Anatomical Variations in Patients with Ménière Disease: A Tomography Study

Lucinda, Lucas Resende; Cristoff, Daniela Dranka; Coelho, Luiz Otávio De Mattos; Zanini, Otávio Pereira Lima; Guimarães, Rita De Cassia Cassou

doi:10.1055/s-0037-1604463

Abstract

Introduction

The etiology of Ménière disease (MD), a difficult-to-treat condition with great morbidity, remains controversial in the literature. The possible clinical and diagnostic impact of anatomical variations of the temporal bone among patients with MD has been recently studied.

Objective

To identify anatomical variations of the temporal bone associated with the diagnosis of MD.

Methods

Thirty-seven patients were included, although each ear was considered separately (n = 74). A case group (nA = 33) was composed of the affected ears of patients with definiteMDand a control group (nB = 41) was used consisting of the ears of individuals who did not meet the criteria for MD and of the contralateral ears from patients with unilateral disease. Tomographic images from the individuals included in the study were submitted to a blinded and systematic evaluation regarding a broad variety of anatomical variations of the temporal bone. Obtained data were compared statistically between the groups and after stratifying the study sample. Significance level was set at 0.05.

Results

Among the affected ears, it was observed an increased number of tomographic scans in which the vestibular aqueduct could not be identified (p = 0.01, Fisher exact test). No statistically significant differences were observed when comparing the affected and contralateral ears frompatients with unilateral MD, between affected ears from patients with unilateral and bilateral disease or between contralateral ears of patients with unilateral affection and patients without the disease.

Conclusion

Some anatomical variations might be more frequent in the affected ears of patients with MD, such as the lower rates of individualization of the vestibular aqueduct.

Keywords:
Ménière disease; temporal bone; x-ray computed tomography

Introduction

Ménière disease (MD) is a chronic disease affecting the inner ear. It was first described, in 1861, by Prosper Ménière, and it is broadly characterized by intermittent episodes of vertigo, fluctuating hearing loss, tinnitus and aural fullness.¹1 Sajjadi H, Paparella MM. Meniere's disease. Lancet 2008;372 (9636):406-414495 ²2 Meniere P. Maladies de l'oreille interne offrant des symptomes de la congestion cerebral apoplectiforme. Gaz Med de Paris 1961;16:88

Data concerning the incidence and prevalence of MD are scarce and uncertain.³3 da Costa SS, de Sousa LCA, Piza MR. Meniere's disease: overview, epidemiology, and natural history. Otolaryngol Clin North Am 2002;35(03):455-495 Prevalence estimates ranges from 10 to 150 per 100,000 individuals.⁴4 Schessel DA, Minor LB, Nedzelski J. Meniere's disease and other peripheral vestibular disorders. In: Gaertner RS, Murphy MB, ed. Cummings Otolaryngology Head and Neck Surgery. 4th ed. Philadelphia: Mosby; 2004:3231-3232 Most of the studies suggest a slight preponderance of the disease among women (1.3 women per each affected man).⁵5 da Costa SS. Central causes of vertigo. In: Souza SD, Claussen C, ed. Modern concepts of neurology. Mumbai: Prajakta Arts; 1997: 310-331 Ménière disease also seems more frequent among adults in their fourth or fifth decades of life and positive family history is extremely common.⁶6 Paparella MM, da Costa SS, Fox R, Yoo TH. Meniere's disease and other labyrinthine diseases. in: Paparella MM, Shumrick DA, Gluckmann J, Meyerhoff WL, ed. Otolaryngology. 3rd edn. WB Saunders, Philadelphia1991:1689-1714 ⁷7 Paparella MM. The cause (multifactorial inheritance) and pathogenesis (endolymphatic malabsorption) of Meniere's disease and its symptoms (mechanical and chemical). Acta Otolaryngol 1985; 99(3-4):445-451

The diagnosis of Ménière disease remains eminently clinical.⁸8 Harcourt J, Barraclough K, Bronstein AM. Meniere's disease. BMJ 2014;349:g6544 Its clinical presentation is widely variable. Many patients present with audiological symptoms, some have mostly vestibular complaints and others show a combination of audiovestibular manifestations.⁹9 Perez-Garrigues H, Lopez-Escamez JA, Perez P, et al. Time course of episodes of definitive vertigo in Meniere's disease. Arch Otolaryngol Head Neck Surg 2008;134(11):1149-1154 Bilateral involvement might be seen in 10–50% of the patients, leading to a difficult-to-treat condition with more disabling symptoms and unfavorable prognosis.¹⁰10 Balkany TJ, Sires B, Arenberg IK. Bilateral aspects of Meniere's disease: an underestimated clinical entity. Otolaryngol Clin North Am 1980;13(04):603-609 In 2015, the Classification Committee of the Bárány Society, the Japan Society for Equilibrium Research, the European Academy of Otology and Neurotology (EAONO), the Equilibrium Committee of the American Academy of Otolaryngology-Head and Neck Surgery (AAO-HNS) and the Korean Balance Society jointly revised the diagnostic criteria and established a new classification for MD.(Table 1)¹¹11 Lopez-Escamez JA, Carey J, ChungWH, et al; Classification Committee of the Barany Society; Japan Society for Equilibrium Research; European Academy of Otology and Neurotology (EAONO); Equilibrium Committee of the American Academy of Otolaryngology- Head and Neck Surgery (AAO-HNS); Korean Balance Society. Diagnostic criteria for Menière's disease. J Vestib Res 2015;25(01):1-7 These criteria remain as the main diagnostic tool for MD in clinical practice.

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Table 1
Diagnosis criteria and classification of Ménière disease according to the Classification Committee of the Bárány Society, the Japan Society for Equilibrium Research, the European Academy of Otology and Neurotology (EAONO), the Equilibrium Committee of the American Academy of Otolaryngology-Head and Neck Surgery (AAO-HNS) and the Korean Balance Society¹¹11 Lopez-Escamez JA, Carey J, ChungWH, et al; Classification Committee of the Barany Society; Japan Society for Equilibrium Research; European Academy of Otology and Neurotology (EAONO); Equilibrium Committee of the American Academy of Otolaryngology- Head and Neck Surgery (AAO-HNS); Korean Balance Society. Diagnostic criteria for Menière's disease. J Vestib Res 2015;25(01):1-7

However, some authors report that evidences of endolymphatic hydrops, obtained in particular complementary investigation methods with growing sensibility and specificity, might be helpful in patients with MD in its early stage or those with mild and non-specific symptoms.

The possibility of clinical implications of the anatomical variations of the temporal bone among patients with MD has been targeted in some studies. Recent technological advances, unique special resolution and wide availability have made high resolution computed tomography (HRCT) of the temporal bone the main imaging modality in otology.¹²12 Jackler RK, Dillon WP, Schindler RA. Computed tomography in suppurative ear disease: a correlation of surgical and radiographic findings. Laryngoscope 1984;94(06):746-752 High resolution computed tomography is capable of detecting anatomical correlations between the structures of the inner ear, including surrounding vascular components. As a result, it can define, with high sensibility and specificity rates, anatomical variations which, among patients with MD, might serve as clinical markers that could underpin the diagnosis of this condition or play a role in its pathophysiology.

No radiological sign is deemed specific for MD. Previous studies have shown higher prevalence of some anatomical variations in the temporal bones of affected individuals, although they vary significantly in terms of the variables evaluated, the radiological method employed and the stratification of the sample. Yet, there are few researches including patients with bilateral MD.

This present study aims to identify anatomical variations of the temporal bone which might be associated with unilateral and/or bilateral MD.

Methods

This is a case-control study. All included participants (n= 37) attended ambulatories of otoneurology in a public tertiary hospital and a specialized clinic in Curitiba, Brazil, and underwent a computed tomography (CT) of the temporal bone as a complementary evaluation. For the study, each ear was considered separately (n_final= 74). Hence, a case group (group A, n_A= 33) consisted of the affected ears of patients with clinical diagnosis of unilateral or bilateral MD, according to the new criteria proposed by international societies in 2015, which includes, by definition, suggestive and audiometrically documented hearing loss. A control group (group B, n_B= 41) included the ears of individuals attending the same clinics, although without criteria for either probable or definite MD and presenting a normal audiometry, as well as the contralateral ears of the patients with unilateral MD included in the case group. Patients under 18 years of age or with history of inflammatory otitis media, temporal bone neoplasm or trauma, congenital ear anomalies or previous otologic surgery were excluded from the sample. All included participants signed a free and informed consent form. The project was approved and registered by the Institutional Ethics Committee (CAAE number, 54235316.9.0000.0096).

The tomographic images were obtained in a matrix of 512 × 512 pixels, in high resolution, between 2014 and 2016. The HRCT scans provided volumetric images in the axial plane, which were transferred to a workstation for post-processing. These data were reformatted in the axial and coronal planes using specific software, yielding images with 1 mm section thickness on each side individually.

Clinical and epidemiological data were collected from the participants and their images were assessed by a single radiologist specialized in temporal bone evaluation, without previous knowledge of their clinical history or physical examination. Anatomical aspects regarding region-specific temporal bone pneumatization, the jugular bulb and the positioning and structure of the cochlear and vestibular aqueducts were systematically analyzed. (Table 2, Fig. 1)

Fig. 1
Computed axial tomography images showing anatomical variations of the temporal bone: (A) High jugular bulb, above the level of the tympanic annulus (arrow); (B) Jugular bulb diverticulum (arrow); (C) Contact between the jugular bulb and the vestibular aqueduct (arrow); (D) Asymmetric pneumatization of the retrolabyrinthine space, deemed increased on the right (D1) and decreased on the left side (D2) (arrow). Source: the author.

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Table 2
Variables individually investigated in each ear of this study's sample

The results from the case and control groups were confronted. A secondary assessment of the case group was performed after its stratification into two subgroups: one (A1, n_A1= 13) composed by the affected ears of patients with unilateral MD and another by the ears of those with bilateral disease (A2, n_A2= 20). The control group was also divided into two subgroups, which had their data compared as well: one (B1, n_B1= 13) formed by asymptomatic contralateral ears of individuals with unilateral MD and another (B2, n_B2= 28) consisting of individuals without MD and normal audiometric evaluation. (Fig. 2). Results from subgroups A1 and B1 were also confronted.

Fig. 2
Study flow chart.

The Pearson chi-square and Fisher exact tests were employed to evaluate categorical variables. Continuous variables were assessed using the Wilcoxon-Mann-Whitney. Statistical analysis was performed using the Statistical Package for Social Science (SPSS). Significance level was set at 0.05.

Results

There was no statistical difference between the study groups in terms of age or sex (p> 0.05, data not shown).

The comparison between the results from the case (A) and control (B) groups is summarized in Fig. 3. There was a significant correlation between MD in only one of the variables assessed: capacity of individualization of the vestibular aqueduct (VA). Among patients with MD, this structure was observed less frequently (p= 0.01; Fisher exact test).

Fig. 3
Values (p) for each assessed variable resultant from comparative statistical analysis between the main study groups, case (A) and control (B). Significance level: p-value < 0.05.

Table 3 shows the statistical significance level obtained when analyzing subgroups A1 and A2, which were composed by the affected ears of patients with unilateral and bilateral MD, respectively. None of the variables was significantly associated with the occurrence of bilateral disease (p< 0.05).

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Table 3
A summary of statistical data (p-value) obtained for each variable after assessing both case subgroups. Comparison between data of affected ears from patients with unilateral disease (subgroup A1) and those of individuals with bilateral disease (subgroup A2)

The results from the statistical analysis between subgroups consisting of the affected (A1) and healthy contralateral (B1) ears of patients with MD are provided in Table 4. Similarly, there was no significant difference for any of the variables investigated.

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Table 4
A summary of statistical data (p-value) obtained for each variable when comparing the results of affected ears from patients with unilateral Ménière disease (subgroup A1) and those of the contralateral ears of these individuals. (subgroup B1)

Fig. 4 reports statistical data regarding the results when comparing the control subgroups (B1 and B2). There was a trend toward lower angulation between the vestibular aqueduct and the vestibule in the contralateral ears of patients with unilateral disease, when compared with the ears of individuals without MD (p= 0.11). Nonetheless, none of the variables reached statistical significance (p< 0.05).

Fig. 4
Results obtained after stratifying the control group: p-value associated with each variable, when comparing the results from the contralateral ears of patients with unilateral MD (subgroup B1) and those from individuals without the disease (subgroup B2). Significance level: p-value < 0.05.

Discussion

One previous study has suggested that the sigmoid sinus could be placed significantly more anteriorly and medially in patients with MD. The authors hypothesized that the anomalous position of the vessel could generate compression of the endolymphatic sac and, therefore, hydrops.¹³13 Paparella MM, Sajjadi H. The significance of the lateral sinus in Meniere's disease. in: J Nadol, ed. Proceedings of the 2nd International Symposium on Meniere's Disease, pathogenesis, pathophysiology, diagnosis and treatment. Kugler & Ghedini Publishers, Amsterdam; 1989:139-146

The jugular bulb consists of a dilation of the internal jugular vein and is located at the posterior part of the jugular foramen. When enlarged, it might be responsible for audiovestibular symptoms.¹⁴14 Brook CD, Buch K, Kaufmann M, Sakai O, Devaiah AK. The Prevalence of High-Riding Jugular Bulb in Patients with Suspected Endolymphatic Hydrops. J Neurol Surg B Skull Base 2015;76(06):471-474 Variations in its size and location are common and might occur due to malformations in the surrounding bony structure or in the intracranial venous system itself or secondary to lack of pneumatization of the mastoid portion of the temporal bone. If the jugular bulb is located superiorly to the inferior surface of the tympanic annulus in the middle ear, at the level of the basal cochlear turn or less than 2 mm from the inner auditory channel, it is classified as a high jugular bulb (HJB).¹⁵15 Wadin K, Thomander L,Wilbrand H. Effects ofa highjugular fossa and jugular bulb diverticulum on the inner ear. A clinical and radiologic investigation. Acta Radiol Diagn (Stockh) 1986;27(06):629-636 ¹⁶16 Rauch SD, XuWZ, Nadol JB Jr. High jugular bulb: implications for posterior fossa neurotologic and cranial base surgery. Ann Otol Rhinol Laryngol 1993;102(02):100-107 Most of the previous studies that aimed to evaluate HJB have shown limitations, such as emphasis on its incidence or small samples.¹⁷17 Woo CK, Wie CE, Park SH, Kong SK, Lee IW, Goh EK. Radiologic analysis of high jugular bulb by computed tomography. Otol Neurotol 2012;33(07):1283-1287 Radiological and post-mortem studies of the temporal bone report a prevalence of HJB ranging from 3–24% of the population, although this variation might not be clinically apparent.¹⁵15 Wadin K, Thomander L,Wilbrand H. Effects ofa highjugular fossa and jugular bulb diverticulum on the inner ear. A clinical and radiologic investigation. Acta Radiol Diagn (Stockh) 1986;27(06):629-636 ¹⁷17 Woo CK, Wie CE, Park SH, Kong SK, Lee IW, Goh EK. Radiologic analysis of high jugular bulb by computed tomography. Otol Neurotol 2012;33(07):1283-1287 ¹⁸18 Vachata P, Petrovicky P, Sames M. An anatomical and radiological study of the high jugular bulb on high-resolution CT scans and alcohol-fixed skulls of adults. J Clin Neurosci 2010;17(04): 473-478 ¹⁹19 Kuhn MA, Friedmann DR, Winata LS, et al. Large jugular bulb abnormalities involving the middle ear. Otol Neurotol 2012;33 (07):1201-1206 Jugular bulb abnormalities have also been implied in a various range of cochleovestibular symptoms, depending on the impact on the surrounding structures. The jugular bulb might erode into the middle ear or into the cochlear or vestibular aqueducts. Hearing loss, vertigo and tinnitus have also been attributed to high and dehiscent jugular bulbs, as well as to the compressive effects of HJB on the endolymphatic sac.¹⁸18 Vachata P, Petrovicky P, Sames M. An anatomical and radiological study of the high jugular bulb on high-resolution CT scans and alcohol-fixed skulls of adults. J Clin Neurosci 2010;17(04): 473-478 ²⁰20 Friedmann DR, Eubig J, Winata LS, Pramanik BK, Merchant SN, Lalwani AK. Prevalence of jugular bulb abnormalities and resultant inner ear dehiscence: a histopathologic and radiologic study. Otolaryngol Head Neck Surg 2012;147(04):750-756 A recent German retrospective controlled study has shown a significantly higher prevalence of jugular bulb abnormalities among patients with MD. The authors concluded that the temporal bone in these individuals might be constitutionally different and carry predisposing factors for the development of clinically overt MD.²¹21 Park JJ, Shen A, Keil S, Kuhl C, Westhofen M. Jugular bulb abnormalities in patients with Meniere's disease using highresolution computed tomography. Eur Arch Otorhinolaryngol 2015;272(08):1879-1884 Redfern et al have also described higher prevalence of abnormalities of the jugular bulb in patients with MD, when compared with the general population.²²22 Redfern RE, Brown M, Benson AG. High jugular bulb in a cohort of patientswith definiteMénière's disease. J Laryngol Otol 2014;128 (09):759-764 In the present study, differences in the prevalence of HJB or major jugular bulb abnormalities among affected ears have not been found.

Ikeda e Sando have shown in a study with post-mortem temporal bones that patients with MD have smaller tube-shaped endolymphatic ducts, in contrast with normal subjects, whose ducts were bigger and funnel-shaped.²³23 Ikeda M, Sando I. Endolymphatic duct and sac in patients with Meniere's disease. A temporal bone histopathological study. Ann Otol Rhinol Laryngol 1984;93(6 Pt 1):540-546 Welling et al reported that, in MD, the identification of the endolymphatic duct on magnetic resonance imaging (MRI) could be significantly less frequent compared with controls. In this study, the authors also compared the measurements of the temporal bone in the region of the endolymphatic duct and found smaller dimensions among affected individuals.²⁴24 Welling DB, Clarkson MW, Miles BA, et al. Submillimeter magnetic resonance imaging of the temporal bone in Meniere's disease. Laryngoscope 1996;106(11):1359-1364 By using a systematic approach to the evaluation of CT scans, Alvarenga et al achieved identification rates of the vestibular aqueduct superior to 90% among both ears of patients with unilateral MD. The rates did not differ statistically from those of control individuals.²⁵25 Alvarenga EHL, Cruz OLM, Yamashita HKL, Lima EJ, Alvarenga AM, Bisinoto SMB. Sistematização do estudo anatômico do aqueduto vestibular por tomografia computadorizada de alta resolução em pacientes com doenças de Ménière unilateral. Radiol Bras 2006; 39(05):345-349 In the present study, among affected ears, there was a significantly greater number of CT scans in which the vestibular aqueduct could not be individualized (p= 0.01). However, considering only the exams in which this structure was identified, the absolute measurements did not differ from those of the control arm. No statistically significant difference between the study groups was obtained regarding either the position of the internal aperture or the inclination of the vestibular aqueduct. Rates of identification of the cochlear aqueduct were also similar. As to the assessment of pneumatization of different portions of the temporal bone, a trend to reduced (p= 0.07, Pearson chi-square test) pneumatization of the retrolabyrinthine space was observed among subjects with MD, although this result could not be deemed statistically significant. No difference was demonstrated in the pneumatization of the petrous apex, infralabyrinthine and supralabyrinthine spaces.

Previous functional studies have shown the presence of abnormal findings in the contralateral ears of patients with unilateral MD.²⁶26 Conlon BJ, Gibson WPR. Meniere's disease: the incidence of hydrops in the contralateral asymptomatic ear. Laryngoscope 1999;109(11):1800-1802 ²⁷27 Brookes GB, Morrison AW, Richard R. Unilateral Meniere's disease: is the contralateral ear normal? Am J Otol 1985;6(06): 495-499 These findings have been corroborated by histopathologic studies, which have identified significantly more damage in the contralateral inner ears of patients with MD compared with those of normal controls.²⁸28 Kariya S, Cureoglu S, Fukushima H, et al. Histopathologic changes of contralateral human temporal bone in unilateral Ménière's disease. Otol Neurotol 2007;28(08):1063-1068 The incidence of functional contralateral involvement and development of clinically apparent bilateral MD increases linearly, so that after 30 years of follow-up, up to 50% of the patients have bilateral disease.²⁹29 Friberg U, Stahle J, Svedberg A. The natural course of Meniere's disease. Acta Otolaryngol Suppl 1984;406:72-77 Increasing evidence of endolymphatic hydrops in asymptomatic contralateral ears might suggest that MD is a systemic disease.³⁰30 Gürkov R, Pyykö I, Zou J, Kentala E. What is Menière's disease? A contemporary re-evaluation of endolymphatic hydrops. J Neurol 2016;263(Suppl 1):S71-S81 ³¹31 Pyykkö I, Nakashima T, Yoshida T, Zou J, Naganawa S. Meniere's disease: a reappraisal supported by a variable latency of symptoms and the MRI visualisation of endolymphatic hydrops. BMJ Open 2013;3(02):e001555 Hence, the recurrent findings in the literature of abnormal anatomical features among both affected and contralateral ears in comparison to normal controls might indicate that MD has a complex pathophysiology, in which the anatomical component might be a marker of disease progression or a contributing factor. Accordingly, the previous existence or the development during follow-up of certain anatomical abnormalities in the asymptomatic contralateral ear could predispose the patient to the progression to bilateral disease, with an unfavorable prognosis. Karatas et al studied the size and width of the endolymphatic duct and the presence of jugular bulb abnormalities in the CT scans of patients with unilateral MD. In this study, the measurements for the endolymphatic duct were reported to be smaller and the prevalence of abnormalities of the jugular bulb was higher among MD patients when compared with healthy controls. However, for none of the variables, there was a significant difference between the results of affected and contralateral non-affected ears.³²32 Karatas A, Kocak A, Cebi IT, Salviz M. Comparison of Endolymphatic Duct Dimensions and Jugular Bulb Abnormalities Between Meniere Disease and a Normal Population. J Craniofac Surg 2016; 27(05):e424-e426 Hall et al also described lower periaqueductal pneumatization rates in the CT scans of patients with MD. Similarly, in this study, the results from the contralateral ears did not differ from those of the affected ears.³³33 Hall SF, O'Connor AF, Thakkar CH, Wylie IG, Morrison AW. Significance of tomography in Meniere's disease: periaqueductal pneumatization. Laryngoscope 1983;93(12):1551-1553 Using MRI and CT to evaluate the cochlear aqueduct, Park et al found similar bony dimensions among the affected ears of patients with MD when compared with a control group, although fluid length within this structure was significantly decreased among case subjects. These findings could not be reproduced when comparing the affected and non-affected ears of patients with MD.³⁴34 Park JJ, Shen A, Keil S, Kraemer N, Westhofen M. Radiological findings of the cochlear aqueduct in patients with Meniere's disease using high-resolution CT and high-resolution MRI. Eur Arch Otorhinolaryngol 2014;271(12):3325-3331

In this work, no statistically significant difference in the prevalence of any anatomical variations was observed when comparing the affected ears of individuals with unilateral MD with those of patients with bilateral MD. Thus, the anatomical factor, if important in MD's pathophysiology and/or diagnosis approach, might contribute independently of the existence of involvement of both ears. There was no difference when comparing the results from the affected and the contralateral non-affected ears of patients with unilateral MD and from these contralateral non-affected ears with the ears of healthy controls. This finding would indicate that the contralateral ears did not differ from the affected ears or from the ears of healthy subjects. Longitudinal and cohort studies might determine more precisely the meaning of these results, as the possibility of progression of unilateral MD to bilateral disease is well known. Thereby, it would be necessary to better stratify contralateral ears longitudinally and check the occurrence of dynamic alterations in the anatomical findings reported according to the progression of the disease. As a result, it might be possible to establish the role of the anatomical variations as markers of disease progression or risk factors for the development of bilateral MD, in case of significant identification of these variations, late or precociously in the follow-up of contralateral ears that would become affected over time. Experimental and histopathological studies might define more clearly the existence of pathophysiological links between anatomical factors and the incidence of MD, which remain elusive.

Conclusion

Some anatomical variations of the temporal bone might be more frequently found in routine CT scans from affected ears of patients with MD, such as the lower rates of individualization of the vestibular aqueduct. Nonetheless, according to the literature,²⁵25 Alvarenga EHL, Cruz OLM, Yamashita HKL, Lima EJ, Alvarenga AM, Bisinoto SMB. Sistematização do estudo anatômico do aqueduto vestibular por tomografia computadorizada de alta resolução em pacientes com doenças de Ménière unilateral. Radiol Bras 2006; 39(05):345-349 the use of the imaging study of the vestibular aqueduct as a supportive diagnostic tool and the role of correlated anatomical variations in the development of MD remain a controversial issue. Longitudinal controlled studies including patients with anatomical variations possibly related to MD might be important to observe if they develop the disease more frequently over time.

References

¹
Sajjadi H, Paparella MM. Meniere's disease. Lancet 2008;372 (9636):406-414495
²
Meniere P. Maladies de l'oreille interne offrant des symptomes de la congestion cerebral apoplectiforme. Gaz Med de Paris 1961;16:88
³
da Costa SS, de Sousa LCA, Piza MR. Meniere's disease: overview, epidemiology, and natural history. Otolaryngol Clin North Am 2002;35(03):455-495
⁴
Schessel DA, Minor LB, Nedzelski J. Meniere's disease and other peripheral vestibular disorders. In: Gaertner RS, Murphy MB, ed. Cummings Otolaryngology Head and Neck Surgery. 4th ed. Philadelphia: Mosby; 2004:3231-3232
⁵
da Costa SS. Central causes of vertigo. In: Souza SD, Claussen C, ed. Modern concepts of neurology. Mumbai: Prajakta Arts; 1997: 310-331
⁶
Paparella MM, da Costa SS, Fox R, Yoo TH. Meniere's disease and other labyrinthine diseases. in: Paparella MM, Shumrick DA, Gluckmann J, Meyerhoff WL, ed. Otolaryngology. 3rd edn. WB Saunders, Philadelphia1991:1689-1714
⁷
Paparella MM. The cause (multifactorial inheritance) and pathogenesis (endolymphatic malabsorption) of Meniere's disease and its symptoms (mechanical and chemical). Acta Otolaryngol 1985; 99(3-4):445-451
⁸
Harcourt J, Barraclough K, Bronstein AM. Meniere's disease. BMJ 2014;349:g6544
⁹
Perez-Garrigues H, Lopez-Escamez JA, Perez P, et al. Time course of episodes of definitive vertigo in Meniere's disease. Arch Otolaryngol Head Neck Surg 2008;134(11):1149-1154
¹⁰
Balkany TJ, Sires B, Arenberg IK. Bilateral aspects of Meniere's disease: an underestimated clinical entity. Otolaryngol Clin North Am 1980;13(04):603-609
¹¹
Lopez-Escamez JA, Carey J, ChungWH, et al; Classification Committee of the Barany Society; Japan Society for Equilibrium Research; European Academy of Otology and Neurotology (EAONO); Equilibrium Committee of the American Academy of Otolaryngology- Head and Neck Surgery (AAO-HNS); Korean Balance Society. Diagnostic criteria for Menière's disease. J Vestib Res 2015;25(01):1-7
¹²
Jackler RK, Dillon WP, Schindler RA. Computed tomography in suppurative ear disease: a correlation of surgical and radiographic findings. Laryngoscope 1984;94(06):746-752
¹³
Paparella MM, Sajjadi H. The significance of the lateral sinus in Meniere's disease. in: J Nadol, ed. Proceedings of the 2nd International Symposium on Meniere's Disease, pathogenesis, pathophysiology, diagnosis and treatment. Kugler & Ghedini Publishers, Amsterdam; 1989:139-146
¹⁴
Brook CD, Buch K, Kaufmann M, Sakai O, Devaiah AK. The Prevalence of High-Riding Jugular Bulb in Patients with Suspected Endolymphatic Hydrops. J Neurol Surg B Skull Base 2015;76(06):471-474
¹⁵
Wadin K, Thomander L,Wilbrand H. Effects ofa highjugular fossa and jugular bulb diverticulum on the inner ear. A clinical and radiologic investigation. Acta Radiol Diagn (Stockh) 1986;27(06):629-636
¹⁶
Rauch SD, XuWZ, Nadol JB Jr. High jugular bulb: implications for posterior fossa neurotologic and cranial base surgery. Ann Otol Rhinol Laryngol 1993;102(02):100-107
¹⁷
Woo CK, Wie CE, Park SH, Kong SK, Lee IW, Goh EK. Radiologic analysis of high jugular bulb by computed tomography. Otol Neurotol 2012;33(07):1283-1287
¹⁸
Vachata P, Petrovicky P, Sames M. An anatomical and radiological study of the high jugular bulb on high-resolution CT scans and alcohol-fixed skulls of adults. J Clin Neurosci 2010;17(04): 473-478
¹⁹
Kuhn MA, Friedmann DR, Winata LS, et al. Large jugular bulb abnormalities involving the middle ear. Otol Neurotol 2012;33 (07):1201-1206
²⁰
Friedmann DR, Eubig J, Winata LS, Pramanik BK, Merchant SN, Lalwani AK. Prevalence of jugular bulb abnormalities and resultant inner ear dehiscence: a histopathologic and radiologic study. Otolaryngol Head Neck Surg 2012;147(04):750-756
²¹
Park JJ, Shen A, Keil S, Kuhl C, Westhofen M. Jugular bulb abnormalities in patients with Meniere's disease using highresolution computed tomography. Eur Arch Otorhinolaryngol 2015;272(08):1879-1884
²²
Redfern RE, Brown M, Benson AG. High jugular bulb in a cohort of patientswith definiteMénière's disease. J Laryngol Otol 2014;128 (09):759-764
²³
Ikeda M, Sando I. Endolymphatic duct and sac in patients with Meniere's disease. A temporal bone histopathological study. Ann Otol Rhinol Laryngol 1984;93(6 Pt 1):540-546
²⁴
Welling DB, Clarkson MW, Miles BA, et al. Submillimeter magnetic resonance imaging of the temporal bone in Meniere's disease. Laryngoscope 1996;106(11):1359-1364
²⁵
Alvarenga EHL, Cruz OLM, Yamashita HKL, Lima EJ, Alvarenga AM, Bisinoto SMB. Sistematização do estudo anatômico do aqueduto vestibular por tomografia computadorizada de alta resolução em pacientes com doenças de Ménière unilateral. Radiol Bras 2006; 39(05):345-349
²⁶
Conlon BJ, Gibson WPR. Meniere's disease: the incidence of hydrops in the contralateral asymptomatic ear. Laryngoscope 1999;109(11):1800-1802
²⁷
Brookes GB, Morrison AW, Richard R. Unilateral Meniere's disease: is the contralateral ear normal? Am J Otol 1985;6(06): 495-499
²⁸
Kariya S, Cureoglu S, Fukushima H, et al. Histopathologic changes of contralateral human temporal bone in unilateral Ménière's disease. Otol Neurotol 2007;28(08):1063-1068
²⁹
Friberg U, Stahle J, Svedberg A. The natural course of Meniere's disease. Acta Otolaryngol Suppl 1984;406:72-77
³⁰
Gürkov R, Pyykö I, Zou J, Kentala E. What is Menière's disease? A contemporary re-evaluation of endolymphatic hydrops. J Neurol 2016;263(Suppl 1):S71-S81
³¹
Pyykkö I, Nakashima T, Yoshida T, Zou J, Naganawa S. Meniere's disease: a reappraisal supported by a variable latency of symptoms and the MRI visualisation of endolymphatic hydrops. BMJ Open 2013;3(02):e001555
³²
Karatas A, Kocak A, Cebi IT, Salviz M. Comparison of Endolymphatic Duct Dimensions and Jugular Bulb Abnormalities Between Meniere Disease and a Normal Population. J Craniofac Surg 2016; 27(05):e424-e426
³³
Hall SF, O'Connor AF, Thakkar CH, Wylie IG, Morrison AW. Significance of tomography in Meniere's disease: periaqueductal pneumatization. Laryngoscope 1983;93(12):1551-1553
³⁴
Park JJ, Shen A, Keil S, Kraemer N, Westhofen M. Radiological findings of the cochlear aqueduct in patients with Meniere's disease using high-resolution CT and high-resolution MRI. Eur Arch Otorhinolaryngol 2014;271(12):3325-3331

Note

This paper has been chosen to be presented in the IFOSENT World Congress, which was held in Paris, in June of 2017.

Publication Dates

Publication in this collection
Jul-Sep 2018

History

Received
18 Apr 2017
Accepted
09 June 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[31] ³¹
Pyykkö I, Nakashima T, Yoshida T, Zou J, Naganawa S. Meniere's disease: a reappraisal supported by a variable latency of symptoms and the MRI visualisation of endolymphatic hydrops. BMJ Open 2013;3(02):e001555

[32] ³²
Karatas A, Kocak A, Cebi IT, Salviz M. Comparison of Endolymphatic Duct Dimensions and Jugular Bulb Abnormalities Between Meniere Disease and a Normal Population. J Craniofac Surg 2016; 27(05):e424-e426

[33] ³³
Hall SF, O'Connor AF, Thakkar CH, Wylie IG, Morrison AW. Significance of tomography in Meniere's disease: periaqueductal pneumatization. Laryngoscope 1983;93(12):1551-1553

[34] ³⁴
Park JJ, Shen A, Keil S, Kraemer N, Westhofen M. Radiological findings of the cochlear aqueduct in patients with Meniere's disease using high-resolution CT and high-resolution MRI. Eur Arch Otorhinolaryngol 2014;271(12):3325-3331

Anatomical Aspect	Categories/Unity of Measurement for the Variable
Categorical Variables
Height of the jugular bulb considering the basal turn of the cochlea	High or normal
Presence of any of the major anatomical variations of the jugular bulb: diverticulum, dehiscence to the middle ear or otic capsule, contact with cochlear or vestibular aqueducts	Present or absent
Position of the aperture opening of the vestibular aqueduct	Above or below the basal turn of the cochlea
Individualization of the cochlear aqueduct	More or less than half of its extension
Pneumatization of the retrolabyrinthine space	Absent/decreased or increased
Pneumatization of the supralabyrinthine space	Absent/decreased or increased
Pneumatization of the infralabyrinthine space	Absent/decreased or increased
Pneumatization of the petrous apex	Absent/decreased or increased
Continuous Variables
Anteroposterior diameter of the jugular bulb	In millimeters (mm)
Transverse diameter of the jugular bulb	In millimeters (mm)
Size of the vestibular aqueduct (if visible)	In millimeters (mm))
Inclination angle between the vestibular aqueduct and the vestibule	In grades (^o)

Variable	p-value
Presence of high jugular bulb	0.41 (χ²)
Anteroposterior diameter of the jugular bulb	0.41 (WCX)
Transverse diameter of the jugular bulb	0.17 (WCX)
Overall incidence of major variations of the jugular bulb	0.63 (Fisher)
Rate of visualization of the vestibular aqueduct	0.13 (Fisher)
Size of the vestibular aqueduct (if visible)	1.0 (WCX)
Position of the aperture opening of the vestibular aqueduct	1.0 (Fisher)
Inclination angle between the vestibular aqueduct and the vestibule	0.57 (WCX)
Grade of visualization of the cochlear aqueduct	1.0 (Fisher)
Pneumatization of the infralabyrinthine space	0.73 (Fisher)
Pneumatization of the retrolabyrinthine space	0.21 (Fisher)
Pneumatization of the supralabyrinthine space	1.0 (Fisher)
Pneumatization of the petrous apex	1.0 (Fisher)

Variable	p-value
Presence of high jugular bulb	1.0 (χ²)
Anteroposterior diameter of the jugular bulb	0.82 (WCX)
Transverse diameter of the jugular bulb	0.45 (WCX)
Overall incidence of major variations of the jugular bulb	0.66 (Fisher)
Rate of visualization of the vestibular aqueduct	1.0 (Fisher)
Size of the vestibular aqueduct (if visible)	0.48 (WCX)
Position of the aperture opening of the vestibular aqueduct	1.0 (Fisher)
Inclination angle between the vestibular aqueduct and the vestibule	0.96 (WCX)
Grade of visualization of the cochlear aqueduct	1.0 (Fisher)
Pneumatization of the infralabyrinthine space	0.69 (Fisher)
Pneumatization of the retrolabyrinthine space	1.0 (Fisher)
Pneumatization of the supralabyrinthine space	1.0 (Fisher)
Pneumatization of the petrous apex	1.0 (Fisher)

Brasil

Brasil

Anatomical Variations in Patients with Ménière Disease: A Tomography Study

Abstract

Introduction

Objective

Methods

Results

Conclusion

Introduction

Methods

Results

Discussion

Conclusion

References

Note

Publication Dates

History