Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-27T17:23:03.231Z Has data issue: false hasContentIssue false

Cochlear measurement in computed tomography and magnetic resonance imaging data sets by the Otoplan measurement tool: a retrospective comparative study

Published online by Cambridge University Press:  19 February 2024

Martin Sylvester Otte*
Affiliation:
Department of Otorhinolaryngology, Head and Neck Surgery, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
Verena Mueller
Affiliation:
Department of Otorhinolaryngology, Head and Neck Surgery, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
Pauline Burkhardt
Affiliation:
Department of Otorhinolaryngology, Head and Neck Surgery, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
Christoph Hans-Juergen Endler
Affiliation:
Department of Diagnostic and Interventional Radiology, University Hospital Bonn, Bonn, Germany
Jens Peter Klussmann
Affiliation:
Department of Otorhinolaryngology, Head and Neck Surgery, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany Center for Molecular Medicine Cologne, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
Jan Christoffer Luers
Affiliation:
Department of Otorhinolaryngology, Head and Neck Surgery, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
Maria Grosheva
Affiliation:
Department of Otorhinolaryngology, Head and Neck Surgery, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
Ruth Lang-Roth
Affiliation:
Department of Otorhinolaryngology, Head and Neck Surgery, Faculty of Medicine and University Hospital Cologne, University of Cologne, Cologne, Germany
*
Corresponding author: Martin Sylvester Otte; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Background

Using Otoplan software, it is possible to measure the cochlea before cochlear implant surgery. Until now, computed tomography (CT) of the cochlea has been necessary for this purpose. The aim of this study was to find out whether measuring the cochlea with magnetic resonance imaging (MRI) using Otoplan is possible with the same accuracy.

Methods

The cochlea of 44 patients of the local cochlear implant centre was measured by Otoplan using high-resolution CT-bone and MRI images, and the determined lengths were compared.

Results

No significant difference was found between the cochlear lengths measured, regardless of whether the length measurement was based on a CT or an MRI data set.

Conclusion

For the determination of cochlear length prior to cochlear implant surgery, MRI images are just as suitable as CT images, therefore CT is not mandatory for length measurement by Otoplan, which could reduce the patient's radiation exposure.

Type
Main Article
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of J.L.O. (1984) LIMITED

Introduction

The purpose of this study was to investigate the hypothesis that the measurement of cochlear duct length based on magnetic resonance imaging (MRI) data sets is as good as that based on computed tomography (CT) temporal bone images. To this end, a retrospective comparative study of these two imaging modalities was designed.

Cochlear implants enable hearing rehabilitation in cases of profound sensorineural hearing loss or deafness by electrical stimulation of the auditory nerve. The individualised planning of a cochlear implant operation is becoming more and more important.Reference Dhanasingh1Reference Ricci, Lapenna, Gambacorta, Della Volpe, Faralli and Di Stadio3 The providers of implants have specific electrodes in their portfolio to optimally utilise the anatomical length of the cochlea, to take anatomical peculiarities into account or to provide individualised frequency-specific hearing loss.

For the pre-operative measurement of the cochlear duct length, Otoplan (CAScination AG, Bern, Switzerland, in collaboration with Med-El Corporation, Innsbruck, Austria) has recently become available. It is a tool to determine the length of the cochlear duct from a Dicom-formatted data set of a thin-slice CT temporal bone. Other features of the program also make it possible to estimate the cochlear place frequency using the Greenwood function.Reference Dhanasingh1,Reference Greenwood4 Until now, a thin-slice CT scan of the temporal bone was required for evaluation with Otoplan.Reference Chen, Chen, Tan, Jiang, Wu and Zhang5

However, not all centres do a CT scan of the temporal bone prior to cochlear implant surgery. By contrast, a thin-slice magnetic resonance imaging (MRI) scan of the inner ear is always available, as this can confirm the fluid filling of the cochlea and the presence of the auditory nerve.Reference Guirado, Martínez, Roig, Mirosa, Salmerón and Florensa6Reference Tanioka, Shirakawa, Machida and Sasaki8 We therefore wanted to investigate with this study whether measuring the cochlea with Otoplan using MRI and CT data sets provides comparable results.

Methods

The study used data sets from 27 patients who had both MRI inner-ear and CT temporal bone scans collected in preparation for cochlear implant surgery. Patients with structural abnormalities of the cochlea described in the original radiological report of CT or MRI were excluded from the study. This retrospective study was conducted in accordance with the principles of the Declaration of Helsinki and its later amendments as well as the regulations of the Ethics Commission of the Medical Faculty of the University of Cologne.

The high-resolution CT scans were obtained using a Philips Brilliance 64-slice CT scanner (Philips Healthcare, Best, The Netherlands). The scan volume included the petrous bone region with the external auditory canal, the middle ear and the inner ear. Reformatted images were reconstructed with a slice thickness of 0.67 mm and an increment of 0.33 mm in the axial and oblique coronal planes using a soft tissue and bone window.

Magnetic resonance images were acquired using a whole-body 3.0 Tesla (T) Philips Ingenia System (Philips Healthcare) with a dedicated head coil. A standard T2-weighted turbo spin echo sequence with a slice thickness of 5 mm (matrix 576 × 576, FOV 230 × 200 mm, in-plane resolution 0.4 × 0.35 mm) was obtained of the entire head in the axial plane, followed by a three-dimensional T2-weighted turbo spin echo sequence with a driven equilibrium radio frequency reset pulse and a slice thickness of 1 mm (matrix 512 × 512, Field of View 180 × 162 mm, in-plane resolution 0.35 × 0.32 mm) through the region of the cerebellopontine angle and the inner ear. With the driven equilibrium radio frequency reset pulse applied at the end of a turbo spin echo train, an acceleration of image acquisition was achieved with high spatial resolution of the temporal bone and the facial and vestibulocochlear nerves within the internal auditory canal. Maximum intensity projection images of the vestibule, cochlear and semicircular canals were obtained.

The data sets were uploaded into tablet-based software (Otoplan, version 2). For measurement of the cochlear duct length, the user, a surgeon with expertise in the field of ear and cochlear implant surgery first identified the modiolus in the CT (defined as the centre of the modiolus in the three-dimensional rendered cochlear view). Then the round window and the outer boundary of the cochlea opposite the round window were marked. Subsequently, an orthogonal line was drawn through the connecting line of these two points and the modiolus, and their intersections with the outer cochlear wall were also marked (Figure 1). These points were entered manually by the user into the cochlear view of the program. For more precise placement of the measurement points, an external computer mouse was connected to the tablet.

Figure 1. Exemplary image of a cochlea in (a) computed tomography and (b) magnetic resonance imaging in Otoplan after manual definition of the outer boundaries of the cochlea and alignment of the connecting lines through the modulus.

Otoplan calculates the cochlear duct length according to the elliptic-circular approximation method, which allows a more precise estimation of the cochlear duct length compared with other methods.Reference Schurzig, Timm, Batsoulis, Salcher, Sieber and Jolly9 For this purpose, user-defined points are used to calculate the cochlear diameters (Figure 1), which are then used to derive the cochlear duct length.

The MRI data sets were also read into the Otoplan system and the above-mentioned landmarks were determined in the same way. The software then determined the cochlear duct length from these points.

First all CT and then all MRI data sets were evaluated, whereby the order of the evaluated imaging was random and anonymised. The measurements were all taken by the same examiner.

Statistical analysis was performed using SPSS v. 24 (SPSS Inc., Chicago, USA). The Kolmogorov–Smirnov test and the Shapiro–Wilk test were applied before to check the data distribution. As both tests showed that the data were normally distributed, a paired t-test was conducted to investigate the difference between the MRI and CT cochlear lengths. In addition, the comparability of the two measurement methods was visualised via a Bland–Altman plot.Reference Bland and Altman10 The significance level was set to p ≤ 0.05. The data are presented as average values (± standard error of the mean).

Results

For this study, the data sets of 27 patients were analysed with a balanced gender ratio of 14 male patients and 13 female patients. The mean age of the patients was 55.22 years, with all but 2 patients having reached 18 years of age. In 10 patients, due to a cochlear implant already in place, only the other, non-operated, side was considered, so that a total of 44 corresponding CT and MRI data sets of the cochlea were used.

Cochlear duct length was measured in each case using the method described above. The mean cochlear duct length was 32.443 mm (±0.294 mm) from the CT scans and 32.591 mm (±0.2605 mm) from the MRI data.

The cochlear duct lengths collected using the MRI and CT data were not statistically different (t (43) = −0.989, p = 0.328). There was good correlation between the lengths determined by MRI and CT according to the Pearson analysis (r = 0.862, p < 0.01; Figure 2). The relationship between the two measurements could be described with the correlation function: cochlear duct length–MRI = 7.86 + 0.76 × cochlear duct length–CT.

Figure 2. (a) Visualisation of the determined cochlear lengths in CT and MRI of all subjects. (b) With the exception of two outliers, all differences between the two measurement methods were in the interval of ±1.96 times the standard deviation around the mean value of the differences. (c) With a correlation coefficient of 0.862, a good correlation was found between cochlear duct lengths measured by CT (CDL-CT) and MRI (CDL-MRI). CDL = cochlear duct length; CT = computed tomography; MRI = magnetic resonance imaging; SD = standard deviation

The graphical representation of the data in the Bland–Altman plot showed that, except for two outliers, all differences between the paired measurements were within the required interval of ±1.96 × standard deviation around the mean value of the differences (Figure 2).

Discussion

The results from this study showed that the cochlear duct length calculated using Otoplan does not differ when it is determined from a CT or a thin-slice MRI data set. The results of the measurement methods correlated well with each other and did not differ significantly. With the exception of two outliers, the differences between the respective measurement methods were all within the interval required by Bland and Altman for the comparison of two measurement methods.Reference Bland and Altman10

It has been shown several times in the literature that MRI images can be used to measure the cochlear duct length.Reference Eser, Atalay, Dogan, Gündüz and Kalcioglu11Reference Taeger, Müller-Graff, Ilgen, Schendzielorz, Hagen and Neun13 With regard to the Otoplan program, however, there are different statements in the literature. While the study of Weber et al. produced different results in the application of MRI to CT data and thus cast doubts about the application of MRI imaging in Otoplan,Reference Weber, Kwok, Picou, Wendl, Bohr and Marcrum14 Thomas et al. had already produced consistent results in the application of both types of imaging.Reference Thomas, Klein, Haubitz, Dazert and Völter15 Our study supports these results.

While imaging of the cochlear and auditory nerves by MRI is routinely performed prior to cochlear implant surgery,Reference Aschendorff16 the need for pre-operative CT imaging is questioned by some surgeons.Reference Ellul, Shelton, Davidson and Harnsberger17 Even though other surgeons value CT because of the better visualisation of bony structures before cochlear implant surgery, it can be concluded from this study that CT imaging is not necessary solely for the application of Otoplan.

  • The Otoplan tool provides a way to measure the cochlear duct length before cochlear implant surgery. This can help with individual surgery planning and the choice of electrode length

  • So far, Otoplan has been used mainly for computed tomography (CT) imaging

  • This study shows that it is possible to calculate the cochlear duct length based on magnetic resonance imaging slice images with the same quality as on CT images

  • It was found that Otoplan can also be used when CT is not available

The reduction of one imaging can bring a cost saving.Reference Paul, Oklu, Saini and Prabhakar18 In addition, a significantly increased radiation exposure for the patient can be prevented by omitting CT examination of the temporal bone.Reference Giacomuzzi, Torbica, Rieger, Lottersberger, Peer and Peer19,Reference Neufang, Zanella and Ewen20 This is particularly critical in view of the fact that many patients also undergo further CT imaging post-operatively or intra-operatively to check their position.Reference Aschendorff16,Reference Vogl, Tawfik, Emam, Naguib, Nour-Eldin and Burck21 Especially in children, the saving of radiation doses is particularly important due to the carcinogenicity of CT radiationReference Joshi, Navlekar, Kishore, Reddy and Kumar22 and fortunately there are efforts to also carry out post-operative quality control after cochlear implant surgery by MRI.Reference Riemann, Scholtz, Gehl, Schürmann, Sudhoff and Todt23

Setting the points in the Otoplan cochlear view on the MRI slides is more difficult than in CT, where the bony boundaries and the round window stand out better (Figure 1), therefore, as in our case, the recordings should be as thin as possible. Nevertheless, the use of Otoplan with MRI alone could be more difficult for the inexperienced examiner and lead to incorrect measurements. To explore this, further prospective studies should follow to determine the predictive power of MRI-based Otoplan analysis on the choice of the correct electrode.

Acknowledgements

This study was supported by Med-El, who provided the tablet-based version of Otoplan.

Competing interests

None declared

Data availability statement

The data for the study are with the corresponding author.

Footnotes

Martin Sylvester Otte takes responsibility for the integrity of the content of the paper

References

Dhanasingh, A. Research software in cochlear duct length estimation, Greenwood frequency mapping and CI electrode array length simulation. World J Otorhinolaryngol – Head Neck Surg 2021;7:1722CrossRefGoogle ScholarPubMed
Lovato, A, Marioni, G, Gamberini, L, Bonora, C, Genovese, E, de Filippis, C. OTOPLAN in cochlear implantation for far-advanced otosclerosis. Otol Neurotol 2020;41:e102410.1097/MAO.0000000000002722CrossRefGoogle ScholarPubMed
Ricci, G, Lapenna, R, Gambacorta, V, Della Volpe, A, Faralli, M, Di Stadio, A. OTOPLAN, cochlear implant, and far-advanced otosclerosis: could the use of software improve the surgical final indication? J Int Adv Otol 2022;18:74–810.5152/iao.2022.21329CrossRefGoogle ScholarPubMed
Greenwood, DD. A cochlear frequency-position function for several species—29 years later. J Acoust Soc Am 1990;87:2592–605CrossRefGoogle ScholarPubMed
Chen, Y, Chen, J, Tan, H, Jiang, M, Wu, Y, Zhang, Z et al. Cochlear duct length calculation: comparison between using otoplan and curved multiplanar reconstruction in nonmalformed cochlea. Otol Neurotol. 2021;42:e8758010.1097/MAO.0000000000003119CrossRefGoogle Scholar
Guirado, CR, Martínez, P, Roig, R, Mirosa, F, Salmerón, J, Florensa, F et al. Three-dimensional MR of the inner ear with steady-state free precession. AJNR Am J Neuroradiol 1995;16:1909–13Google Scholar
Biller, A, Bartsch, A, Knaus, C, Müller, J, Solymosi, L, Bendszus, M. Neuroradiological imaging in patients with sensorineural hearing loss prior to cochlear implantation [in German]. Rofo 2007;179:901–13CrossRefGoogle ScholarPubMed
Tanioka, H, Shirakawa, T, Machida, T, Sasaki, Y. Three-dimensional reconstructed MR imaging of the inner ear. Radiology 1991;178:141–410.1148/radiology.178.1.1984292CrossRefGoogle ScholarPubMed
Schurzig, D, Timm, ME, Batsoulis, C, Salcher, R, Sieber, D, Jolly, C et al. A novel method for clinical cochlear duct length estimation toward patient-specific cochlear implant selection. OTO Open 2018;2:2473974X18800238CrossRefGoogle ScholarPubMed
Bland, JM, Altman, DG. Statistical methods for assessing agreement between two methods of clinical measurement. Lancet 1986;327:307–1010.1016/S0140-6736(86)90837-8CrossRefGoogle Scholar
Eser, MB, Atalay, B, Dogan, MB, Gündüz, N, Kalcioglu, MT. Measuring 3D cochlear duct length on MRI: is it accurate and reliable? AJNR Am J Neuroradiol 2021;42:2016CrossRefGoogle ScholarPubMed
Nash, R, Otero, S, Lavy, J. Use of MRI to determine cochlear duct length in patients undergoing cochlear implantation. Cochlear Implants Int 2019;20:5761CrossRefGoogle ScholarPubMed
Taeger, J, Müller-Graff, FT, Ilgen, L, Schendzielorz, P, Hagen, R, Neun, T et al. Cochlear duct length measurements in computed tomography and magnetic resonance imaging using newly developed techniques. OTO Open 2021;5:2473974X21104531210.1177/2473974X211045312CrossRefGoogle ScholarPubMed
Weber, L, Kwok, P, Picou, EM, Wendl, C, Bohr, C, Marcrum, SC. Vermessung der Cochlea mittels eines Tablet-basierten Softwarepakets: Einfluss der Bildgebungsmodalität und des Untersucherhintergrunds. HNO 2022;70:769–77CrossRefGoogle Scholar
Thomas, JP, Klein, H, Haubitz, I, Dazert, S, Völter, C. Intra- and interrater reliability of CT- versus MRI-based cochlear duct length measurement in pediatric cochlear implant candidates and its impact on personalized electrode array selection. J Pers Med 2023;13:63310.3390/jpm13040633CrossRefGoogle ScholarPubMed
Aschendorff, A. Imaging in cochlear implant patients. GMS Curr Top Otorhinolaryngol Head Neck Surg 2011;10Google Scholar
Ellul, S, Shelton, C, Davidson, HC, Harnsberger, HR. Preoperative cochlear implant imaging: is magnetic resonance imaging enough? Otol Neurotol 2000;21:528–33Google Scholar
Paul, AB, Oklu, R, Saini, S, Prabhakar, AM. How much is that head CT? Price transparency and variability in radiology. J Am Coll Radiol 2015;12:453–710.1016/j.jacr.2014.12.016CrossRefGoogle ScholarPubMed
Giacomuzzi, SM, Torbica, P, Rieger, M, Lottersberger, C, Peer, S, Peer, R et al. Radiation exposure in single slice and multi-slice spiral CT (a phantom study) [in German]. Rofo 2001;173:643–9CrossRefGoogle Scholar
Neufang, KF, Zanella, FE, Ewen, K. Radiation doses to the eye lenses in computed tomography of the orbit and the petrous bone. Eur J Radiol 1987;7:203–5Google Scholar
Vogl, TJ, Tawfik, A, Emam, A, Naguib, NNN, Nour-Eldin, A, Burck, I et al. Pre-, intra- and post-operative imaging of cochlear implants. Rofo 2015;187:980–9Google ScholarPubMed
Joshi, VM, Navlekar, SK, Kishore, GR, Reddy, KJ, Kumar, ECV. CT and MR imaging of the inner ear and brain in children with congenital sensorineural hearing loss. RadioGraphics 2012;32:683–98CrossRefGoogle Scholar
Riemann, C, Scholtz, LU, Gehl, HB, Schürmann, M, Sudhoff, H, Todt, I. Evaluation of cochlear implant electrode scalar position by 3 Tesla magnet resonance imaging. Sci Rep 2021;11:21298CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Exemplary image of a cochlea in (a) computed tomography and (b) magnetic resonance imaging in Otoplan after manual definition of the outer boundaries of the cochlea and alignment of the connecting lines through the modulus.

Figure 1

Figure 2. (a) Visualisation of the determined cochlear lengths in CT and MRI of all subjects. (b) With the exception of two outliers, all differences between the two measurement methods were in the interval of ±1.96 times the standard deviation around the mean value of the differences. (c) With a correlation coefficient of 0.862, a good correlation was found between cochlear duct lengths measured by CT (CDL-CT) and MRI (CDL-MRI). CDL = cochlear duct length; CT = computed tomography; MRI = magnetic resonance imaging; SD = standard deviation