Cone-beam CT versus Multidetector CT in Postoperative Cochlear Implant Imaging: Evaluation of Image Quality and Radiation Dose

DISCUSSION

The number of CI operations has increased notably in recent years; however, there is still a wide spectrum of postoperative outcomes. Hence, more improvement in the electrode design, surgical approaches, and evaluation of the related detailed cochlear anatomy is necessary.^5,20 Conventional radiography and MDCT have long been used for postoperative evaluation. CBCT imaging is a relatively new technique in the imaging of CIs and is reported to have a better spatial resolution than MDCT, with fewer metallic artifacts affecting the implant evaluation.^3,21

High-resolution images are necessary for the proper visualization of single electrode contacts. Verbist et al²² compared 4 different MDCT devices in the evaluation of CIs. They used an in-plane resolution (x and y axis) of 0.48–0.68 mm and a longitudinal resolution (z-axis) of 0.7–0.98 mm, obtaining images with the high resolution necessary to adequately discriminate among the different electrode contacts. However, the use of flat panel detectors in CBCT devices provides images with higher isotropic resolution using a submillimeter detector size ranging from 0.09 to 0.4 mm.¹⁵ In the current study, the voxel size used in the CBCT group was 0.125 mm (in all dimensions), which provided an isotopic image with high spatial resolution, thus allowing good-to-perfect visualization of single electrode contacts in 56% of patients (including widely spaced and narrowly spaced electrode contacts) compared with only 16% in the MDCT group (including only widely spaced contacts).

The metallic artifacts were also significantly lower in the CBCT group than in the MDCT group (P < .001). However, some of the patients undergoing CBCT implanted with CI532 (intercontact distance of 0.6 mm) and CI512 (nonuniform intercontact distance ranging from 0.4 to 0.8) had high to-moderate metallic artifacts, leading to poor visualization of electrode contacts. The signal-to-noise ratio was significantly lower in the CBCT group; this finding can be explained by the higher scattered radiation of CBCT, which is one of its main disadvantages, which decreases the contrast resolution and increases image noise.⁸ The other disadvantage of CBCT was the relatively longer exposure time, which may increase the risk of motion artifacts. However, in patients with dizziness, shortened techniques with slightly lower resolution can be used to overcome this.

Some studies have examined the role of CBCT in the assessment of postoperative CIs in vitro.^12,13 These studies compared the results of image analysis, including scalar positioning of the electrode, the presence of kinking, the number of intracochlear electrode contacts, and proper overall insertion using CBCT with those of histopathologic examinations in temporal bone specimens and concluded that CBCT as a noninvasive approach yielded results comparable with those of histopathologic analyses, encouraging its clinical use. Razafindranaly et al¹⁴ compared the role of CBCT with that of MDCT in 9 patients in terms of scalar localization, insertion depth, and radiation doses. They concluded that there was good agreement between the 2 modalities in the evaluation of insertion depth; however, CBCT could be superior to MDCT in determining the scalar location of electrodes with lower doses.

Our results are in line with these previous studies because perfect visualization of the scalar position of the electrode was successful in 78% of cases in the CBCT group compared with 47% in the MDCT group. There was no statistically significant difference between both groups in the ability to measure the electrode insertion angle. Nevertheless, Jia et al²³ had difficulty in assessing the scalar position of electrode or interscalar translocation using the mobile intraoperative CBCT device compared with previously obtained images using MDCT in the same patients; however, this issue could be attributed to the differences between mobile and fixed CBCT devices and the lack of specialized neuroradiologists during the operation.

The assessment of cochlear walls is essential for electrode localization, scalar position, and evaluation of postimplant inner ear trauma. Verbist et al²² concluded that the outer (lateral) cochlear wall could be better evaluated than the inner wall, a result attributed to the thick outer wall being a part of the otic capsule (dense bone), which provides a better contrast with the cochlear lumen, unlike the inner wall, which contains neural elements with lower density.

Our study revealed a statistically significant difference between the 2 groups regarding the visualization of the cochlear outer wall (P < .001), with it being perfectly visualized in 94% of the patients of the CBCT group compared with 53% in the MDCT group; however, there was no significant difference in the visualization of the cochlear inner wall (P > .99) and the modiolus (P = .37). Perfectly visualized cochlear inner walls and modioli were reported in 69% and 78% of patients in the CBCT group, respectively, compared with 73.7% and 95% in the MDCT group. This finding could be attributed to the larger number of lateral wall electrodes used in the MDCT group compared with the more perimodiolar and midscalar electrodes used in the CBCT group in our study population. The proximity of the electrode to the lateral cochlear wall or the modiolus can degrade the image quality by metallic artifacts. Furthermore, the osseous spiral lamina could be identified in only the CBCT group, in which 31% were barely visualized and 13% were well-visualized. The visualization of the spiral lamina could be further used for better evaluation of electrode translocation and inner ear trauma after CI.

The facial nerve canal, though an extracochlear anatomic structure, is an important surgical landmark in the CI field.²⁴ In the current study, the good-to-perfect visualization of the facial canal bony wall was higher in the CBCT group than in the MDCT group. Although the difference was nonsignificant, this finding might allow a better radiologic evaluation of postoperative complications such as facial nerve injury or stimulation.

Many studies have compared the radiation dose of MDCT and CBCT in the assessment of CIs.²⁵ Guberina et al²⁶ compared CBCT with MDCT with 3 different machines (128-, 256-, and 384-multislice CT scanners) by imaging 4 temporal bone specimens and concluded that the dose-length product of a CBCT examination was 9%–15% of the dose-length product used during MDCT. In another study, this mean value was 200 [SD, 53.4] mGy*cm for CBCT compared with 605 [SD, 57.2] mGy*cm for MDCT.²¹ Our results also revealed significant radiation dose differences between the 2 groups. The dose-length product for the CBCT group ranged from 47.6 to 93 mGy*cm, while it was 179–650 mGy*cm for the MDCT group, indicating a reduction of about 85.7% of the maximum dose with CBCT compared with MDCT. However, the low radiation dose is associated with a decreased signal-to-noise ratio, which makes CBCT unsuitable for soft-tissue imaging and limits its use for visualizing bone details.⁷

Other studies examined the possibility of using low-dose CT in the cadaveric lamb model for assessment of the electrode position.^27,28 They succeeded in evaluating the electrode position using a reduced tube current of 50% without an increase in the artifacts. They stated that the use of low-dose CT protocols might have results comparable with those of CBCT, both in terms of image quality and radiation dose. However, further prospective studies are needed to substantiate this possibility.

The main limitations of our study were the heterogeneity in the age, the differences in the types of implanted electrodes, and the 2 imaging modalities not being compared in the same group of patients because of the risk of radiation exposure.