ADVERTISEMENT
Evaluation of Globe Position Asymmetry in Endocrine Orbitopathy Patients and a Control Group – A Computed Tomography–Based 3D Cephalometric Analysis
Abstract
Background. Previous studies have shown that patients suffering from endocrine orbitopathy (EO) seem to present with profound asymmetry in proptosis. As asymmetry might pose a major problem in planning decompression surgery, information on the amount of variation between sides and a concise evaluation method should be available. Therefore, a study based on a concise 3D cephalometric analysis was conceived to evaluate globe position.
Methods. A 3D-cephalometric analysis was performed on computed tomography (CT) data from 52 orbitopathy and 54 control data sets. Using 36 anatomic landmarks, 33 distances were evaluated to measure sagittal, vertical, and horizontal globe position.
Results. EO patients presented with marked exophthalmos and statistically significant asymmetry. Depending on the 2 measured distances, 38% and 42%, respectively, presented sagittal asymmetry of >2 mm, and 12% and 13%, respectively, presented with sagittal asymmetry >4mm. No such asymmetry was seen in the control group. Furthermore, EO patients showed a larger interglobe distance due to lateral globe position. Marked asymmetry correlated with male sex. Proptosis measured to the deep bony orbit correlated with values measured to the orbital aperture or with constructed Hertel values.
Conclusions. Use of 3D cephalometry and CT-based analysis confirmed findings from previous clinical studies on profound sagittal asymmetry in EO. Endocrine orbitopathy leads to a sagittal-lateral globe displacement that is even more pronounced in the current study than in earlier investigations. Concerning surgical therapy, presurgical asymmetry, especially if profound, has to be considered to achieve an esthetic symmetrical outcome. Use of 3D orbital analysis is an appropriate method to describe globe position beyond clinical measurements.
Introduction
Endocrine orbitopathy (EO) is a disfiguring, potentially vision-threatening disease affecting mostly women from 30 to 60 years of age.1,2 It is a typical extrathyroidal symptom of Graves’ disease and may cause exophthalmos, eyelid retraction, chemosis, periorbital tissue increase, diplopia, and conjunctival injection.1,2 Recent findings suggest that asymmetry of globe position is a predictor of disease progression and severity.3,4 By now, assessment of globe position (and thus asymmetry) relative to the orbit is performed mainly by way of exophthalmometry5-7 or, to a lesser extent, by using 3D imaging.8-10 Besides providing the clinician with knowledge on the possible presence of asymmetry, this assessment might be an important aspect in treatment planning if decompression surgery is scheduled to achieve a symmetric esthetically pleasing outcome.
As the authors’ workgroup had developed a 3D cephalometric computed tomography (CT)-based orbital analysis,11 they sought to evaluate the prevailing asymmetry in a database of patients with and without EO, measure the clinical usability of the 3D analysis, and compare the data to previous reports.
Methods and Materials
The 3D cephalometry was based on FAT software12,13 that uses the open-source VTK (Visualization Toolkit) library (vtk.org). The interface has been structured to permit best clinical usability. After loading and registering the CT data, a set of anatomical landmarks (Table 1) was placed either directly on the 3D rendering or by using crosshairs on the 3D image or 2D sagittal, coronal, and axial slices. The software could zoom the images, determine threshold indices, and rotate the images automatically for each landmark and highlight the supposed area were the landmark would be placed by using the inherent software landmark library. After all landmarks were placed and their positions confirmed, the software would run a cephalometric script to create lines and planes or construct new landmarks. The results were then displayed, consisting of distances, angles, proportions, and symmetry measurements in a spreadsheet ready for export. Screenshots could be captured if appropriate.
For measurement of globe position symmetry, the recorded distances are stated in Table 1. For the analysis, 36 landmarks were used: 14 bilateral and 1 midline landmark, and 2 constructed bilateral and 3 constructed midline landmarks (Table 1, Figure 1). A total of 12 planes were constructed and 33 distances were measured (16 bilateral, 1 midline) (Table 1). As the software was modular, existing landmark sets could be reused, landmarks added, and the cephalometric analysis modified.
For the investigation, CT images obtained from 52 patients with bilateral EO were used. Mean age of these patients was 49.1 ± 10.4 years (range, 28-76 years); 35 patients were female and 17 were male. For the control (non-EO) group, CT images were obtained from 54 patients without known orbital/craniofacial pathology. Mean age of these patients was 41.6 ± 18.3 years (range, 18-84 years); 21 patients were female and 33 were male. CT data did not exceed 1.5 mm thickness of contiguous slices.
Statistical analysis was performed using WinMEDAS software (Fa. Christian Grund). Symmetry was assessed with paired t tests, and comparisons regarding sex or EO were performed with unpaired t tests. Correlations were measured using Spearman’s rank correlation test. Statistical significance threshold was set at P ≤ .05.
Results
Regarding average time needed to perform a single analysis from a CT scan, approximately 5 minutes were spent on data selection, loading, analysis, and export. As shown in the descriptive statistical results (Table 2), patients in the EO group presented a statistically significant larger globe protrusion regarding the bony orbit (eg, orbital apex), orbital aperture, and soft tissue lateral rim (computed Hertel values).
Asymmetry was evaluated in 3 ways. First, the mean values of both sides were compared. Here, the non-EO group presented minor, statistically nonsignificant differences (Table 2). In the EO group, both sagittal side differences and the lateral globe position in relation to the orbital aperture midpoint showed statistically significant asymmetry values. Next, individual difference values were computed for each patient. Here, the EO group showed statistically significant larger values, too. For the bony sagittal value, asymmetry of globe protrusion were between 2 and 2.2 mm, depending on the measured distances; in contrast, these values were between 0.7 and 1.2 mm in the non-EO group. Regarding interglobe distance and globe distance to the midsagittal plane, absolute values and asymmetry were also statistically larger in the EO group. Only in the cranial/caudal deviation to the Frankfurt horizontal plane were no statistical differences for absolute and asymmetry values found. Lastly, the individual asymmetry values in the sagittal dimension (exophthalmos) were divided in 3 groups: asymmetry <2 mm, asymmetry from 2 to 4 mm, and asymmetry >4 mm. Here, the EO group showed larger percentages of patients in the 2- to 4-mm group and the >4-mm group. In the control group, no patients had asymmetry values >2 mm (Table 2). Due to the rather small vertical and lateral asymmetry values, no subgroups to define the extent of asymmetry were calculated.
In both the EO and non-EO groups, the right side was more often the prominent one (EO group: 30 patients with right predominance vs 20 patients with left predominance; non-EO group: 32 CTs showed right-side prominence vs 22 with left-side prominence).
Concerning asymmetry prevalence and sex, no statistically significant correlation was found in the non-EO group. In the EO group, male sex was correlated with asymmetry in the distances globe to orbital apex, globe lateral position, globe position anterior, globe protrusion, and bony orbit to the frontomalar suture (FMS) as calculated by Hertel exophthalmometer. (Table 3).
Regarding correlations between the different globe position measurements, the following results were seen: sagittal globe position measured in relation to the orbital apex (directly measured or projected) correlated statistically significantly to the sagittal globe position with respect to the orbital aperture; higher correlation coefficients were seen in the EO group. Interglobe distance showed no or a weak significant correlation to the sagittal globe position measured in the orbital aperture region. Sagittal globe position to the orbital apex plane presented no statistically significant correlation with the lateral and horizontal globe position.
Summarizing the findings, patients in the EO group presented a statistically significantly larger globe protrusion and a higher degree in asymmetry, both in average and when grouped according to asymmetry severity. Male sex correlated with some asymmetry parameters, and the right side was more often the prominent eye. Sagittal globe position with respect to the orbital apex correlated with sagittal globe position calculated to the orbital aperture.
Discussion
Sagittal globe position in healthy persons varies depending on age, sex, and ethnicity.5 For clinical measurements, various devices have been invented but the most widely used are Hertel and Naugle types; several modifications, however, have been suggested (eg, the Luedde or Mourits meter).14,15 When using Hertel devices for these measurements, parallax errors, rotation on the horizontal plane, and incorrect resting of the footplate on the lateral orbital rim15 may lead to errors in the range of ±1 mm.14 Other devices may furnish differing results in singular examinations, but these devices seem to be comparable when used for large groups of patients7 and have been shown to provide acceptable interobserver reliability.6 According to previous reports,3-5,16 asymmetry in >90% of individuals in healthy study groups is <1 mm and never >2 mm.
CT has been employed to measure sagittal globe position in various investigations.8-10 In all studies, CT results showed a high correlation with clinical Hertel values. A noteworthy difference between these investigations and the current study, however, lies in the CT analysis. For sagittal globe position calculation in previous investigations, the patient had to be oriented parallel to the Frankfort plane by the radiologist, and the acquired axial planes were used to calculate proptosis values. Perfect orientation may be performed in selected studies but may be problematic in routine investigations, especially if CTs are performed at a different facility than where measurements would be performed. In the current investigation, patient head orientation was definitively mixed. Thus, using 3D cephalometry and image manipulation, a sound analysis was possible; this would not have been the case if the original axial CT planes had been utilized. It has been shown that landmark repeatability is high in anatomically defined landmarks17,18 (ie, Bookstein types 1 and 219,20), leading to a low inter- and intraobserver variability of 0.5 to 1 mm.21-25 Thus, linear measurements should be precise and reliable.26
Comparing the authors’ asymmetry measurements with clinical exophthalmometric results, the mean values for both sides showed differences in accordance with previous reports.5,16 These variations were <1 mm in both groups with higher values seen in the EO group (0.9 and 0.8 mm in EO patients; 0.2 and 0.1 mm in the non-EO group; Table 2). Sagittal side differences were statistically higher in the EO group.
Looking at asymmetry values on an individual basis, the situation was different. Here, patients in the EO group presented asymmetry of >2 mm in 38% and 42%, respectively, for the distances from anterior globe to apex orbitae and anterior globe to cor-apex orb plane (Table 3). This is in accordance with several investigations3,4,27 that stated that asymmetry is not uncommon in patients with EO. Panagiotou et al3 reported that asymmetry >2 mm may be encountered in 9% to 34% of patients with bilateral EO disease, whereas Kavoussi et al27 found asymmetry in 38%. This corresponds with the current study’s finding of asymmetry of >2 mm in 38% and 42% of patients, depending on the calculation performed (Table 3). The results of the EUGOGO study,4 which reported asymmetry in 30.9% of patients with EO, are difficult to compare because a score of 6 symptoms was used to define asymmetry, one of which was a proptosis difference of >2 mm. As with the present study, Perros et al and Kavoussi et al4,27 found male sex to correlate with pronounced asymmetry; the reason for this correlation is only speculative. The same also applies to the dominance of the right side in asymmetry cases for which no causes are known.
Novel findings of the present study were the amount of severe asymmetry (>4 mm side difference) and the slight but statistically significant asymmetry regarding the lateral globe position. Furthermore, the authors could demonstrate the correlation of sagittal globe position measured to the bony orbit with the sagittal position in relation to the bony aperture, whereas sagittal position showed no correlation with the lateral, horizontal, or vertical globe position. Concerning the higher correlation coefficients of proptosis measured to the deep bony orbit and the orbital aperture in the EO group, a possible explanation could lie in the variable lateral inclination of the orbital aperture.11 In individuals in the non-EO group, this anatomical trait was an influencing factor of sagittal globe position measured to the orbital aperture, thus leading to a comparatively low correlation coefficient. In patients with EO who had pronounced proptosis, however, the influence of the orbital aperture tilting (eg, retrusion of the lateral orbital rim) could become less important in the statistical correlation analysis.
In the non-EO group, no asymmetry >2 mm was found, which is in accordance with previous studies.3,5,16
Limitations
Even if this 3D cephalometric approach worked well, there are 2 potential problems in performing 3D cephalometric globe position analysis. First, reference planes were used for measurements. These are necessary if true sagittal, vertical, or horizontal values are to be recorded. These planes rely on symmetrical landmarks; therefore, stable, symmetric, and clearly identifiable landmarks have to be selected. In orthodontics and maxillofacial surgery, bilateral points (such as Porion and FMS), midline landmarks (such as Nasion and Sella), or midpoints of symmetrical landmarks are used.18,24 Minimal asymmetry in selecting symmetrical landmarks can thus lead to asymmetric values measured to these planes. Performing measurements in larger study groups should eliminate this minor tilting of the reference planes, but in singular measurements, this could have an impact in asymmetry scores. The second and probably more relevant problem lies in identifying anterior and posterior globe landmarks. These landmarks were the most difficult to define within the current analysis. According to the Bookstein definition, these are type 3 landmarks and therefore, by nature, are less precise.19,20 The authors tried to eliminate this factor by using crosshairs and simultaneous scrolling in three 2D windows in addition to reformatting or tilting the axial planes if needed. However, alternative ways to measure anterior and posterior globe landmarks could be required to reduce the effort of landmark placing (which should be at least semiautomatic to ease usability and reduce investigation effort). By now, no such algorithms are known to the authors.
Summarizing the aforementioned effects, future software should incorporate automatic orientation plane extraction by determination of multiple symmetrical landmarks and an algorithm to define the “true” anterior and posterior globe landmarks (eg, measured to the true vertical plane as defined in orthodontic analyses).
Conclusions
To the authors’ knowledge, there is no study utilizing 3D analysis of the orbit and globe position that has presented information on the time required for a single analysis. It can be speculated that this ranged well above the average 5 minutes required by the authors’ software. Nevertheless, clinical exophthalmometry using a Hertel device is faster and less expensive and does not require 3D data. Thus, in a first investigation on proptosis and asymmetry, clinical devices should be the method of choice. In case of pathologic findings that will lead to 3D image acquisition, however, a fast and reliable 3D analysis will deliver precise information on the bony orbit and soft tissues11 on globe position and asymmetry.
Importantly, 3D cephalometry could be used to analyze treatment effects on globe position. The tool would be well-suited to investigating treatment changes beyond a postsurgical reduction of clinical Hertel values because surgery might influence the correct position of the exophthalmometer.
In conclusion, previous findings reporting on higher occurrence of sagittal globe position asymmetry were confirmed, as were the higher prevalence of asymmetry in male patients and the predominance of right-sided asymmetry. By way of 3D cephalometry, novel information on the concurrent lateral globe displacement was found, demonstrating that EO causes a complex change in globe position. Furthermore, the extent of asymmetry (13% of patients in the EO group had asymmetry >4 mm) has not been previously reported in the literature. As asymmetry has been reported to correlate with disease progression or severity,3,4 a 3D analysis based on CT data might be appropriate in these cases. When planning treatment with decompression surgery in patients with EO, clinicians must consider the impact of such asymmetry, which could be quite prominent. Here, software-supported 3D cephalometry can be an efficient means to analyze orbital hard and soft tissue anatomy in patients with EO and could be an important part of any surgical software, even if some features (like the exact definition of the most anterior globe landmark) need improvement. Such future refinements will be the task of the authors’ workgroup. Furthermore, having a precise tool for globe position measurement could be beneficial when evaluating the progress of presurgical asymmetry after decompression.
Acknowledgments
Affiliations: 1Department of Ophthalmology, Leipzig University, Leipzig, Germany; 2Department of Oral & Maxillofacial Plastic Surgery, Helios Vogtland-Klinikum Plauen, Plauen, Germany; 3Department of Informatics and Media, Leipzig University of Applied Sciences, Leipzig, Germany; 4Department of Oral & Maxillofacial Plastic Surgery, Leipzig University, Leipzig, Germany
Correspondence: Thomas Hierl, MD, DDS, PhD; thomas.hierl@helios-gesundheit.de
Sources of support: This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors. The development of the 3D analysis software (FAT) was partially funded by German Federal Ministry of Economics and Technology ZIM KF2036708SS0.
Ethics: Ethical approval for this study was given by the Leipzig University ethics commission (No. 285-14-25082014), and the study was performed in accordance with the Declaration of Helsinki on medical protocols and ethics. As pseudonymization of the CT data was performed, no requirement of informed consent was requested by the ethics committee.
Disclosures: The authors declared no conflicts of interest with respect to the research, authorship, and/or publication of this article.
References
1. Gould DJ, Roth FS and Soparkar CNS. The diagnosis and treatment of thyroid-associated ophthalmopathy. Aesth Plast Surg. 2012;36(3):638-648. doi:10.1007/s00266-011-9843-4
2. Bartalena L, Baldeschi L, Dickinson A, et al. European Group on Graves’ Orbitopathy (EUGOGO): consensus statement of the European Group on Graves’ orbitopathy (EUGOGO) on management of GO. Eur J Endocrinol. 2008;158(3):273-285. doi:10.1530/EJE-07-0666.
3. Panagiotou G, Perros P. Asymmetric Graves’ orbitopathy. Front Endocrinol. 2020;11:1-5. doi:10.3389/fendo.2020.611845
4. Perros P, Zarkovic MP, Panagiotou GC, et al. Asymmetry indicates more severe and active disease in Graves’ orbitopathy: results from a prospective cross-sectional multicentre study. J Endocrinol Invest. 2020;43(12):1717-1722. doi:10.1007/s40618-020-01258-w
5. Bagheri A, Shahraki K, Arabi A, et al. Normal exophthalmometry values in Iranian population: a meta-analysis. J Ophthalmic Vis Res. 2021;16(3):470-477. doi:10.18502/jovr.v16i3.9441
6. Kashkouli MB, Beigi B, Noorani MM, et al. Hertel exophthalmometry: reliability and interobserver variation. Orbit. 2003;22(4):239-245. doi:10.1076/orbi.22.4.239.17245
7. Cole HP, Couvillion JT, Fink AJ, et al. Exophthalmometry: a comparative study of the Naugle and Hertel instruments. Ophthalm Plast Reconstr Surg. 1997;13(3):189-194.
8. Park NR, Moon JH, Lee JK. Hertel exophthalmometer versus computed tomography can in proptosis estimation in thyroid-associated orbitopathy. Clin Ophthalmol. 2019;13(8):1461-1467. doi:10.2147/OPTH.S216838
9. Ramli N, Kala S, Samsudin A, et al. Proptosis-correlation and agreement between Hertel exophthalmometry and computed tomography. Orbit. 2015;34(5):257-262. doi:10.3109/01676830.2015.1057291
10. Nkenke E, Maier T, Benz M, et al. Hertel exophthalmometry versus computed tomography and optical 3D imaging for the determination of the globe position in zygomatic fractures. Int J Oral Maxillofac Surg. 2004;33(2):125-133. doi:10.1054/ijom.2002.0481
11. Hierl KV, Krause M, Kruber D, et al. 3-D cephalometry of the orbit regarding endocrine orbitopathy exophthalmos, and sex. Plos One. 2022 Mar 11;17(3):e0265324.1-20. doi:10.1371/journal.pone.0265324
12. Hierl T, Huempfner-Hierl H, Kruber D, et al. Requirements for a universal image analysis tool in dentistry and oral and maxillofacial surgery. In: Daskalaki A, ed. Dental Computing and Applications: Advanced Techniques for Clinical Dentistry. IGI Global; 2009:79-89.
13. Krause M, Kruber D, Hümpfner-Hierl H, et al. Three-dimensional changes of scleral show after surgical treatment of endocrine orbitopathy. J Craniomaxillofac Surg. 2018;46(1):44-49. doi:10.1016/j.jcms.2017.10.021
14.Chang AA, Bank A, Francis IC, et al. Clinical exophthalmometry: a comparative study of the Luedde and Hertel exophthalmometers. Austr New Zeal J Ophthalmol. 1995;23(4):315-318. doi:10.1111/j.1442-9071.1995.tb00182.x
15. Genders SW, Mourits D, Jasem M, et al. Parallax-free exophthalmometry: a comprehensive review of the literature and the introduction of the first parallax-free exophthalmometer. Orbit. 2015;34(1):23-29. doi:10.3109/01676830.2014.963877
16. Ahmadi H, Shams PN, Davies NP, et al. Age-related changes in the normal sagittal relationship between globe and orbit. J Plast Reconstr Aesthet Surg. 2007;60(3):246-250. doi:10.1016/j.bjps.2006.07.001.
17. Ji Y, Qian Z, Dong Y, et al. Quantitative morphometry of the orbit in Chinese adults based on a three-dimensional reconstruction method. J Anat. 2010;217(5):501-506. doi:10.1111/j.1469-7580.2010.01286.x
18. Olszweski R, Zech F, Cosnard G, et al. Three-dimensional computed tomography cephalometric craniofacial analysis: experimental validation in vitro. Int J Oral Maxillofac Surg. 2007;36(9):828-833. doi:10.1016/j.ijom.2007.05.022
19. Bookstein FL. A Course in Morphometrics for Biologists. Cambridge University Press; 2018.
20. Wärmländer SKTS, Garvin H, Guyomarch P, et al. Landmark typology in applied morphometric studies: what´s the point? Anatom Rec. 2019;302(7):1144-1153. doi:10.1002/ar.24005
21. Bajaj K, Rathee P, Jain P, et al. Comparison of the reliability of anatomic landmarks based on PA cephalometric radiographs and 3D CT scans in patients with facial asymmetry. Int J Clin Ped Dent. 2011;4(3):213-223. doi:10.5005/jp-journals-10005-1112
22. Naji P, Alsufyani NA, Lagravere MO. Reliability of anatomic structures as landmarks in three-dimensional cephalometric analysis using CBCT. Angle Orthod. 2014;84(5):762-772. doi:10.2319/090413-652.1
23. Lagravere MO, Low C, Flores-Mir C, et al. Intraexaminer and interexaminer reliabilities of landmark identification on digitized lateral cephalograms and formatted 3-dimensional cone-beam computerized tomography images. Am J Orthod Dentofac Orthop. 2010;137(5):598-604. doi:10.1016/j.ajodo.2008.07.018
24. Frongia G, Bracco P and Piancino MG. Three-dimensional cephalometry: a method for the identification and for the orientation of the skull after cone-beam computed tomographic scan. J Craniofac Surg. 2013;24(3):e308-e311. doi:10.1097/SCS.0b013e31828f2e8e
25. Frongia G, Piancino MG, Bracco AA, et al. Assessment of the reliability and repeatability of landmarks using 3-D cephalometric software. J Craniomand Prac. 2012;30(4):255-263. doi:10.1179/crn.2012.039
26. Moreira CR, Sales MAO, Lopes PML, et al. Assessment of linear and angular measurements on three-dimensional cone-beam computed tomographic images. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2009;108(3):430-436. doi:10.1016/j.tripleo.2009.01.032
27. Kavoussi SC, Giacometti JN, Servat JJ, et al. The relationship between sex and symmetry in thyroid eye disease. Clin Ophthalmol. 2014;8(7):1295-1300. doi:10.2147/OPTH.S61041
Sign Up Today
