Temporal High-Resolution Computed Tomography and Magnetic Resonance Imaging of Congenital Inner Ear Anomalies in Children

Palabıyık, Figen; Hacıkurt, Kadir

doi:10.1097/scs.0000000000002981

Cited by 4 publications

(4 citation statements)

References 11 publications

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“…A review of the literature was performed for imaging of the inner ear. MRI 8 – 12 and CT 13 , 14 have been used previously. Both T1 and T2 weighted imaging MRIs have captured images of the inner ear 8 – 10 .…”

Section: Discussionmentioning

confidence: 99%

“…MRI has been used to image the inner ear in diagnosing Meniere disease 15 , 16 . High-resolution CT has been used to study calcium functional imaging of otoliths 13 and congenital inner ear anomalies in children 14 . Current imaging systems of this type are not practically feasible for space travel due to limitations of weight and space, as well as the need for containment of ionizing radiation and strong magnetic fields.…”

Section: Discussionmentioning

confidence: 99%

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Special anatomy series. Imaging inner ear structures with high-frequency ultrasound: Application to physical rehabilitation space medicine

Strakowski,

Zhang,

Reschke

et al. 2024

The Journal of the International Society of Physical and Rehabilitation Medicine

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Objective: The objective of this paper is to document the feasibility of image acquisition, image optimization, and sonographic appearance of the exposed anatomic windows of cadaveric inner ear dissection for purposes of potential future clinical evaluation as part of the developing area of physical and rehabilitation space medicine. Methods: Cadaveric dissection of the inner ear was conducted with the goal of exposing areas relevant to vestibular balance. Middle and inner ear structures of 3 human cadavers were imaged with multiple broadband transducers, including emphasis with higher frequency transducers. Results: The images were best optimized with 17 MHz and 22 MHz small footprint transducers. High-frequency ultrasound (US) images of the semicircular canals, vestibular and facial nerves, and utricles with reflected otoliths (otoconia) were obtained and reported in this article. Detailed visualization of both the vestibular nerve and facial nerve was accomplished, including identification of fascicular architecture. In addition, US reflection from the otoliths contained within the utricle was identified with sufficient clarity to provide surface measurements. Bony acoustic landmarks of the middle ear bones were identified by scanning externally from the tympanic membrane, including the dynamic movement of the bones with manual manipulation. Conclusion: US visualization has the potential to be an effective imaging modality to monitor potential changes to the otolith's size throughout extended space flight. To our knowledge, no prior study has reported US images of human inner ear structures.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Special anatomy series. Imaging inner ear structures with high-frequency ultrasound: Application to physical rehabilitation space medicine

Strakowski,

Zhang,

Reschke

et al. 2024

The Journal of the International Society of Physical and Rehabilitation Medicine

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“…Another aspect considered in our study was the use of imaging studies to plan surgery and avoid potential complications. Several studies have illustrated the importance of a thorough preoperative radiological examination to classify cochlear and/or vestibular anomalies before surgery [64,65]. Abnormal HRCT or MRI scans may predict compromised cochlear patency, thus anticipating difficulties with device insertion [7,23].…”

Section: Discussionmentioning

confidence: 99%

Cochlear implantation in children with enlarged vestibular aqueduct (EVA): relationship to Pendred syndrome diagnosis, surgical outcomes, and radiological findings

Remjasz-Jurek¹,

Clarós²,

Clarós-Pujol³

et al. 2023

J Hear Sci

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IntroductionThe cochlear implant (CI) procedure in patients with inner ear malformations is challenging. The aim of this study was to evaluate auditory perception and speech development in children with enlarged vestibular aqueduct (EVA) and to relate the results to the diagnosis of Pendred syndrome (PS), imaging findings, surgical course, and postoperative period.Material and methodsThe study group consisted of 49 children with EVA, aged 11 months to 15 years, with severe to profound hearing loss. The EVA patients included 22 with PS and 27 with nonsyndromic EVA (NSEVA). The control group consisted of 46 children with nonsyndromic deafness. Outcomes after cochlear implantation were evaluated annually for at least 10 years. Auditory performance was assessed by categories of auditory performance (CAP) and Meaningful Auditory Integration Scale (MAIS). Speech outcomes were evaluated by Speech Intelligibility Rating Scale (SIR) and Meaning Use of Speech Scale (MUSS). Genetic counselling, imaging studies, and vestibular testing were also evaluated when available.ResultsAll patients included in the study benefited from cochlear implants, especially when implantation was performed before the age of 3 years. After CI, EVA patients (PS and NSEVA) achieved a steeper rate of increase in auditory perception and speech intelligibility, demonstrating higher scores at each follow-up point compared to nonsyndromic patients (NS). There were no differences in auditory and speech perception between NSEVA and PS patients. In addition to EVA, the most commonly diagnosed malformation was incomplete partition type 2 (IP-2), the presence of which negatively affected postoperative outcomes. During cochleostomy, cerebrospinal fluid (CSF)/perilymph leakage was observed in 50% of implanted ears, but its presence did not affect the final outcomes.ConclusionsEarly cochlear implantation is associated with satisfactory speech and auditory development in children with EVA. Due to the presence of inner ear malformations in patients with Pendred syndrome, detailed imaging of the temporal bone is indicated. Despite the frequent occurrence of CSF/perilymph leakage during cochleostomy, patients with EVA benefit satisfactorily from cochlear implantation.

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“…Es relevante decir que los datos obtenidos con TAC y resonancia magnética (RM) de los huesos temporales son complementarios y en pacientes seleccionados con hipoacusia se deben considerar ambas modalidades (12,13). El método diagnóstico y de planeación quirúrgica recomendado es la TAC del hueso temporal.…”

Section: Valoración Imagenológica De La Pérdida Auditiva: La Relevanc...unclassified

Escuchar con los ojos: evaluación por tomografía axial computarizada de la pérdida auditiva

Jaramillo

Sandoval

Morera

et al. 2022

Rev. colomb. radiol.

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Múltiples patologías pueden afectar el funcionamiento del aparato auditivo. El conocimiento anatómico de los compartimentos del hueso temporal en la tomografía axial computarizada (TAC) conduce a una mejor comprensión de estas entidades y mejora el enfoque clínico hacia la pérdida auditiva conductiva o neurosensorial. Un diagnóstico preciso significa un inicio rápido del tratamiento, lo cual puede modificar el pronóstico del paciente.

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Temporal High-Resolution Computed Tomography and Magnetic Resonance Imaging of Congenital Inner Ear Anomalies in Children

Cited by 4 publications

References 11 publications

Special anatomy series. Imaging inner ear structures with high-frequency ultrasound: Application to physical rehabilitation space medicine

Special anatomy series. Imaging inner ear structures with high-frequency ultrasound: Application to physical rehabilitation space medicine

Cochlear implantation in children with enlarged vestibular aqueduct (EVA): relationship to Pendred syndrome diagnosis, surgical outcomes, and radiological findings

Escuchar con los ojos: evaluación por tomografía axial computarizada de la pérdida auditiva

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