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Thyroid ophthalmopathy revisited

Abstracts

Thyroid ophthalmopathy is an autoimmune orbital disorder closely associated with Graves' disease, although both conditions may also occur isolatedly. Thyroid ophthalmopathy may precede, coincide or follow the thyroid dysfunction onset and may rarely occur in euthyroid and hypothyroid patients. The extraocular muscles are most frequently involved and become enlarged resulting in ophthalmoplegia and proptosis. Other relevant signs include palpebral retraction, conjuctival hyperemia and periorbitary edema. Visual loss may occur in association with compressive optic neuropathy at the orbital apex. Thyroid ophthalmopathy is characterized by inflammation, congestion, hypertrophy and fibrosis involving fat and the orbital muscles. The disease activity is divided into two phases: an acute or inflammatory phase and a second one corresponding to an inactive phase associated with fibrotic changes and fat infiltration of the retrobulbar tissues. The diagnosis is based on clinical findings and imaging methods are indicated in case of doubt or suspicion of optic neuropathy. Computed tomography and magnetic resonance imaging can confirm the diagnosis, allowing the evaluation of the critical region of the orbital apex. Magnetic resonance imaging is the method of choice considering the superior tissue contrast resolution, besides the capacity of evaluating the disease activity by means of long TR sequences and detecting inflammatory changes, with a relevant role in a timely therapeutic planning, which may improve the prognosis.

Thyroid ophthalmopathy; Extraocular muscles; Magnetic resonance imaging; Computed tomography


A oftalmopatia tireoidea é doença orbitária autoimune intimamente associada com o hipertireoidismo, porém podendo existir separadamente. Pode preceder, coincidir ou suceder o início da disfunção tireoidea, raramente ocorrendo em eutireoideos ou hipotireoideos. Os músculos extraoculares são os principais alvos acometidos e tornam-se aumentados de volume, determinando oftalmoplegia e proptose. Outros sinais importantes incluem retração palpebral, hiperemia conjuntival e edema periorbitário. Perda visual pode ocorrer se há compressão do nervo óptico no ápice orbitário. A oftalmopatia tireoidea é caracterizada por inflamação, congestão, hipertrofia e fibrose da gordura e músculos orbitários. A atividade da doença é dividida em fase aguda ou inflamatória, seguida pela fase inativa associada com alterações fibróticas e infiltração gordurosa. O diagnóstico é clínico, e quando este é difícil ou se suspeita de neuropatia óptica os métodos de imagem são indicados. A tomografia computadorizada e a ressonância magnética podem confirmar o diagnóstico e avaliar a área crítica do ápice orbitário. A ressonância magnética é superior, em virtude da resolução tecidual e da sua capacidade de avaliar a atividade da doença (mediante sequências com TR longo) e detectar alterações inflamatórias, auxiliando o planejamento terapêutico no momento certo, melhorando o prognóstico.

Oftalmopatia tireoidea; Músculos extraoculares; Imagem por ressonância magnética; Tomografia computadorizada


REVIEW ARTICLE

Karina Freitas Soares Machado; Marcelo de Mattos Garcia

Titular Members of Colégio Brasileiro de Radiologia e Diagnóstico por Imagem (CBR), São Paulo, SP, MDs, Radiologists at Axial Centro de Imagem, Belo Horizonte, MG, Brazil

Mailing address

ABSTRACT

Thyroid ophthalmopathy is an autoimmune orbital disorder closely associated with Graves' disease, although both conditions may also occur isolatedly. Thyroid ophthalmopathy may precede, coincide or follow the thyroid dysfunction onset and may rarely occur in euthyroid and hypothyroid patients. The extraocular muscles are most frequently involved and become enlarged resulting in ophthalmoplegia and proptosis. Other relevant signs include palpebral retraction, conjuctival hyperemia and periorbitary edema. Visual loss may occur in association with compressive optic neuropathy at the orbital apex. Thyroid ophthalmopathy is characterized by inflammation, congestion, hypertrophy and fibrosis involving fat and the orbital muscles. The disease activity is divided into two phases: an acute or inflammatory phase and a second one corresponding to an inactive phase associated with fibrotic changes and fat infiltration of the retrobulbar tissues. The diagnosis is based on clinical findings and imaging methods are indicated in case of doubt or suspicion of optic neuropathy. Computed tomography and magnetic resonance imaging can confirm the diagnosis, allowing the evaluation of the critical region of the orbital apex. Magnetic resonance imaging is the method of choice considering the superior tissue contrast resolution, besides the capacity of evaluating the disease activity by means of long TR sequences and detecting inflammatory changes, with a relevant role in a timely therapeutic planning, which may improve the prognosis.

Keywords: Thyroid ophthalmopathy; Extraocular muscles; Magnetic resonance imaging; Computed tomography.

INTRODUCTION

Thyroid ophthalmopathy is an autoimmune orbital disorder closely associated with hyperthyroidism (Graves' disease), although both conditions may also occur isolatedly.

The most accepted theory to explain the association between thyroid ophthalmopathy and autoimmune thyroid disease comprises a possible cross-reaction of sensitized T-lymphocytes and/or antibodies against common antigens for both the thyroid and the orbita(1).

In a great number of cases, thyroid ophthalmopathy may occur concomitantly with the onset of hyperthyroidism, but also it may precede or follow the onset of the thyroid dysfunction(1,2), although in few cases euthyroid and hypothyroid patients may be affected(3,4). In most of cases, the disease is self-limited, and if a treatment is indicated, systemic corticoid therapy is the main strategy adopted(1).

Thyroid ophthalmopathy is the most frequent cause of orbital disease in the adult population, responsible for 15% to 28% of cases of unilateral exophthalmia and 80% of cases of bilateral exophthalmia(1,2).

The active phase of the disease is progressive, lasting from several months to few years, usually from one to three years, with the inflammation settling to a more quiescent or inactive phase characterized by the presence of fibrosis(2,5).

This disease is characterized by inflammation, congestion, hypertrophy, fat and orbital muscles fibrosis leading to increase in volume of these muscles(1).

Supplementary evaluation is performed with computed tomography (CT) and magnetic resonance imaging (MRI) which plays a significant role in the demonstration and better characterization of a wide spectrum of clinical findings.

CLINICAL AND IMAGING FINDINGS

The natural history of the disease is divided into an acute or inflammatory, progressive phase histologically associated with lymphocytic infiltration and edema, followed by an inactive and fibrotic phase associated with fibrotic alterations and fat infiltration of retro-orbital tissues, particularly the extraocular muscles(4,5).

Usually, signs and symptoms of thyroid ophthalmopathy develop within one year after the thyroid dysfunction onset.

Extraocular muscles are most frequently involved by the immunological phenomenon and, as a result, they present increase in volume which, in association with abnormalities in the retro-orbital fat, determines ophthalmoplegia and proptosis(1,6). Other relevant clinical signs determined by inflammatory alterations and/or vascular congestion include lower and upper eyelid retraction (Figure 1), conjunctival hyperemia and periorbital edema(1,2), as well as sequelae resulting from extraocular muscles hypertrophy, such as visual loss resulting from corneal ulceration secondary to proptosis and optic neuropathy caused by optic nerve compression at the apex of the orbit(1,4,7,8).


Nearly always, exophthalmia is bilateral and generally relatively symmetrical. The inferior rectus muscle is most frequently involved, followed by the medial rectus, superior rectus and lateral rectus muscles(1,2).

The disease diagnosis is based on clinical findings, and imaging methods are indicated in cases where the diagnosis is dubious or in the suspicion of optic neuropathy(2).

CT and MRI are useful methods for confirming the diagnosis by visualizing the orbital muscles and fat hypertrophy, and evaluating the critical region of the orbital apex(3). Many times, increased orbital fat volume and resulting proptosis will be observed as the sole imaging finding(3) (Figure 2).


Muscles involvement is typically ventral, sparing the tendinous insertions (Figure 3), in association with other useful finding, i.e., hypodense foci at CT and hyperintense foci on T2-weighted MRI, involving the muscle bellies, probably because of inflammatory infiltrate (Figure 3).


Other imaging findings in the active or inflammatory phase of the disease include lacrimal gland hypertrophy and prolapse (Figure 4), palpebral edema, anterior displacement of the orbital septum. Optic nerve stretching and orbital bone wall remodeling(1,3,9-11).


Extraocular muscles thickening can also be observed in other diseases that should be eventually considered in the differential diagnosis; among them, orbital pseudotumor and lymphoproliferative processes. In these cases, unilateral involvement is most frequently observed without sparing the tendinous insertions(12). Additionally, the clinical condition is usually associated with pain. Most rarely, orbital amyloidosis and metastatic neoplastic process can be mentioned, the latter being usually secondary to breast neoplasm, in general with a nodular pattern(12).

Axial images are utilized to estimate the proptosis degree, the volumetric increase of the medial and lateral rectus muscles (Figure 5) and the relation between these muscles and the optic nerve. The optic nerve compression at the orbital apex also is best evaluated in the axial plane with the aid of coronal and sagittal images(10) (Figure 6). The coronal plane is best for evaluating the inferior and superior recti muscles and the superior oblique muscle (Figure 7)(7,13).




The tomographic images are acquired in the axial and coronal planes, the first one with an approximate angle of -10º to -15º in relation to the orbitomeatal plane, and the latter almost perpendicular to the axial plane. It is important to note that the risk for thyrotoxicosis should be taken into consideration in the utilization of computed tomography with iodinated contrast agents(4). The normal positioning of the ocular globe is determined by a straight line connecting the zygomatic processes, utilizing the median portion of the globe as a reference (interzygomatic line). The measurement of the ocular globe positioning is based on the distance between the interzygomatic line and the posterior margin on the median portion of the ocular globe in the axial plane (Figure 8). The superior rectus muscle and the elevator muscle of the upper eyelid are measured in conjunction, considering that they cannot be easily distinguished from each other, thus comprising the superior muscle group (Figure 9). Vertical diameters of the superior muscle group and inferior rectus muscle can be best obtained in the coronal and sagittal planes (Figure 10). The horizontal diameters of the lateral and medial recti muscles are measured with higher reliability in the axial plane(14) (Table 1).




MRI is the best imaging method for evaluating the orbital structures because of its better tissue resolution and absence of ionizing radiation(15).

The protocol for examination with MRI in the author´s institution is comprised of spin-echo T1-weighted sequences in the axial and coronal planes, multiechoes T2weighted sequence in the coronal plane, and short time inversion recovery (STIR) sequence in the coronal plane. Paramagnetic contrast-enhanced images are acquired with T1-weighted sequence with fat-suppression in the axial, coronal and sagittal oblique planes(16).

Normal extraocular muscles are characterized by low signal intensity on T1-weighted sequences and low to intermediate signal intensity on T2-weighted sequences, with well-defined margins. There is a marked contrast enhancement, related to the great vascular supply to the extraocular muscles (Figure 11)(1).


The T1-weighted sequence offers a better contrast resolution for evaluating the region and measurement of the extraocular muscles(17), while the physiopathological condition of these muscles is best evaluated on T2-weighted sequences(16).

Because of the capability to evaluate the water contents of tissues by means of long TR-weighted sequences with and without fat-suppression (respectively T2-weighted and STIR), MRI is a useful method for approaching the disease activity, identifying inflammatory and edematous alterations involving the muscles through an increase in the signal intensity on T2weighted sequences, which is critical to achieve a good outcome of the anti-inflammatory treatment whose effectiveness only can be achieve in the active phase of the disease(1,3,5-8,17,18). This information corroborates the MRI's superiority over other imaging methods in the follow-up of the disease progression.

Some authors describe a correlation between the pattern of muscle involvement on T2-weighted sequences and the reversibility of diplopia. In cases where the signal intensity was uniformly increased, a better response to the treatment was observed, but, when the signal intensity was heterogeneous, the diplopia tended to be irreversible(19).

Hypertrophy of the extraocular muscles is observed and increase in their signal intensity on T2-weighted images indicates the edematous or inflammatory phase of the disease(18). On the other hand, decreased signal intensity of these muscles on T1- and T2-weighted sequences suggests the presence of chronic fibrotic alterations. Hyperintense intramuscular foci on T1- and T2-weighted sequences are suggestive of chronic fat degeneration(1,3,5), which also can be identified at CT through hypoattenuating areas corresponding to fat infiltration (Figure 12). These latest findings indicate chronic, non-congestive phase of the disease with restricted ocular motion secondary to extraocular muscles fibrosis and subsequent loss of elasticity(3) in association with volume decrease in these muscles(5)corresponding to lack of response to the clinical treatment.


Surgical orbital decompression or radiotherapy may be indicated in the setting of compressive optic neuropathy to prevent a significant vision loss(12). The surgical procedure is aimed at achieving orbital enlargement by means of a partial bone removal from one of the four orbital walls, depending on the required decompression degree(20).

On images of all the extraocular muscles, the paramagnetic contrast enhancement has shown to be significantly decreased in patients with thyroid ophthalmopathy at the edematous phase, while on T2-weighted images the signal intensity was increased, thus inferring a decrease in the vascular supply in the acute phase of this disease which, in the future, with the development of additional studies and improvement of MRI techniques, will probably allow the prediction of the severity, type of therapy and prognosis for the disease(1).

CONCLUSION

Imaging methods (CT and MRI) play a significant role as an aid in the evaluation of patients with endocrine ophthalmopathy, especially those with signs of optic neuropathy, and in the demonstration of the wide spectrum of findings involving the orbital structures, both in the inflammatory and fibrotic phases of the disease.

MRI plays the most relevant role in the differentiation of the disease phases, allowing the detection of inflammatory signs indicative of the disease activity, which is important for selecting the patients eligible for anti-inflammatory therapy, with a great influence on the prognosis. Additionally, MRI is the method of choice in the therapeutic follow-up of these patients for evaluating the response translated into reversal of inflammatory signs and consequential development of fibrosis and hypertrophy of extraocular muscles.

REFERENCES

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  • Thyroid ophthalmopathy revisited

    *
  • Publication Dates

    • Publication in this collection
      28 Aug 2009
    • Date of issue
      Aug 2009

    History

    • Accepted
      23 Mar 2009
    • Received
      07 Nov 2008
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