Computed tomography and magnetic resonance imaging of the orbit in the diagnosis and treatment of thyroid-associated orbitopathy – experience from practice. A Review
Authors:
M. Karhanová 1,2; J. Čivrný 3,4; J. Kalitová 1; J. Schovánek 5,6; B. Pašková 1,2; Z. Schreiberová 1,2; P. Hübnerová 1,2
Authors place of work:
Oční klinika, Fakultní nemocnice Olomouc
1; Oční klinika, Lékařská fakulta Univerzity Palackého Olomouc
2; Radiologická klinika, Fakultní nemocnice Olomouc
3; Radiologická klinika, Lékařská fakulta Univerzity Palackého Olomouc
4; III. interní klinika - nefrologická, revmatologická a endokrinologická, Fakultní nemocnice Olomouc
5; III. interní klinika - nefrologická, revmatologická a endokrinologická, Lékařská fakulta Univerzity Palackého Olomouc
6
Published in the journal:
Čes. a slov. Oftal., 79, 2023, No. 6, p. 283-292
Category:
Review Article
doi:
https://doi.org/10.31348/2023/10
Summary
The purpose is to acquaint readers with the contribution of imaging methods (IMs) of the orbit, specifically computed tomography (CT) and magnetic resonance imaging (MRI), in the diagnosis of thyroid-associated orbitopathy (TAO).
Methods: IMs of the orbit are an indispensable accessory in the clinical and laboratory examination of TAO patients. The most frequently used and probably most accessible method is an ultrasound examination of the orbit (US), which, however, has a number of limitations. Other methods are CT and MRI. Based on the published knowledge implemented in our practice and several years of experience with the diagnosis and treatment of TAO patients, we would like to point out the benefits of CT and MRI in the given indications: visualisation of the extraocular muscles, assessment of disease activity, diagnosis of dysthyroid optic neuropathy and differential diagnosis of other pathologies in the orbit. Our recommendation for an ideal MRI protocol for disease activity evaluation is also included.
Conclusion: IMs play an irreplaceable role not only in the early diagnosis of TAO, but also in the monitoring of the disease and the response to the applied treatment. When choosing a suitable IM for this diagnosis, a number of factors must always be taken into account; not only availability, cost and burden for the patient, but especially the sensitivity and specificity of the given method for the diagnosis of TAO.
Keywords:
activity – computed tomography – extraocular muscles – magnetic resonance imaging – thyroid-associated orbitopathy
INTRODUCTION
Thyroid-associated orbitopathy (TAO) is a serious, chronic eye disease associated with autoimmune thyroid gland disorder, most commonly with Graves-Basedow disease. The course of the disease typically has three phases. The first active progressive phase, accompanied by varying degrees of inflammatory symptoms, is followed by a plateau phase in which the condition gradually stabilizes. In the third, final phase, gradual fibrosis of tissues occurs when the disease activity ceases entirely, and cosmetic and functional changes are now permanent.
Increased intraocular pressure (IOP) in patients with TAO was first described more than 100 years ago. Whereas previously published studies did not primarily focus on disease phase and severity (which may have been the reason for the ambiguous to contradictory results), studies published in the last decade have begun to take these factors into account. The prevalence of intraocular hypertension (IH) is undoubtedly higher in patients with TAO than in the general population [1,2] and is also associated with a more severe involvement of the orbital structures, particularly the extraocular muscles [3]. In cases of long-term active TAO, IH is considered a risk factor for the onset of open-angle glaucoma [4]. However, a higher prevalence of open-angle glaucoma has not been unequivocally confirmed in patients with TAO.
In TAO, it is necessary to devote special attention to the technique of measuring IOP, particularly when the extraocular muscles are affected, and the eyeball is deviated in either hypotropia or esotropia. However, based on our practical experience, the type of tonometer used is also essential. Kuebler et al. [5] found that whereas non-contact tonometers (Corvis ST and Ocular Response Analyser; ORA) significantly overestimated IOP in comparison with Goldmann applanation tonometry (GAT), the values obtained using the iCARE rebound tonometer were comparable with those obtained with GAT. However, the study included patients with varying severity of the disease (and therefore varying degrees of involvement of the extraocular muscles) in both the active and inactive phases of TAO.
Our study aimed to compare the concordance of IOP measurement in patients with TAO in the inactive phase using three different types of tonometers: iCARE rebound tonometer, Goldmann applanation tonometer (GAT), and non-contact tonometer (NCT). We only included patients without diplopia in direct forward gaze position, i.e., in other words, those suitable for district eye clinic referral and, therefore, not requiring follow-up in a tertiary center. These were often patients in whom chronic effects of TAO may not be readily apparent.
MATERIAL AND METHOD
Study design and cohort characteristics
A total of 98 eyes of 49 adult patients (36 women, 13 men) aged 19 to 70 years (median 55.0 years) who attended the consulting center for TAO at the Department of Ophthalmology at the Faculty of Medicine and Dentistry of Palacký University and the University Hospital in Olomouc, were included in the study. All the patients had received the diagnosis and treatment of thyroid disease and had a history of mild to moderate TAO (Table 1) which had previously required immunosuppressant therapy (oral prednisone, or IV methylprednisolone). However, the patients had not been receiving systemic therapy for at least one year. TAO was inactive with a Clinical Activity Score (CAS) of 0 (Table 2). We performed a comprehensive eye examination in all the patients (determination of visual acuity, examination of the anterior and posterior eye segments and of the periocular region). We devoted special attention to eyeball motility and the presence of diplopia. All patients in whom diplopia (permanent or intermittent) persisted in direct forward gaze position were excluded, as were patients who already wore prismatic correction. Residual diplopia in maximal gaze directions, which was unnoticed by patients in everyday life, was not among the exclusion criteria. Additional exclusion criteria were previous eye surgery (anti-glaucomatous, vitreoretinal, refractive), strabismus surgery, condition following decompression of the orbit, any corneal pathology, and astigmatism of more than 2.5 diopters. IOP was measured in all the patients with the aid of three different types of tonometers: Goldmann applanation tonometer (GAT; Köniz, Switzerland); iCARE rebound tonometer (iCARE; Tiolat, Helsinki, Finland); and non-contact tonometer (NCT; Reichert AT 555). All the measurements were performed during the morning hours. We always performed a measurement using NCT first, followed by a measurement with the aid of iCARE and GAT. A pause of at least five minutes was allowed between each measurement, and the measurements were performed by a single examiner (MK).
The Ethics Committee of the University Hospital and the Faculty of Medicine and Dentistry at Palacký University Olomouc approved the study protocol. The study was conducted in accordance with Good Clinical Practice and the Helsinki Declaration.
Statistical analysis
The software SPSS version 15 (SPSS Inc., Chicago, USA) and the software MedCalc version 20.105 (MeCalc Software Ltd, Belgium) were used for the statistical analysis of the data. The results were evaluated by the Wilcoxon paired test and Bonferroni correction. The dependency between the values measured by GAT, NCT, and iCARE was assessed with the Spearman correlation coefficient and further analyzed with the Bland-Altman analysis. The normality of the data was verified using the Shapiro-Wilk test. The tests were conducted at a level of significance of 0.05.
RESULTS
The mean IOP measured using GAT was 18.1 ±2.4 mmHg (13–25 mmHg), using NCT 22.3 ±5.0 mmHg (13–35 mmHg), and using iCARE 18.0 ±2.4 mmHg (13.3–26 mmHg). The values of IOP measured with the aid of NCT were significantly higher (p < 0.0001) than those obtained with GAT and iCARE.
Using the Bland-Altman analysis, we found that the mean difference between GAT and iCARE is −0.1 ±1.16 mmHg (limits of agreement −2.4 to 2.1), and there is no statistically significant difference between the methods. It is evident from Graph 1 that there is no systematic difference between the methods (the differences are distributed symmetrically around zero), and there is no perceptible trend in the differences.
The mean difference between GAT and NCT was 4.2 ±3.6 mmHg (limits of agreement −2.8 to 11.2), and between iCARE and NCT, the mean difference was −4.3 ±3.7 mmHg (limits of agreement −11.6 to 2.9). In both cases, the 95% confidence interval of the mean differences does not cover zero, and there is a statistically significant difference between the methods. It is evident from the Bland-Altman analysis in Graphs 2 and 3 that a systematic difference exists between the methods (the differences are not distributed symmetrically around zero). In Graph 2, most of the differences are positive, meaning that higher values were measured with NCT than with GAT. A trend is manifested in the differences; thus, the differences depend upon the mean (the greater the mean, the greater the difference). In Graph 3, a significant trend is also obvious. Almost all the values measured with the iCARE method were lower than those measured using the NCT method.
We, therefore, did not determine any statistically significant difference (p = 1.000) between the GAT and iCARE methods. By contrast, we determined a statistically significant difference between GAT and NCT (p < 0.0001) and between iCARE and NCT (p < 0.0001).
A Spearman correlation analysis confirmed that GAT correlates most strongly with iCARE (Table 3). It is evident in the point correlation graph (Graph 4) that the difference between the GAT and NCT methods increases along with the increase in IOP values. The correlation between the GAT and iCARE methods and iCARE and NCT is illustrated in Graphs 5 and 6.
DISCUSSION
Glaucoma in the setting of TAO is classified among secondary open-angle glaucoma caused by an extrabulbar pathology. The pathogenetic mechanisms, which in some patients with TAO may lead to an increase in IOP, are complex and typically involve a combination of several factors. They always depend mainly on disease duration and phase (active, inactive), as well as the type of predilection for the involvement of the orbital tissue (extraocular muscles, fat tissue), as to which of the factors will contribute most to the increase in IOP in a particular patient. One of the main causal factors is an increase in episcleral venous pressure and constriction of venous outflow from the orbit, which occurs as a consequence of inflammatory infiltration of the retrobulbar orbital tissues and an expansion of the fat and conjunctival tissue (and the extraocular muscles). Among other factors, during the course of TAO, excessive production of glycosaminoglycans also occurs, possibly even in the trabecular meshwork, which may lead to an increase in outflow resistance. The last important known mechanism that may increase IOP is the degree of involvement of the extraocular muscles [6]. In the acute phase of the disease, inflammatory infiltration and edema of the muscles occur.
Consequently, the relaxation capacity of the muscle is impaired, and an insufficiency of a corresponding antagonist causes diplopia. In this phase, we usually find only clinically discrete motility disorders in maximal gaze directions (most often disorders of elevation in abduction). If the disease progresses to the next phase, gradual fibrosis of the muscles occurs, and diplopia may become permanent even in the primary position. The extraocular muscles may progressively transform into rigid fibrous strips without active or passive motility. Because the medial and inferior rectus muscles are the most commonly affected [7], the eyeball is generally deviated downwards or in esotropia in the final phase of the disease.
It is precisely due to the above-described changes (restrictive myopathy) that increased IOP (mostly up to 15 mmHg) in upward gaze is a relatively common finding in patients with TAO. A linear dependency has been demonstrated between the degree of eye deviation (hypotropia) and increased IOP in upward gaze [8,9,10]. This phenomenon occurs as a result of the so-called "pincer mechanism". In an effort to fix upward gaze (in the case of hypotropia of the eye, an effort to fix direct forward gaze), the tension of the superior rectus muscle increases, but the affected inferior rectus muscle does not relax. This results in compression of the eyeball and, subsequently, an increase in episcleral venous pressure and IOP. This theory is in accordance with published studies which have confirmed that a significant reduction in IOP occurs following surgery for restrictive strabismus or following intramuscular administration of botulinum toxin A [11,12].
As a result, measurement of IOP in patients with TAO with eye deviation due to restrictive myopathy (especially hypotropia of the eye) is challenging. Measurement with GAT is considered to be the gold standard. However, it is necessary to be aware that the precision and reliability of measurement are influenced not only by corneal thickness, but also by corneal curvature and other biomechanical properties. We measure with GAT as standard in the center of the cornea at the slit lamp. If there is significnat hypotropia or esotropia of the eye, we have to perform the measurement in the periphery of the cornea, and in extreme cases even partially on the sclera. However, in the periphery, the cornea has different biomechanical properties: it is thicker than in the center and has a flatter curvature, to name only a few. In particular, corneal thickness may, therefore, lead to a potential overestimation of IOP. On the other hand, it has been demonstrated that corneal hysteresis is lower in patients with TAO than in the healthy population [13,14]. However, despite all these circumstances, measurement of IOP with the aid of GAT in the case of TAO remains the best possible option. Based on our experience with patients with TAO, we do not recommend NCT because it often falsely produces very high values, particularly in patients with an involvement of the inferior rectus muscle (if the eye is in the primary position in hypotropia). The patient attempts to fix the affected eye into the device, and the above-described pincer mechanism results in an increase in IOP.
Kuabler et al. [5] compared the results of IOP measurement in 29 patients with TAO using four different tonometers (GAT, iCARE, ORA, Corvis) demonstrating concordance only between GAT and iCARE. In comparison with GAT, ORA and Corvis overestimated IOP. Nevertheless, this study included patients with mild, moderate, and severe forms of TAO in the active and inactive phases. Therefore, the study did not consider whether (and to what extent) motility was impaired. Pérez-López et al. [14] focused on the biomechanical properties of the cornea in 30 patients in the inactive phase of TAO, among other factors, also comparing the values of IOP measured using GAT and ORA, and arrived at the same results. The values of IOP obtained with ORA were significantly higher than those obtained with GAT.
Falsely high values of IOP may be measured using non-contact types of tonometers in eyes with restrictive myopathy (primarily in hypotropia) due to the pincer mechanism, which is well known, and we can confirm this from our own experience. However, our study aimed to determine the concordance between the measured values of IOP with the aid of three types of tonometers in patients without significant motility disorders after suffering from TAO, which required systemic therapy. We only included patients without an apparent eye deviation (i.e., without diplopia in direct forward gaze) in the study, and we excluded all patients with prismatic correction. Our results confirmed that, in this group of patients, the IOP values measured using NCT were significantly higher than in the case of GAT or iCARE. This can be explained particularly by the fact that when using a sufficiently sensitive examination method, a certain degree of involvement of the extraocular muscles can be identified in most patients with TAO. In patients who require systemic therapy in the active phase (i.e., moderate and severe forms of TAO; mild form in case it significantly affects the quality of life), the involvement of at least one muscle is virtually inevitable. In the case of sufficiently intensive systemic therapy, we can prevent permanent consequences in terms of diplopia in direct forward gaze; however, we cannot prevent a certain degree of reparative changes in the muscle tissue. The result may be only subjectively non-troublesome diplopia in a certain maximal gaze direction, or mild phoria, which patients with good binocular functions can compensate for without difficulties. Upon measurement of IOP with the aid of NCT, the head position (according to the placement of the forehead) is often inclined slightly forward. Upon fixation on the central point during measurement, an elevation in IOP may occur due to the above-described muscle changes (particularly if the inferior rectus muscle is affected). This hypothesis is supported also by the fact that the increase in IOP in upward gaze is typically more pronounced in patients with TAO than in healthy individuals [9].
By contrast, the measurement results using an iCARE tonometer in our cohort corresponded with the values measured using GAT. The iCARE tonometer is based on the method of "rebound tonometry". This well-tolerated method does not require corneal anesthesia and can be used in immobile patients and in children. In our study, we used the tonometer iCARE PRO (other types are the older TA01, the newer HOME, and the ic100V) [16]. It is the iCARE PRO that is used most frequently in published studies and that demonstrates good concordance with GAT in healthy individuals and in patients with glaucomatous disease [17,18,19]. Experience with the iCARE tonometer in patients with TAO has been published sporadically, nonetheless with good results, as discussed above [5,14].
Our study had relatively strict inclusion criteria; to the best of our knowledge, it is the first with this design. However, its limitations include the fact that measurements were performed by a single examiner who therefore did not perform the applanation measurement blind (this one was the last to be performed). It would therefore be appropriate to verify the results in the future in a further study on which we are currently working.
CONCLUSION
Based on our results and our experience from practice, we recommend measurement of IOP with the aid of GAT or with an iCARE tonometer in all patients with a history of TAO since NCT may overestimate IOP values. We recommend these methods for patients with TAO with no signs of restrictive strabismus and eye deviation apparent in the primary gaze direction. For this reason, it is always necessary to inquire patients about a possible history of TAO in outpatient practice.
Zdroje
1. Kahaly G. Imaging in thyroid-associated orbitopathy. Eur J Endocrinol. 2001:107-118. https://doi.org/10.1530/eje.0.1450107
2. Rabinowitz MP, Carrasco JR. Update on advanced imaging options for thyroid-associated orbitopathy. Saudi J Ophthalmol. 2012;26:385-392. https://doi.org/10.1016/j.sjopt.2012.07.006
3. Karhanova M, Kovar R, Frysak Z et al. Correlation between magnetic resonance imaging and ultrasound measurements of eye muscle thickness in thyroid-associated orbitopathy. Biomed Pap. 2015;159:307-312. https://doi.org/10.5507/bp.2014.001
4. Jiskra J, Gabalec F, Diblík P et al. Doporučený postup pro diagnostiku a léčbu endokrinní orbitopatie, NOVELIZACE. 3/2022 n.d.
5. Česká oftalmologická společnost ČLS JEP. Doporučený postup pro diagnostiku a léčbu endokrinní orbitopatie [internet]. Available from: www.oftalmologie.com/cs/doporucene-postupy/doporuceny-postup-pro-diagnostiku-a-lecbu-endokrinni-orbitopatie.html Czech. n.d.
6. Shampo MA, Kyle RA, Steensma DP. Isidor Rabi-1944 Nobel Laureate in Physics. Mayo Clin Proc. 2012;87:e11. https://doi.org/10.1016/j.mayocp.2011.11.012
7. Pohost GM, Elgavish GA, Evanochko WT. Nuclear magnetic resonance imaging: With or without nuclear? J Am Coll Cardiol. 1986;7:709-710. https://doi.org/10.1016/S0735-1097(86)80486-7
8. Bloch F. Nuclear Induction. Phys Rev. 1946;70:460-474. https://doi.org/10.1103/PhysRev.70.460
9. Bley TA, Wieben O, François CJ, Brittain JH, Reeder SB. Fat and water magnetic resonance imaging: Fat and Water MRI. J Magn Reson Imaging. 2010;31:4-18. https://doi.org/10.1002/jmri.21895
10. Rana K, Juniat V, Patel S, Selva D. Extraocular muscle enlargement. Graefes Arch Clin Exp Ophthalmol. 2022. https://doi.org/10.1007/s00417-022-05727-1
11. Kuriyan AE, Woeller CF, O’Loughlin CW, Phipps RP, Feldon SE. Orbital Fibroblasts From Thyroid Eye Disease Patients Differ in Proliferative and Adipogenic Responses Depending on Disease Subtype. Investig Opthalmology Vis Sci. 2013;54:7370. https://doi.org/10.1167/iovs.13-12741
12. Ozgen A, Ariyurek M. Normative measurements of orbital structures using CT. Am J Roentgenol. 1998;170:1093-1096. https://doi.org/10.2214/ajr.170.4.9530066
13. Dodds NI, Atcha AW, Birchall D, Jackson A. Use of high-resolution MRI of the optic nerve in Graves’ ophthalmopathy. Br J Radiol. 2009;82:541-544. https://doi.org/10.1259/bjr/56958444
14. Barrett L, Glatt JH, Burde RM. Ronald, Gado H. Optic nerve dysfunction in thyroid eye disease: CT. Head Neck Radiol. 1988;167:503-507. https://doi.org/10.1148/radiology.167.2.3357962.
15. Monteiro MLR, Gonçalves ACP, Silva CTM, Moura JP, Ribeiro CS, Gebrim EMMS. Diagnostic Ability Of Barrett’s Index to Detect Dysthyroid Optic Neuropathy Using Multidetector Computed Tomography. Clinics. 2008;63:301-306. https://doi.org/10.1590/S1807-59322008000300003
16. Nagy E, Toth J, Kaldi I et al. Graves’ ophthalmopathy: eye muscle involvement in patients with diplopia. Eur J Endocrinol. 2000;142:591-597. https://doi.org/10.1530/eje.0.1420591
17. Majos A, Pajak M, Stefanczyk L. Magnetic Resonance evaluation of disease activity in Graves’ ophthalmopathy: T2-time and signal intensity of extraocular muscles. Med Sci Monit. 2007;13:44-48.
18. Kirsch EC, Kaim AH, De Oliveira MG, von Arx G. Correlation of signal intensity ratio on orbital MRI-TIRM and clinical activity score as a possible predictor of therapy response in Graves’ orbitopathy—a pilot study at 1.5 T. Neuroradiology. 2010;52:91-97. https://doi.org/10.1007/s00234-009-0590-z
19. Mayer EJ, Fox DL, Herdman G et al. Signal intensity, clinical activity and cross-sectional areas on MRI scans in thyroid eye disease. Eur J Radiol. 2005;56(1):20-24. https://doi.org/10.1016/j.ejrad.2005.03.027
20. Yokoyama N, Nagataki S, Uetani M, Ashizawa K, Eguchi K. Role of Magnetic Resonance Imaging in the Assessment of Disease Activity in Thyroid-Associated Ophthalmopathy. Thyroid. 2002;12:223-227. https://doi.org/10.1089/105072502753600179
21. Politi LS, Godi C, Cammarata G et al. Magnetic resonance imaging with diffusion-weighted imaging in the evaluation of thyroid-associated orbitopathy: getting below the tip of the iceberg. Eur Radiol. 2014;24:1118-1126. https://doi.org/10.1007/s00330-014-3103-3
22. Prummel MF, Gerding MN, Zonneveld FW, Wiersinga WM. The usefulness of quantitative orbital magnetic resonance imaging in Graves’ ophthalmopathy: Quantitative orbital MRI in Graves’ ophthalmopathy. Clin Endocrinol (Oxf). 2001;54:205-209. https://doi.org/10.1046/j.1365-2265.2001.01220.x
23. Cheng HLM, Stikov N, Ghugre NR, Wright GA. Practical medical applications of quantitative MR relaxometry. J Magn Reson Imaging. 2012;36:805-824. https://doi.org/10.1002/jmri.23718
24. Jiang H, Wang Z, Xian J, Li J, Chen Q, Ai L. Evaluation of rectus extraocular muscles using dynamic contrast- enhanced MR imaging in patients with Graves’ ophthalmopathy for assessment of disease aktivity. Acta Radiol. 2012;53(1):87-94. https://doi.org/ 10.1258/ar.2011.110431
25. Das T, Roos JCP, Patterson AJ, Graves MJ, Murthy R. T2-relaxation mapping and fat fraction assessment to objectively quantify clinical activity in thyroid eye disease: an initial feasibility study. Eye. 2019;33:235-243. https://doi.org/10.1038/s41433-018-0304-z
26. Lin C, Song X, Li L et al. Detection of active and inactive phases of thyroid-associated ophthalmopathy using deep convolutional neural network. BMC Ophthalmol. 2021;21:39. https://doi.org/10.1186/s12886-020-01783-5
27. Yuan MK, Tsai DC, Chang SCet al. The Risk of Cataract Associated With Repeated Head and Neck CT Studies: A Nationwide Population-Based Study. Am J Roentgenol. 2013;201:626-630. https://doi.org/10.2214/AJR.12.9652
28. Bednarczuk T, Brix TH, Schima W, Zettinig G, Kahaly GJ. 2021 European Thyroid Association Guidelines for the Management of Iodine-Based Contrast Media-Induced Thyroid Dysfunction. Eur Thyroid. J 2021;10:269-284. https://doi.org/10.1159/000517175
Štítky
OphthalmologyČlánok vyšiel v časopise
Czech and Slovak Ophthalmology
2023 Číslo 6
Najčítanejšie v tomto čísle
- The Far Nasal Part of the Visual Field – Part I
- Binocular Function in Adults before and after Strabismus Surgery
- Computed tomography and magnetic resonance imaging of the orbit in the diagnosis and treatment of thyroid-associated orbitopathy – experience from practice. A Review
- Comparison of Three Methods of Tonometry in Patients with Inactive Thyroid-Associated Orbitopathy