RESUMO
Otolaryngology specialists must be familiar with radiological studies that allow the diagnosis of different otological pathologies. Magnetic resonance imaging is a complement to computed tomography, which allows a better evaluation of soft tissues and contributes to the differential diagnosis of space-occupying lesions located in the temporal bone and lateral skull base. It is also the technique of choice for the evaluation of the inner ear and the anatomical structures located in the cerebellopontine angle. In this article we present a checklist for magnetic resonance imaging of the ear with different sections that will allow a systematic review of all structures of interest in otological practice, as well as the preferred sequences for each situation.
Assuntos
Lista de Checagem , Orelha Interna , Ângulo Cerebelopontino , Orelha Interna/diagnóstico por imagem , Humanos , Imageamento por Ressonância Magnética , Osso TemporalRESUMO
Otolaryngology specialists must be familiar with radiological studies that allow the diagnosis of different otological pathologies. Magnetic resonance imaging is a complement to computed tomography, which allows a better evaluation of soft tissues and contributes to the differential diagnosis of space-occupying lesions located in the temporal bone and lateral skull base. It is also the technique of choice for the evaluation of the inner ear and the anatomical structures located in the cerebellopontine angle. In this article we present a checklist for magnetic resonance imaging of the ear with different sections that will allow a systematic review of all structures of interest in otological practice, as well as the preferred sequences for each situation.
RESUMO
PURPOSE: Because successful healing of a tympanic membrane perforation (TMP) depends upon the maintenance of blood supply to the injured area, we assessed the usefulness of narrow band imaging (NBI) video endoscopy to evaluate its vascularization. To our knowledge, the use of NBI to assess tympanic membrane (TM) vascular patterns has never been attempted. METHODS: Prospective observational study. NBI and cold white light (CWL) flexible videoendoscopy was used to explore perforated TMs of 100 patients. Main outcome measures were visualization of vessels among abnormal TM findings: monomeric areas (MA) (n = 6), myringosclerosis plaques (MP) (n = 65) and perforation edges (n = 100). They were graded by a vascular otoendoscopic score (VOS) comparing both types of lights (Wilcoxon test). Location and vascularization patterns were analyzed (Fisher's test). RESULTS: NBI was better to observe vascularization of 32% of perforation edges and 75.4% of MP (p < 0.001). NBI displayed higher (better) VOS when evaluating TMP edges (1.05 vs. 0.73) and MP (1.56 vs. 0.81, p < 0.001). The majority of TMP edges showed a ring pattern (66%), followed by irregular (19%), avascular (12%) and radial patterns (3%). The avascular pattern was more frequent in posterior perforations (p = 0.003). The radial pattern was most frequently found in MP, especially at posterior quadrants (p = 0.048). MA presented an irregular pattern in 83.3% of TMs. CONCLUSIONS: NBI videoendoscopy is a promising non-invasive technique, superior to CWL for visualizing vessels among TMP edges and MP, based on further study, could become a supplementary diagnostic tool in the workup of TMP and the decision-making surgical field.