Vascular loops in the anterior inferior cerebellar artery, as identified by magnetic resonance imaging, and their relationship with otologic symptoms

Abreu Junior, Luiz de; Kuniyoshi, Cristina Hiromi; Wolosker, Angela Borri; Borri, Maria Lúcia; Antunes, Augusto; Ota, Vanessa Kiyomi Arashiro; Uchida, Daniela

doi:10.1590/0100-3984.2015.0069

Abstract

Objective:

To use magnetic resonance imaging to identify vascular loops in the anterior inferior cerebellar artery and to evaluate their relationship with otologic symptoms.

Materials and Methods:

We selected 33 adults with otologic complaints who underwent magnetic resonance imaging at our institution between June and November 2013. Three experienced independent observers evaluated the trajectory of the anterior inferior cerebellar artery in relation to the internal auditory meatus and graded the anterior inferior cerebellar artery vascular loops according to the Chavda classification. Kappa and chi-square tests were used. Values of p < 0.05 were considered significant.

Results:

The interobserver agreement was moderate. Comparing ears that presented vascular loops with those that did not, we found no association with tinnitus, hearing loss, or vertigo. Similarly, we found no association between the Chavda grade and any otological symptom.

Conclusion:

Vascular loops do not appear to be associated with otoneurological manifestations.

Keywords:
Arteries/anatomy & histology; Nerve compression syndromes; Magnetic resonance imaging; Tinnitus; Hearing loss; Vertigo

Resumo

Objetivo:

O objetivo deste estudo foi avaliar e analisar, por ressonância magnética, a presença e o tipo de alça vascular da artéria cerebelar anteroinferior e sua associação com sintomas otológicos.

Materiais e Métodos:

Selecionamos 33 adultos com queixas otológicas que realizaram ressonância magnética em nosso serviço, entre junho e novembro de 2013. Três observadores experientes, independentes, avaliaram o trajeto da artéria cerebelar anteroinferior e sua relação com o conduto auditivo interno, classificando os tipos de alça vascular segundo a classificação de Chavda. Os testes de kappa e de qui-quadrado foram utilizados e o índice de significância adotado foi p < 0,05.

Resultados:

O coeficiente kappa entre diferentes observadores demonstrou concordância moderada. Comparando as orelhas que apresentavam alça vascular com as que não apresentavam, não encontramos associação com zumbido, hipoacusia ou tontura. Semelhantemente, comparando os diferentes graus da classificação de Chavda com os sintomas relatados, não encontramos associação estatisticamente significante.

Conclusão:

Concluímos que não há associação entre a presença ou o tipo de alça vascular e sintomas otoneurológicos.

Unitermos:
Compressão vascular; Ressonância magnética; Zumbido; Hipoacusia; Tontura

INTRODUCTION

Common otologic symptoms include tinnitus (the perception of sounds in the absence of external stimuli), hearing loss, and dizziness. The estimated prevalence of these symptoms in the Brazilian population is approximately 22% for tinnitus⁽¹1 Oiticica J, Bittar RS. Tinnitus prevalence in the city of São Paulo. Braz J Otorhinolaryngol. 2015;81:167-76.⁾, 9% for hearing loss⁽²2 Bittar RSM, Oiticica J, Bottino MA, et al. Population epidemiological study on the prevalence of dizziness in the city of São Paulo. Braz J Otorhinolaryngol. 2013;79:688-98.⁾, and 42% for dizziness⁽³3 Cruz MS, Oliveira LR, Carandina L, et al. Prevalence of self-reported hearing loss and attributed causes: a population-based study. Cad Saúde Pública. 2009;25:1123-31.⁾, and those rates increase with advancing age.

Although various diseases are associated with otologic symptoms, the cause is not always identified. In some cases, it is believed that the etiology involves a vascular loop in the anterior inferior cerebellar artery (AICA), insinuating itself into the internal auditory meatus.

The term vascular compression syndrome, which refers to a group of diseases caused by direct contact between a blood vessel and a cranial nerve, was introduced by McKenzie in 1936 and popularized by Jannetta in 1975⁽⁴4 Markowski J, Gierek T, Kluczewska E, et al. Assessment of vestibulocochlear organ function in patients meeting radiologic criteria of vascular compression syndrome of vestibulocochlear nerve-diagnosis of disabling positional vertigo. Med Sci Monit. 2011;17: CR169-73.^,⁶6 Jannetta PJ. Neurovascular cross-compression in patients with hyperactive dysfunction symptoms of the eighth cranial nerve. Surg Forum. 1975;26:467-9.⁾. The prototype of this syndrome, hemifacial spasm, was first described in 1875, when a vertebral artery aneurysm was found to be compressing the facial nerve of a patient⁽⁷7 Shultze F. Linksseitieer fatialiskrampf in folge cines aneurysma der arterid verteralis sinistra. Virchows Arch. 1875;65:385-91.⁾. The concept has since been expanded to explain diseases related to various cranial nerves.

Jannetta et al., for example, suggested that redundant arterial loops could interfere with the vestibulocochlear nerve (eighth cranial nerve), resulting in otologic symptoms⁽⁸8 Jannetta PJ, Mrller MB, Mrller AR. Disabling positional vertigo. N Engl J Med. 1984;310:1700-5.⁾. Although numerous articles have focused on this condition, the existence of vascular compression syndromes continues to be questioned.

The objective of the present study was to evaluate and analyze, through magnetic resonance imaging (MRI), the presence of vascular loops and their association with the otologic profile.

MATERIALS AND METHODS

We selected 33 adults with otologic complaints who underwent MRI at our facility between June and November of 2013. These patients completed a questionnaire and gave written informed consent. The sample comprised 21 women (63.6%) and 12 men (36.4%). The mean age was 51.1 ± 17.3 years (range, 21-83 years).

We evaluated the trajectory of the AICA in relation to the internal auditory meatus through a T2-weighted sequence, using the three-dimensional driven equilibrium technique, which increases the contrast between the cerebrospinal fluid in the subarachnoid space and the cranial nerves. The scans were obtained in 1.0 T and 1.5 T MRI scanners (Gyroscan-NT and Intera, respectively; Philips, Best, the Netherlands). Three radiologists, each with more than five years of experience, graded the vascular loops according to the Chavda classification⁽⁸8 Jannetta PJ, Mrller MB, Mrller AR. Disabling positional vertigo. N Engl J Med. 1984;310:1700-5.⁾. The raters were blinded to the sidedness of the otologic symptom.

The Chavda classification grades the vascular loops in the AICA as follows⁽⁸8 Jannetta PJ, Mrller MB, Mrller AR. Disabling positional vertigo. N Engl J Med. 1984;310:1700-5.⁾: grade I - when an AICA vascular loop borders the internal auditory meatus (internal acoustic pore); grade II - when the loop insinuates itself into the internal auditory meatus but occupies 50% or less of the canal; or grade III - when the loop occupies more than 50% of the canal.

We used the chi-square test to determine whether the presence of a vascular loop was associated with tinnitus, hearing loss, or dizziness The level of significance adopted was 0.05. The kappa test was used in order to characterize the concordance between the examiners as to the type of vascular loop identified.

RESULTS

The frequencies of otologic symptoms (tinnitus, hearing loss, and dizziness) are listed in Table 1. Of the 33 patients evaluated, 14 (42.4%) had complained of tinnitus (in either ear), 14 (42.4%) had reported hearing loss, and 25 (75.8%) had complained of dizziness.

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Table 1
Tinnitus, hearing loss, and dizziness in the sample studied.

To determine the Chavda grade, we first calculated the interobserver agreement. The kappa values are shown in Table 2.

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Table 2
Interobserver agreement (kappa values) among the three evaluators.

Examples of MRI scans in which Chavda grade I, II, and III vascular loops were found are shown in Figures 1, 2, and 3, respectively.

Figure 1
Chavda grade I vascular loops in the AICA. Note that the vessel runs alongside the internal auditory meatus of the left ear, without extending to the inside (arrows).

Figure 2
Examples of Chavda grade II vascular loops in the AICA. The vascular structure extends to the interior of the internal auditory meatus but occupies 50% or less of the canal (arrows).

Figure 3
Examples of Chavda grade III vascular loops in the AICA. The vessel occupies more than 50% of the canal of the internal auditory meatus, reaching its basal portion (arrows).

To evaluate interobserver agreement regarding the grading of the vascular loops, we separated the data by sidedness and considered the Chavda classification concordant if at least two of the three evaluators were in agreement. In this analysis, a total of 66 ears were evaluated. Two of those were excluded for presenting different classifications among the three evaluators. Therefore, the final sample comprised 64 ears.

Of the 64 ears evaluated, 28 (43.75%) presented no vascular loop, 31 (48.44%) presented a grade I Chavda vascular loop and 5 (7.81%) presented a grade II Chavda vascular loop.

The results of the chi-square tests comparing the occurrence of otologic symptoms (tinnitus, hearing loss, and dizziness) with the presence of vascular loops and with the Chavda classification are shown in Table 3. The p values indicate that the otoneurological symptoms were no associated with the presence or type of vascular loop.

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Table 3
Results of the chi-square tests comparing the occurrence of otologic symptoms with the presence of vascular loops and with the Chavda classification.

We also evaluated the symptom groups in the absence or presence of a (Chavda grade I or II) vascular loop. However, no statistically significant results were obtained (tinnitus: χ² = 0.339, p = 0.561; hearing loss: χ² = 0.731, p = 0.393; dizziness: χ² = 0.451, p = 0.502).

DISCUSSION

Our results indicate that there is association between otologic symptoms and the presence or type of vascular loop in the AICA. We stratified the results by the ear affected and considered Chavda classification concordant only if at least two of the three evaluators were in agreement. These findings corroborate the bulk of the data in the literature⁽⁵5 Makins AE, Nikolopoulos TP, Ludman C, et al. Is there a correlation between vascular loops and unilateral auditory symptoms? Laryngoscope. 1998;108(11 Pt 1):1739-42.^,⁹9 Grocoske FLB, Mendes RCCG, Vosguerau R, et al. Achados otoneurológicos em pacientes com diagnóstico de alça vascular de VIII par craniano na ressonância magnética. Arq Int Otorrinolaringol. 2011;15:418-25.^,¹¹11 Sirikci A, Bayazit Y, Ozer E, et al. Magnetic resonance imaging based classification of anatomic relationship between the cochleovestibular nerve and anterior inferior cerebellar artery in patients with non-specific neuro-otologic symptoms. Surg Radiol Anat. 2005;27:531-5.⁾.

The concept of vascular compression syndromes was popularized by Jannetta⁽⁶6 Jannetta PJ. Neurovascular cross-compression in patients with hyperactive dysfunction symptoms of the eighth cranial nerve. Surg Forum. 1975;26:467-9.⁾, who reported a reduction in dysfunctional hyperactivity of the eighth cranial nerve after using microsurgery to separate the nerve from a blood vessel, supporting the theory that a vascular loop is an etiological factor of dysfunction. On the basis of that study, various other researchers have attempted to establish a relationship between vascular compressions and a number of clinical conditions, such as hemifacial spasm and trigeminal neuralgia⁽⁴4 Markowski J, Gierek T, Kluczewska E, et al. Assessment of vestibulocochlear organ function in patients meeting radiologic criteria of vascular compression syndrome of vestibulocochlear nerve-diagnosis of disabling positional vertigo. Med Sci Monit. 2011;17: CR169-73.⁾. However, controversy remains regarding the pathophysiology of these conditions. It has been suggested that chronic compression is responsible for regional nerve demyelination or that disturbances in the distribution of blood flow result in reduced vascular perfusion of nerves, either of which could explain the clinical profiles of vascular compression syndromes⁽¹²12 Girard N, Poncet M, Caces F, et al. Three-dimensional MRI of hemifacial spasm with surgical correlation. Neuroradiology. 1997;39:46-51.^,¹⁵15 Applebaum EL, Valvasorri G. Internal auditory canal vascular loops: audiometric and vestibular system findings. Am J Otol. 1985; Suppl:110-3.⁾.

It is of note that new, highly sensitive MRI techniques have made it possible to investigate the relationship between intracranial vessels and nerves in a non-invasive manner. Volumetric sequences with strong T2 weighting (constructive interference in steady state imaging, fast imaging employing steady-state acquisition, and balanced fast-field echo imaging) present advantages over conventional angiographic examinations, given that, in addition to being non-invasive (not involving the use of contrast), the former allow the assessment of the blood vessels, as well as of the nerve in question and the harmonic or potentially pathological relationship between the two⁽¹⁶16 Yoshino N, Akimoto H, Yamada I, et al. Trigeminal neuralgia: evaluation of neuralgic manifestation and site of neurovascular compression with 3D CISS MR imaging and MR angiography. Radiology. 2003;228:539-45.^,¹⁷17 Satoh T, Onoda K, Date I. Fusion imaging oh three-dimensional MR cisternograms and angiograms for the assessment of microvascular decompression in patients with hemifacial spasms. J Neurosurg. 2007;106:82-9.⁾.

Although the concept of vascular compression has been widely accepted for hemifacial spasm and trigeminal neuralgia, its relationship with otologic symptoms such as tinnitus, hearing loss, and dizziness is not yet clear. Otologic complaints are relatively common in daily life, and it is not uncommon to see cases in which the cause of such complaints is not identified; for many of those cases, vascular compression has been considered an etiological factor⁽¹⁸18 De Ridder D, Ryu H, Mrller AR, et al. Functional anatomy of the human cochlear nerve and its role in microvascular decompressions for tinnitus. Neurosurgery. 2004;54:381-8; discussion 88-90.⁾.

Makins et al. found no significant differences between ears with clinical signs and symptoms and healthy (asymptomatic) ears regarding the presence of vascular loops, suggesting that the presence of of vascular loop on MRI is not pathological, per se, and can be viewed more as a normal anatomic finding⁽⁵5 Makins AE, Nikolopoulos TP, Ludman C, et al. Is there a correlation between vascular loops and unilateral auditory symptoms? Laryngoscope. 1998;108(11 Pt 1):1739-42.⁾. Similarly, Grocoske et al. found that the presence of a neurovascular conflict involving the eighth cranial nerve on MRI scans could not, in and of itself, explain the otoneurological signs and symptoms observed in the subjects assessed⁽⁹9 Grocoske FLB, Mendes RCCG, Vosguerau R, et al. Achados otoneurológicos em pacientes com diagnóstico de alça vascular de VIII par craniano na ressonância magnética. Arq Int Otorrinolaringol. 2011;15:418-25.⁾. In the present study, we also found no association between the presence or type of vascular loop seen on the MRI scans and the otoneurological signs and symptoms reported.

Post-mortem studies have shown that vascular loops in the AICA occur within the internal auditory meatus in 12.3% of human temporal bones⁽¹¹11 Sirikci A, Bayazit Y, Ozer E, et al. Magnetic resonance imaging based classification of anatomic relationship between the cochleovestibular nerve and anterior inferior cerebellar artery in patients with non-specific neuro-otologic symptoms. Surg Radiol Anat. 2005;27:531-5.^,¹⁹19 Reisser C, Schuknecht HF. The anterior inferior cerebellar artery in the internal auditory canal. Laryngoscope. 1991;101(7 Pt 1):761-6.⁾. However, that might differ from the reality in vivo, because changes can occur as a result of the formaldehyde fixation process⁽²⁰20 Fukuda H, Ishikawa M, Okumura R. Demonstration of neurovascular compression in trigeminal neuralgia and hemifacial spasm with magnetic resonance imaging: comparison with surgical findings in 60 consecutive cases. Surg Neurol. 2003;59:93-9; discussion 99-100.⁾. Therefore, the mere presence of vascular loops in the AICA might not be an indication that there is vascular compression of the eighth cranial nerve. It should be borne in mind that it can represent a simple anatomic variation. It is of note that most of the patients of our sample (n = 36) had vascular loops that were classified as Chavda grade I or II. In a study conducted by Gultekin et al., 72% of the controls had vascular loops in the AICA involving the internal auditory meatus (Chavda grade I)⁽¹⁰10 Gultekin S, Celik H, Akpek S, et al. Vascular loops at the cerebellopontine angle: is there a correlation with tinnitus? AJNR Am J Neuroradiol. 2008;29:1746-9.⁾. However, the data are still controversial, and some studies that have indicated that there is in fact an association between vascular loops and otologic symptoms⁽⁶6 Jannetta PJ. Neurovascular cross-compression in patients with hyperactive dysfunction symptoms of the eighth cranial nerve. Surg Forum. 1975;26:467-9.^,²¹21 Nowé V, De Ridder D, Van de Heyning PH, et al. Does the location of a vascular loop in the cerebellopontine angle explain pulsatile and non-pulsatile tinnitus? Eur Radiol. 2004;14:2282-9.^,²⁴24 De Ridder D, De Ridder L, Nowé V, et al. Pulsatile tinnitus and the intrameatal vascular loop: why do we not hear our carotids? Neurosurgery. 2005;57:1213-7.⁾.

The discrepancies among the results can be explained, at least in part, by differences among observers, which can skew the results of the estimates and the application of different types of classification. In the present study, we used three evaluators and found that the interobserver agreement, as estimated by the kappa index, was moderate to substantial for the classification of vascular loops. Some of the inconsistencies can be explained by the difficulty in differentiating between the successive types of vascular loops according to the Chavda classification. In view of that, we included in our analysis only the values which were concordant between at least two observers, reducing the risk of observer bias. Further studies would be useful in order to detail the relationship between the vascular structure and the nervous system, perhaps generating new classifications that increase the power to discriminate between truly pathological cases and those within the limits of normality.

Certain findings can increase the likelihood that an otoneurological symptom is related to neurovascular compression. Such findings include deviation of the nerve pathway caused by a vascular structure, vascular compression at the emergence of the nerve root, and a perpendicular intersection between a blood vessel and a nerve⁽²⁵25 Naraghi R, Tanrikulu L, Troescher-Weber R, et al. Classification of neurovascular compression in typical hemifacial spasm: threedimensional visualization of the facial and vestibulocochlear nerves. J Neurosurg. 2007;107:1154-63.⁾.

CONCLUSIONS

Our results show independence between the MRI findings and the clinical profile, suggesting that there is no direct, exclusive relationship between the diagnosis of vascular loop in the AICA identified on an MRI scan and the corresponding otoneurological profile. In view of the current knowledge, we believe that the diagnosis of vascular compression syndrome should not be based only on the findings of the examination (MRI in our case), especially in order to avoid unnecessary or futile interventions.

*
Study conducted by the Grupo Fleury at the Hospital São Luiz/Rede D'Or, São Paulo, SP, Brazil.

REFERENCES

¹
Oiticica J, Bittar RS. Tinnitus prevalence in the city of São Paulo. Braz J Otorhinolaryngol. 2015;81:167-76.
²
Bittar RSM, Oiticica J, Bottino MA, et al. Population epidemiological study on the prevalence of dizziness in the city of São Paulo. Braz J Otorhinolaryngol. 2013;79:688-98.
³
Cruz MS, Oliveira LR, Carandina L, et al. Prevalence of self-reported hearing loss and attributed causes: a population-based study. Cad Saúde Pública. 2009;25:1123-31.
⁴
Markowski J, Gierek T, Kluczewska E, et al. Assessment of vestibulocochlear organ function in patients meeting radiologic criteria of vascular compression syndrome of vestibulocochlear nerve-diagnosis of disabling positional vertigo. Med Sci Monit. 2011;17: CR169-73.
⁵
Makins AE, Nikolopoulos TP, Ludman C, et al. Is there a correlation between vascular loops and unilateral auditory symptoms? Laryngoscope. 1998;108(11 Pt 1):1739-42.
⁶
Jannetta PJ. Neurovascular cross-compression in patients with hyperactive dysfunction symptoms of the eighth cranial nerve. Surg Forum. 1975;26:467-9.
⁷
Shultze F. Linksseitieer fatialiskrampf in folge cines aneurysma der arterid verteralis sinistra. Virchows Arch. 1875;65:385-91.
⁸
Jannetta PJ, Mrller MB, Mrller AR. Disabling positional vertigo. N Engl J Med. 1984;310:1700-5.
⁹
Grocoske FLB, Mendes RCCG, Vosguerau R, et al. Achados otoneurológicos em pacientes com diagnóstico de alça vascular de VIII par craniano na ressonância magnética. Arq Int Otorrinolaringol. 2011;15:418-25.
¹⁰
Gultekin S, Celik H, Akpek S, et al. Vascular loops at the cerebellopontine angle: is there a correlation with tinnitus? AJNR Am J Neuroradiol. 2008;29:1746-9.
¹¹
Sirikci A, Bayazit Y, Ozer E, et al. Magnetic resonance imaging based classification of anatomic relationship between the cochleovestibular nerve and anterior inferior cerebellar artery in patients with non-specific neuro-otologic symptoms. Surg Radiol Anat. 2005;27:531-5.
¹²
Girard N, Poncet M, Caces F, et al. Three-dimensional MRI of hemifacial spasm with surgical correlation. Neuroradiology. 1997;39:46-51.
¹³
McCabe BF, Gantz BJ. Vascular loop as a cause of incapacitating dizziness. Am J Otol. 1989;10:117-20.
¹⁴
Nielsen VK. Pathophysiology of hemifacial spasm: I. Ephaptic transmission and ectopic excitation. Neurology. 1984;34:418-26.
¹⁵
Applebaum EL, Valvasorri G. Internal auditory canal vascular loops: audiometric and vestibular system findings. Am J Otol. 1985; Suppl:110-3.
¹⁶
Yoshino N, Akimoto H, Yamada I, et al. Trigeminal neuralgia: evaluation of neuralgic manifestation and site of neurovascular compression with 3D CISS MR imaging and MR angiography. Radiology. 2003;228:539-45.
¹⁷
Satoh T, Onoda K, Date I. Fusion imaging oh three-dimensional MR cisternograms and angiograms for the assessment of microvascular decompression in patients with hemifacial spasms. J Neurosurg. 2007;106:82-9.
¹⁸
De Ridder D, Ryu H, Mrller AR, et al. Functional anatomy of the human cochlear nerve and its role in microvascular decompressions for tinnitus. Neurosurgery. 2004;54:381-8; discussion 88-90.
¹⁹
Reisser C, Schuknecht HF. The anterior inferior cerebellar artery in the internal auditory canal. Laryngoscope. 1991;101(7 Pt 1):761-6.
²⁰
Fukuda H, Ishikawa M, Okumura R. Demonstration of neurovascular compression in trigeminal neuralgia and hemifacial spasm with magnetic resonance imaging: comparison with surgical findings in 60 consecutive cases. Surg Neurol. 2003;59:93-9; discussion 99-100.
²¹
Nowé V, De Ridder D, Van de Heyning PH, et al. Does the location of a vascular loop in the cerebellopontine angle explain pulsatile and non-pulsatile tinnitus? Eur Radiol. 2004;14:2282-9.
²²
Ryu H, Yamamoto S, Sugiyama K, et al. Neurovascular compression syndrome of the eighth cranial nerve. What are the most reliable diagnostic signs? Acta Neurochir (Wien). 1998;140:1279-86.
²³
Ryu H, Yamamoto S, Sugiyama K, et al. Neurovascular compression syndrome of the eighth cranial nerve. Can the site of compression explain the symptoms? Acta Neurochir (Wien). 1999;141:495-501.
²⁴
De Ridder D, De Ridder L, Nowé V, et al. Pulsatile tinnitus and the intrameatal vascular loop: why do we not hear our carotids? Neurosurgery. 2005;57:1213-7.
²⁵
Naraghi R, Tanrikulu L, Troescher-Weber R, et al. Classification of neurovascular compression in typical hemifacial spasm: threedimensional visualization of the facial and vestibulocochlear nerves. J Neurosurg. 2007;107:1154-63.

Publication Dates

Publication in this collection
Sep-Oct 2016

History

Received
25 Apr 2015
Accepted
02 Sept 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] *
Study conducted by the Grupo Fleury at the Hospital São Luiz/Rede D'Or, São Paulo, SP, Brazil.

Otologic symptom	Frequency
Tinnitus
Right ear only	4
Left ear only	7
Both ears	3
Total ears with tinnitus	17 (25.8%)
Total ears without tinnitus	49 (74.2%)
Hearing loss
Right ear only	5
Left ear only	7
Both ears	2
Total ears with hearing loss	16 (24.2%)
Total ears without hearing loss	50 (75.8%)
Dizziness
Total cases with dizziness	25 (75.8%)
Total cases without dizziness	8 (24.3%)

	Evaluator 1	Evaluator 2	Evaluator 3
Evaluator 1	1	0.746	0.684
Evaluator 2	0.746	1	0.628
Evaluator 3	0.684	0.628	1

	No vascular loop	Chavda grade I	Chavda grade II	χ²	P
Tinnitus	Yes = 8	Yes = 7	Yes = 1	0.354	0.838
	No = 20	No = 24	No = 4
Hearing loss	Yes = 8	Yes = 6	Yes = 1	0.732	0.693
	No = 20	No = 25	No = 4
Dizziness	Yes = 22	Yes = 23	Yes = 3	1.132	0.568
	No = 5	No = 7	No = 2

Brasil

Brasil

Vascular loops in the anterior inferior cerebellar artery, as identified by magnetic resonance imaging, and their relationship with otologic symptoms^* * Study conducted by the Grupo Fleury at the Hospital São Luiz/Rede D'Or, São Paulo, SP, Brazil.

Abstract

Objective:

Materials and Methods:

Results:

Conclusion:

Resumo

Objetivo:

Materiais e Métodos:

Resultados:

Conclusão:

INTRODUCTION

MATERIALS AND METHODS

RESULTS

DISCUSSION

CONCLUSIONS

REFERENCES

Publication Dates

History

Brasil

Brasil

Vascular loops in the anterior inferior cerebellar artery, as identified by magnetic resonance imaging, and their relationship with otologic symptoms* * Study conducted by the Grupo Fleury at the Hospital São Luiz/Rede D'Or, São Paulo, SP, Brazil.

Abstract

Objective:

Materials and Methods:

Results:

Conclusion:

Resumo

Objetivo:

Materiais e Métodos:

Resultados:

Conclusão:

INTRODUCTION

MATERIALS AND METHODS

RESULTS

DISCUSSION

CONCLUSIONS

REFERENCES

Publication Dates

History

Vascular loops in the anterior inferior cerebellar artery, as identified by magnetic resonance imaging, and their relationship with otologic symptoms^* * Study conducted by the Grupo Fleury at the Hospital São Luiz/Rede D'Or, São Paulo, SP, Brazil.