and lateral semicircular canals and the utricle, while the posterior vestibular artery supplies the posterior semicircular canal and the saccule, supporting hair cell depolarization in response to endolymph flow and otolith displacement.[16]The artery's delivery of oxygen and nutrients is critical for the high metabolic demands of inner ear tissues, particularly the stria vascularis in the cochlea, where Na⁺/K⁺-ATPase pumps drive endolymph production and maintain the potassium-rich ionic environment necessary for hair cell activity.[15] This vascular support upholds ionic homeostasis across the inner ear, ensuring proper depolarization of hair cells and efficient signal propagation to brainstem nuclei for auditory and vestibular processing.[17]
Variations
Anatomical Variations
The labyrinthine artery exhibits several deviations from its typical origin as a branch of the anterior inferior cerebellar artery (AICA). In approximately 28% (95% CI: 17–40) of cases, it arises directly from the basilar artery, altering the vascular dynamics at the pontocerebellar junction.[1] Less frequently, origins from the posterior inferior cerebellar artery (PICA) occur with a prevalence of approximately 3% (95% CI: 0–9).[1] Additionally, in 10-20% of individuals, the labyrinthine artery emerges via a common trunk shared with the AICA, which may influence surgical approaches to the cerebellopontine angle.[1] Rarer origins include the vertebral artery (~5%) and superior cerebellar artery (exceptionally rare).[2]Variations in the course of the labyrinthine artery include instances of duplication or double branching, reported in approximately 43% of cases (95% CI: 7–51), where two parallel vessels supply the inner ear instead of a single trunk.[1] Tortuous paths, deviating from the usual straight trajectory through the internal auditory canal, have been observed and can heighten surgical risks due to increased fragility and displacement relative to surrounding nerves.[1] Ectopic entry points into the inner ear, such as atypical penetration sites beyond the standard porus acusticus, represent infrequent anomalies that may affect nutrient distribution to the cochlea and vestibule.[6]Branching variations encompass cases of single branching, where the artery arises as a single trunk (typically dividing later into the common cochlear and anterior vestibular arteries), occurring in about 51% of cases (95% CI: 10–57) and simplifying but potentially under-supplying distal territories.[1] Conversely, additional minor branches may arise to supply the facial nerve (cranial nerve VII), providing supplementary vascularization outside the primary inner ear domain in select anatomies.[6]Associated anomalies include hypoplasia, characterized by a reduced diameter of less than 0.2 mm, which compromises flow to the inner ear and is noted at the lower end of the typical range (mean 0.20 mm).[1] Aplasia, or complete absence of the labyrinthine artery, is exceedingly rare and typically compensated by collateral branches from the stylomastoid artery, maintaining partial inner ear perfusion.[18]
Prevalence and Distribution
The labyrinthine artery most commonly arises from the anterior inferior cerebellar artery (AICA) in 75.4% (95% CI: 62.7–86.4) of cases globally, while direct origin from the basilar artery (BA) is reported in 27.7% (95% CI: 16.8–40.0), based on a meta-analysis of 3,778 arteries across 33 studies encompassing both cadaveric dissections and imaging data.[1] These findings demonstrate consistency between anatomical and radiological methods, with no significant discrepancies in prevalence estimates.[1]Ethnic variations influence the distribution of origins, with higher BA origin rates in certain populations. For instance, in East African (black Kenyan) cohorts, BA origin predominates at 75.1%, common trunk with AICA at 13.9%, and AICA origin at 11.0%, derived from examination of 346 arteries.[19] In contrast, European populations exhibit lower BA origin rates, with AICA or common cerebro-labyrinthine trunk origins reaching 89.0% (95% CI: 80.8–95.3) in Italian samples.[1] Asian and North American groups show intermediate patterns, often with elevated duplication or double branching.[1]
Percentages derived from meta-analysis with varying sample sizes per category; categories are not mutually exclusive across all studies, and common trunks may overlap.
No significant left-right asymmetry is observed in the prevalence or distribution of labyrinthine artery variations.[19] Studies report no notable sex-based differences in origin patterns or branching.[19] Bilateral occurrences of variations, such as duplications, are documented but occur at lower frequencies compared to unilateral forms, though exact rates vary by study cohort.[1]
Clinical Significance
Pathological Conditions
The labyrinthine artery is susceptible to acute infarction, typically resulting from thromboembolic occlusion originating in the anterior inferior cerebellar artery (AICA) or basilar artery.[20] This leads to sudden sensorineural hearing loss (SNHL) and vertigo due to ischemia in the inner ear structures.[21] Such infarctions occur in approximately 1% of ischemic strokes, often as part of AICA territory involvement.[22]Other pathological conditions affecting the labyrinthine artery include vasculitis, such as in polyarteritis nodosa, where inflammation targets the vessel and its branches, causing auditory and vestibular symptoms.[23] Embolic events can also occlude the artery, while extrinsic compression by tumors like acoustic neuroma may impair flow, leading to symptoms such as tinnitus and nystagmus.[24] These disruptions primarily affect the cochlear and vestibular end-organs supplied by the artery.[25]Diagnosis of labyrinthine infarction relies on magnetic resonance imaging (MRI), which demonstrates restricted diffusion in the cochlea and vestibule, confirming acute ischemia.[26]Audiometry typically reveals profound unilateral hearing loss, supporting the vascular etiology.[21]The prognosis for labyrinthine infarction is generally poor, attributed to the artery's status as an end-artery with limited collaterals, resulting in permanent inner ear damage and minimal functional recovery.[27] Spontaneous recanalization is rare.
Surgical and Diagnostic Considerations
In neurosurgical procedures involving the cerebellopontine angle, such as acoustic neuroma resection via the translabyrinthine or retrosigmoid approach, manipulation of the labyrinthine artery poses significant risks of ischemia to the inner ear, potentially leading to profound sensorineural hearing loss or vertigo.[28]Hearing loss is inevitable with the translabyrinthine approach due to labyrinthectomy (nearly 100% incidence) and occurs in approximately 50-70% of cases attempting preservation via the retrosigmoid approach. Similarly, in microvascular decompression for hemifacial spasm or trigeminal neuralgia, the artery's proximity to the internal auditory canal necessitates meticulous preservation to avoid spasm or thrombosis, which has been linked to transient or permanent auditory deficits in approximately 8% of patients with hemifacial spasm.[29]The labyrinthine artery's anatomical position within the internal auditory canal, where it travels alongside the facial (VII) and vestibulocochlear (VIII) nerves, requires careful retraction techniques during surgery to prevent nerve compression or arterial kinking.[1] It typically lies superior to the cochlear nerve (90.5% of cases), inferior to the vestibular nerve (89.4%), and inferior to the facial nerve (88%).[1] Preoperative assessment of anatomical variations, such as multiple branches or aberrant origins, is crucial, as these can elevate complication rates. Preservation strategies include the use of neuro-navigation systems for real-time guidance, which enhance differentiation of vascular structures and reduce inadvertent injury during dissection.[1]Diagnostic evaluation of the labyrinthine artery relies on high-resolution imaging modalities to delineate its origin, course, and patency, particularly in cases of suspected occlusion or preoperative planning. Magnetic resonance imaging (MRI) angiography and high-resolution computed tomography (CT) angiography provide detailed visualization of the artery's trajectory from the anterior inferior cerebellar artery, aiding in the identification of stenoses or variants that could complicate surgery.[2] These techniques are essential for assessing flow dynamics in thromboembolic events, though isolated labyrinthine infarctions may require advanced sequences like 3D-FLAIR MRI to detect subtle abnormalities.[30]Transcranial Doppler ultrasound offers supplementary flow assessment in suspected occlusions affecting the vertebrobasilar system, though its resolution limits direct labyrinthine evaluation.Recent advances in intraoperative imaging have improved outcomes by enabling real-time monitoring of the labyrinthine artery. Indocyanine green (ICG) fluorescenceangiography, introduced in the 2010s for neurosurgical applications, allows visualization of arterial perfusion during procedures like microvascular decompression, facilitating immediate adjustments to avoid ischemia and preserving auditory function in high-risk cases.[31] This technique has demonstrated utility in detecting subtle aneurysms or flow disruptions at the internal auditory canal entry, reducing postoperative complications such as hearing loss.[32]
History
Early Descriptions
The blood supply to the membranous labyrinth was first noted in early anatomical studies of the inner ear, with Joseph Guichard Duverney providing basic descriptions of the vascular supply to the membranous and bony labyrinth in his 1683 treatise Traité de l'organe de l'ouïe, based on dissections that highlighted the role of vessels in inner ear nutrition.[33] These observations laid foundational groundwork but did not identify a specific dedicated artery.The labyrinthine artery itself received its initial specific description in the 19th century by Ernst Thiele in 1843, who observed it accompanying the acoustic nerve through the internal auditory canal and branching to supply the cochlea and vestibule, emphasizing its role in inner ear vascularization.[34] This marked the recognition of the vessel as a distinct entity essential for the inner ear's end-arterial supply.Subsequent early works expanded on its anatomy and branches. Friedrich Henle, in his Handbuch der Gefässlehre des Menschen (1868), detailed the artery's typical origin from the anterior inferior cerebellar artery or adjacent basilar artery segments, describing its entry into the inner ear via the macula cribrosa superior and its division into cochlear and vestibular branches that perfuse the membranous labyrinth.[34] Adam Politzer, through temporal bone dissections in the 1880s documented in his Lehrbuch der Ohrenheilkunde (first edition 1878, expanded in later editions), contributed to understanding of inner ear pathologies via postmortem examinations.[35]Nomenclature for the vessel evolved from early terms like "auditory artery" or "internal auditory artery," reflecting its association with the vestibulocochlear nerve, to "labyrinthine artery" in the early 20th century, which better encompassed its supply to both cochlear (auditory) and vestibular components of the membranous labyrinth.[34]Early studies were limited by reliance on gross dissection and macroscopic observation of temporal bones, which obscured finer microvascular details, such as precise branching patterns and anastomoses, that would later require microscopic and injection techniques for elucidation.[34]
Modern Anatomical Studies
In the mid-20th century, cadaveric dissections provided foundational quantitative data on the labyrinthine artery's anatomical variations. Sydney Sunderland's 1945 study examined relationships with cranial nerves, finding 17% of labyrinthine arteries ventral to the facial and glossopharyngeal nerves, with consistent entry into the internal auditory canal alongside the vestibulocochlear nerve.[34] Concurrently, injection studies by Ryuji S. Kimura in the late 1950s (published 1958) in animal models demonstrated the end-artery characteristics of the labyrinthine artery, where vascular occlusion led to immediate and irreversible ischemia in the cochlea and vestibular labyrinth due to the absence of significant collaterals.Building on these efforts, late 20th-century research refined understanding of rarer origins. Antonio Mazzoni's 1972 dissection of 100 temporal bones identified posterior inferior cerebellar artery (PICA) origins in 3% of specimens, a variation with implications for vascular supply in the posterior fossa. The introduction of magnetic resonance imaging (MRI) and angiography from the 1990s onward enabled noninvasive in vivo visualization, facilitating prevalence assessments; for instance, early 2000s angiographic studies confirmed AICA origins in over 75% of cases while mapping the artery's tortuous course through the cerebellopontine angle.[1]Advances in the 2010s and 2020s have leveraged systematic reviews, 3D reconstructions, and population-specific data to enhance precision. A 2024 narrative review synthesized cadaveric and imaging data to delineate the artery's relationships with cranial nerves VII and VIII, aiding neurosurgical trajectory planning.[34] Ethnic variations were highlighted in a 2020 Kenyan cadaveric study of 346 sides, where 75.1% of labyrinthine arteries arose directly from the basilar artery, contrasting with higher AICA prevalence in other populations and informing diverse anatomical norms.[36]These anatomical insights have directly contributed to surgical advancements, particularly through integration with neuronavigation systems that overlay preoperative MRI/angiography data to minimize intraoperative manipulation of the labyrinthine artery, thereby reducing ischemia risks in procedures such as vestibular schwannoma resection.