Sennaroğlu and Bajin’s description of the findings of abnormalities involving inner ear structures.
Abstract
The last decade has witnessed significant advances in imaging of the middle and inner ear and the auditory pathways. High resolution computerized tomography (CT) scanners and new magnetic resonance (MR) sequences have been implemented in clinical practice as valuable supportive tools for the Audiologist in the identification of the site of lesion and for the surgical planning by the Otologist. The purpose of this chapter is to review the current advanced methods of neuroradiological evaluation of patients with sensorineural hearing loss (SNHL), either congenital or acquired, especially focusing on the assessment of candidates to cochlear implantation (CI), with plenty of explicative images.
Keywords
- sensorineural hearing loss
- congenital inner ear malformations
- acquired inner ear disorders
- flat panel CT
- high-resolution MR-sequences
1. Introduction
The imaging assessment of the inner ear and the auditory pathway requires high-resolution techniques because their anatomical structures are small and complex. In the last 10 years, computed tomography (CT) and magnetic resonance (MR) has reached much higher spatial resolution for bony and neural structures.
Multi-section CT (MSCT) is the technique of choice for the study of the temporal bone, thanks to its high spatial resolution. However flat panel CT (FPCT) constitutes the newest alternative technique, since it guarantees some additional advantage compared with MSCT in terms of ultra-high isotropic spatial resolution (~150 × 150 × 150 μm3) and reduction of the effective dose of up to 40% [1, 2, 3].
On the other hand, 3 Tesla MR scanners, thanks to the high-resolution sequences such as tridimensional (3D) T2 weighted sequence (3D-T2w, spatial resolution: 0.4 × 0.4 × 0.6 mm3, field of view: 140 × 140 mm, time of scan: 5′ 32″) and 3D Fluid Attenuated Inversion Recovery (FLAIR), have provided new insight to detect changes in the inner ear [4, 5]. MR is technique of choice to study the peripheral and central auditory pathways.
The purposes of this chapter is to review the state of the art of pre-operative neuroradiological assessments of patients with sensorineural hearing loss (SNHL) especially focusing on candidates to a cochlear implant (CI). Advanced imaging of the morphology and the integrity of anatomical structures will be presented in order to show the current capabilities of correct site of lesion identification.
2. Inner ear and cochlear-vestibular nerve
2.1 Congenital disorders
Inner ear can be affected by malformative and acquired anomalies, which can cause profound to severe hearing impairment. FPCT scan is more accurate than conventional MSCT in the morphologic evaluation of inner ear; FPCT allows an excellent examination of the 32-mm spiral canal of the snail-shaped cochlea, that winds 2 and ½ turns around the modiolus. These turns are separated by interscalar septa, where defects of it and of the modiolus can describe different types of incomplete partition of the cochlea. Sennaroğlu and Bajin summarized the findings of abnormalities involving each inner ear structure, as described in Table 1 [6].
Type of IEM | Radiological findings |
---|---|
Complete labyrinthine aplasia | Absent labyrinth |
Rudimentary otocyst | Incomplete millimetric otic capsule remnant |
Cochlear aplasia | Absent cochlea |
Common cavity | Round or ovoid cystic structure for cochlea and vestibule |
Cochlear hypoplasia | Cochlear size small |
Incomplete partition—I | Cystic cochlea |
Incomplete partition—II | Cystic cochlea apex |
Incomplete partition—III | Modiolus absent, interscalar septa present |
Enlarged vestibular aqueduct | Normal cochlea with enlarged vestibular aqueduct |
Cochlear acqueduct abnormalities | Narrow or absent cochlear acqueduct |
The most common cochlea anomalies are incomplete partition type I (IP-I) and incomplete partition type II (IP-II). In the IP-I, the cochlea results in a cystic appearance, due to the lack of the entire modiolus and the cribriform area, associated with a large cystic vestibule. In the IP-II (classic Mondini deformity), the cochlea forms a cystic apex, due to the coalescence of the middle and the apical turns, accompanied by a dilated vestibule and enlarged vestibular aqueduct (Figure 1). A rare disorder associated with congenital mixed hearing loss is incomplete partition type III, an X-Linked inner ear anomaly, caused by the absence of the bony modiolus and of the septum between the base of the cochlea and the internal auditory canal, with no associated anomalies in the vestibular structures of the inner ear (Figure 2) [6, 7]. This anomaly is associated with fixed stapes footplate, which represents a surgical risk of perilymph gusher during stapedectomy, and it represents even a risk of misdirected insertion of the cochlear electrode through the internal acoustic canal, inside the cerebellopontine angle against the brain stem, during cochlear implantation (Figure 3).
Cochlear malformations can be accompanied by anomalies of the vestibule or of the semicircular canals, resulting in aplasia, hypoplasia or dilatation [8].
Another cause of SNHL is the presence of enlarged vestibular aqueduct described as larger than 1.5 mm at the midpoint in the axial plane between the common crus and the external aperture, associated with a normal cochlea, vestibule and semicircular canals [8]. The Pöschl projection improves the accuracy in the measurement of the aqueduct. It is defined as 45° from either the sagittal or coronal planes or perpendicular to the long axis of the pyramid, or parallel to the superior semicircular canal (Figure 4) [9].
Enlarged vestibular aqueduct, accompanied by enlarged endolymphatic sac, can be associated with other cochlear and vestibular anomalies, which can affect therapeutic strategies: scalar asymmetry with enlargement of anterior chamber composed of the scala vestibuli and the scala media, or modiolar deficiency that shows a flattened and attenuated modiolus, well evaluated in 3D-T2w (Figure 5).
It is important to identify the atresia or the hypoplasia of the cochlear canal, by measuring the length and the width of the bony canal of the cochlear nerve, respectively obtained by drawing a perpendicular line from the base of the modiolus to the inner margin of the fundus of the internal auditory canal (IAC) and by drawing a line along the inner bony margins (Figure 6). The measurements can detect a hypoplastic bony canal, which may be indicative of a embryologic malformation of the cochlear-vestibular nerve (CVN), in patients with congenital SNHL [10, 11, 12].
The presence of aplasia or hypoplasia of the CVN must be ruled out since may affect the choice of surgical technique and CI device, as well as the performance outcome following CI; in patients whose cochlear nerves are missing, an auditory brain stem implant should be considered [13].
The presence of a normal cochlea does not exclude the agenesis of the cochlear nerve because of the different embryogenesis of the otic labyrinth and its neural elements. Nevertheless the cochlear nerve malformations are often associated with labyrinthine abnormalities [10]. As mentioned above, the hypoplasia of the cochlear canal seen on CT scan is a sensitive indicator of CVN malformation: in that case the CT evaluation should be always followed by MR examination since the 3D-T2w is the most valuable tool to assess nerves anomalies.
The relationship between the facial and the CVN within the IAC may vary among individuals (Figures 7 and 8).
2.2 Acquired disorders
Among acquired lesions in SNHL, the presence and the extension of a labyrinthine ossification represents another great challenge for the surgeon, owing to difficult insertion of the electrode array. It may occur like “end-stage” of different labyrinthine pathologies, categorized as infective or non-infective, including meningitis, otitis media, trauma, otosclerosis and labyrinthectomy. Fibrosis can precede ossification but extensive fibrosis without ossification rarely occurs. The stage of fibrosis begins ~2 weeks after the onset of infection, but CT images remains elusive. Instead, 3D-T2w demonstrates replacement of the normally fluid-filled spaces of the labyrinth, resulting in reduced T2w signal and shows the presence of labyrinthine enhancement after gadolinium. MR images have the advantage of not only diagnosing cochlear obstruction, but even better sensitivity for estimating the extent of fibrous obstruction, subtle at CT images, thus allowing earlier diagnosis (Figures 9 and 10) [14].
The end stage of the ossification results in the absence of T2w signal of the labyrinth; this stage is also well seen from CT images (Figure 11).
Reduced T2w signal is reported in vestibular schwannoma, up to 10–20% of the causes of SNHL, but it always results in intralabyrinthine contrast enhancement (Figure 12).
The management of far advanced otosclerosis may represent another important objective in the era of CI [15]. In the original otosclerosis, the aberrant bone deposition around the stapes footplate results in the impairment of the mechanical transmission of sound, leading to conductive hearing loss. In advanced otosclerosis, bone deposits can extend into the bony labyrinth of the inner ear, surrounding the cochlea and resulting in a mixed conductive and SNHL. Advanced otosclerosis with cochlear involvement may influence the insertion and the performance of a CI. Despite in these patients the CI has proven to be the most effective treatment modality, endoluminal otospongiotic obstruction may complicate the insertion of the array and alter the spread of the electrical stimulation. Pre-operative CT may clearly detect ossification of the cochlea (Figure 13) [16].
Until recently, MR imaging with and without contrast media has been used only to exclude cochlear causes of sudden SNHL (SSHL), such as a vestibular schwannoma, and rare causes of retrocochlear SSHL including demyelinating disease, brain stem infarctions and cerebellopontine tumors.
Nowadays, pre-contrast T1-weighted and 3D-FLAIR sequence may suggest the pathogenesis of SSHL.
Two specific patterns can be identified: the “
MR sequences, in particular 3D-T2, are excellent to analyze inner ear fluids intensity, and to investigate the morphology of the inner ear structures, cranial nerve VIII, internal auditory canal and cerebellopontine angle [18, 19].
Post-contrast 3D-FLAIR sequences are able to identify pathological conditions characterized by blood-labyrinth barrier breakdown, including viral infection, immune-mediated inner ear disease, perilymphatic fistulas [20, 21].
Furthermore, the 4 h-delayed 3D-FLAIR sequences on 3 Tesla scanner after intravenous administration of gadolinium-based contrast agent offer enough spatial resolution to detect small endolymphatic structures, such as saccule and utricle; in this sequences the endolabyrinth appears to have a lower signal compared with the surrounding perilymph.
In patients with Meniere’s disease, the pathological finding is represented by endolymphatic hydrops, characterized by a distension of the endolymphatic space of the inner ear into areas that are normally filled with perilymphatic liquid (Figure 16). CI is an effective means of treatment of patients with end-stage Meniere’s disease affected by severe-to-profound SNHL [22, 23, 24].
3. Auditory central nervous system
The auditory central system includes: the cochlear nucleus and the superior olivary complex in the pons, the inferior colliculus in the midbrain, the medial geniculate nucleus of the thalamus and the auditory cortex (i.e. Heschl’s gyrus) in the temporal lobe.
Nowadays, MR imaging is the modality of choice to investigate the auditory central pathway, because of its better sensitivity and specificity compared with others neuro-imaging modalities (CT and, in the newborn, ultrasound scanning).
The auditory pathway myelination begins during the fetal life and increases up to the first year of age, reflecting the improvement of the auditory system function. The changes in myelin can be seen using MR imaging by the 37th fetal week in the brainstem and later in the structure higher in the auditory pathway, as early as 10 weeks of age in the medial geniculate nucleus and by 24 weeks in subcortical white matter (Figure 17) [25, 26].
The 3T MR scanner, thanks to its high contrast and spatial resolution, guarantees great sensitivity in the detection of white matter injury, playing an important role in the early diagnosis of some pathologies related with congenital SNHL [27].
In addition to conventional MR sequences, some advanced techniques such as diffusion tensor imaging (DTI) and functional MR imaging (fMRI), may be helpful to provide new insight into structural and functional white matter changes in early stage of congenital SNHL [28]. On the other hand, the investigation of the first step of the central auditory pathway, i.e. cochlear nucleus, is challenging and currently limited in clinical practice. The most promising MR sequences are T2-weighted gradient-echo (T2GE) imaging and susceptibility weighted imaging (SWI), which ensure a good contrast resolution between hypointensity of the nuclei, due to paramagnetic deposition, and hyperintensity of the surrounding myelinated tissue.
Both environmental and genetic pathologies may lead to congenital SNHL, with possible involvement of any component of acoustic pathway [29, 30].
Frequently, the anatomical structure primarily involved in inherited hearing loss are the inner ear and the CNV (discussed in the previous chapter), while the auditory central pathway is spared by any lesion at the conventional MR investigation.
Conversely, the central system is commonly involved in acquired SNHL disorders. Cytomegalovirus (CMV) is the most common congenital non-genetic cause of SNHL [31]. About 10% of CMV infection results in several brain abnormalities. At present, an official guideline on the preferred neuroimaging modalities to identify brain abnormalities in patients with CMV infection is lacking; the current practice varies according to center-based protocols [32].
MR imaging is more sensitive than ultrasound scanning in the detection of mild and severe brain abnormalities, such as: microcephaly, cerebellar hypoplasia, cortical anomalies, calcification, white matter changes, polar temporal lesion, sub-ependimal cyst, ventriculomegaly and intraventricular septa (Figure 18). The combination of these malformations depends on gestation age at time of infection [33, 34].
Unfortunately, up to date no specific MR finding is significantly associated with the hearing impairment and outcome of treatment [35]. Moreover, all the above mentioned findings are common to several conditions associated with SNHL and should be considered in the differential diagnosis.
Considering others congenital infections, toxoplasmosis and rubella are commonly described as sharing similar pictures with CMV. In countries where the rubella immunization programs are in place, a congenital infection is currently rare; nevertheless, this diagnostic hypothesis should be considered in presence of brain calcifications, white matter lesions, intraventricular septations, subependymal germinolytic cysts and ventriculomegaly. Noteworthy, newborns affected by CMV showing with brain abnormalities are usually asymptomatic from a neurological standpoint, but may develop progressive SNHL only later on in life [36, 37].
Other rare causes of acquired hearing loss, occurring whenever the auditory central pathway is involved in the injury, are focal brain lesions following perinatal ischemic or hemorrhagic event may (Figure 19), hypoxic-ischemic encephalopathy (HIE) (Figure 20) [38, 39]. Therapeutic hypothermia, which is the only approved treatment for HIE, because it reduces the extension of brain lesions, has been unfortunately associated with SNHL. The correlation between imaging and functional outcome is still unknown; up to 10% of the treated babies develop hearing impairment.
MR studies with DWI sequence are widely used as an early outcome measure after hypothermia.
MR spectroscopy, measuring cerebral metabolites changes, has recently been investigated as a possible tool in predicting neurodevelopmental outcomes in newborn with HIE [40]. In the near future, advanced MR technique might be also used to investigate possible correlation between hypothermia and deafness [41].
In conclusion, the latest neuroimaging techniques play a relevant role in the diagnosis of congenital and acquired disorders underlying SNHL. While advanced MR sequences allow to clarify possible differential diagnoses and to achieve a correct identification of the site of lesion from the inner ear to the auditory cortex, the combination of FPCT and MR undoubtedly support the clinicians in the counseling and management of patient’s candidate to CI.
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