Open Access Peer-Reviewed
Editorial

Management of Intermittent exotropia in childhood: current concepts of the literature and the experts

Manejo da exotropia intermitente na infância: conceitos atuais da literatura e dos especialistas

Luisa Moreira Hopker1; Julia Dutra Rossetto2; Fabio Ejzenbaum3; Luis Carlos Ferreira de Sá4; Geraldo de Barros Ribeiro5; Tomás Scalamandré Mendonça6; Mauro Goldchmit7,8; Iara Debert9

DOI: 10.5935/0004-2749.2022-1001

Intermittent exotropia X(T) occurs in approximately 1% of the population aged <11 years(1). Although extensively investigated, controversies surround its propaedeutics, treatment, and specialists(2). The disease course has also not been clearly defined. Some studies have demonstrated the absence of change over time(3), whereas others have shown deviation improvements(3,4) or even decompensation(4). Opinions varied regarding treatment, both in clinical management with the use of occlusion(5) or over minus lens prescription(6) and in surgical treatment concerning the best time to perform surgery(7,8) and the type of the surgical technique(9,10). This paper summarizes the best practices for evaluating and treating X(T) based on expert opinion and a literature review.

Eight pediatric ophthalmology and strabismus specialists were invited to discuss the main points of X(T) semiology and treatment. They had at least 10 years of experience after ophthalmology residency, master's, or doctorate degrees and trained in Brazil, abroad, or both. They answered a questionnaire concerning their management and were asked about their opinions on hypothetical X(T) cases.

A literature review was performed in PubMed database, using the following terms: "intermittent exotropia," "surgery," "management," "occlusion," and "overminus lenses" to support the points in question. The opinions of experts and literature review were divided in propaedeutics, clinical, and surgical treatment.

 

PROPAEDEUTICS FOR X(T)

As part of propaedeutics, questioning parents about the deviation frequency is considered essential. Therefore, it was categorized as either above or below 50% of the day. The authors considered the deviation frequency during the examination to classify it as compensated or not. Observing the presence and frequency of spontaneous decompensation and the ability to control deviation during anamnesis and examination were highlighted.

Most experts used occlusion 30-60 min before an examination to induce the largest deviation. Some measured near deviation using +3.00 lenses and the distance measurements with the patient fixing on a target or through a window (at least 6 m).

Assessing whether the deviation occurred spontaneously or only after the fusion interruption by occlusion is essential. Another critical factor was to observe whether the recovery of the deviation occurred immediately after the removal of the occlusion, slowly, or if there was no recovery at all.

In the literature, some clinical data could contribute to the assessment of X(T) and its prognosis:

• Deviation angle versus prognosis: No cutoff value was established for the deviation angle. This could be considered a worse prognosis because the deviation control contributes more to the prognosis than its magnitude. A large-angle deviation with reasonable control generally had a better prognosis in the development of binocular vision than a small angle deviation with poor control(11).

• Deviation control: Although scales can stratify the ability of patients to control deviation, control was most often variable, making classification by well-defined scores difficult. Family observations were employed to complement the findings observed during the consultation, as it had adequate variability, mainly related to how much time the guardian spends with the child(11).

• Despite its rarity, stereopsis deterioration was considered an inadequate prognostic factor, as the definition of X(T) assumes normal stereopsis. The measurement of distance stereopsis was infrequently used, but it could provide more data regarding the deterioration of binocular vision(11).

 

CLINICAL TREATMENT OF X(T)

Refractive errors, such as high hyperopia, low-to-moderate myopia, or anisometropia, should be corrected to improve visual acuity(12) and stereoacuity, improving deviation control(13). Myopia must be fully corrected, and hyperopia >4.00 D or anisometropia >1.50 D should be corrected without significant discounts, as these patients might have poor accommodation(2,13). Low myopia and astigmatism should be prescribed, as they improve deviation control(12).

All authors suggested using anti-suppressive occlusion until surgery with an occlusion use of 1-3h, usually in the dominant eye, alternating if there was no dominance in one eye. for treating X(T) with occlusion. A deviation frequency improvement during the use of the occlusion without changing the outcomes of surgery was reported. The occlusion performance was reported to make no difference in the deterioration of the deviation(14).

Recently, better deviation control was reported after 3 and 6 months of alternating occlusion in children aged 3-8 years. No difference in stereoacuity between the groups was reported(15).

Some authors prescribed over minus lenses for children younger than the ideal age for surgery and whose deviation, even with occlusion, was uncontrolled. In such cases, -3.00 lenses were prescribed or added to the prescription.

In patients with X(T), over minus lenses reduced the deviation angle and improved control(6,12). Generally, they were used in children aged <5 years to reduce the deviation frequency until surgery. This occurred because of accommodation, increase in accommodative convergence, and consequent reduction in deviation(6,13). Generally, -1.00 and -3.00 D were added to the child's cycloplegic refraction. The X(T) control improvement did not persist after lens use was discontinued (12). There were controversies about whether this approach could induce the onset of myopia in children(16), and an increase in the myopic shift was recently suggested(12).

 

SURGICAL TREATMENT

For most experts, the frequency of deviation and the capacity to control it are primary indications for surgery. Surgery was indicated if the deviation occurred longer than orthotropy during the day, with poor control, and generally deviations >25-30 prism-diopter (PD).

Other considerations included assessing asthenopia due to excess fusional convergence. Some experts indicated surgery only for children age ≥4 years. Others operated on uncompensated or large deviations (40-45 PD) at any age.

X(T) has a unique feature considering strabismus in children, as most patients had a single binocular vision and adequate stereopsis. Generally, the criteria for indicating surgery were deterioration of fusional control and a large deviation angle. In the literature, the reduction or loss of stereoacuity was also essential, but this test might not be reliable depending on the child's age. No well-established recommendations for using these surgical indication criteria were reported(11). There were controversies about the best age for surgery. Complete visual development was expected at around age 7 years. Hence, an undesired overcorrection postoperatively (consecutive esotropia) at a young age could lead to suppression, followed by amblyopia and loss of stereopsis(11). However, recent studies have shown that early surgery (age 3-5 years) had better surgical success rates after 3 years of follow-up (8) and better motor alignment results(7).

Regarding surgery type, for deviations up to 25 PD, bilateral lateral rectus recession had an adequate success rate of 86%, with a low overcorrection rate of 3%(17). Lateral rectus recession was also more suitable for deviations, such as excess divergence. Still, pseudo-excess divergence and the basic X(T) type could be treated with unilateral recession-resection(11,18). In a recent meta-analysis, for the basic type, both procedures, bilateral rectus recession and recession-resection, had similar success and chance of under or overcorrection(19,20).

X(T) is a common ocular disease experienced by specialist and non-specialist ophthalmologists and lacks consensus on its management. This paper shows the leading scientific evidence and expert opinions on the diagnosis, clinical, and surgical management of X(T). Prospective case-control and randomized clinical trials are needed to establish individual objective criteria for clinical management, the best age for surgery, and surgical strategy.

 

REFERENCES

1. Govindan M, Mohney BG, Diehl NN, Burke JP. Incidence and types of childhood exotropia: A population-based study. Ophthalmology. 2005;112(1):104-8.

2. Lavrich JB. Intermittent exotropia: Continued controversies and current management. Curr Opin Ophthalmol. 2015;26(5):375-81.

3. Pediatric Eye Disease Investigator Group, Writing Committee, Mohney BG, Cotter SA, Chandler DL, Holmes JM, Wallace D , Yamada T, Petersen DB, Kraker RT, Morse CL, Melia BM, Wu R. Three-year observation of children 3 to 10 years of age with untreated intermittent exotropia. Ophthalmology [Internet]. 2019[cited 2020 jul 27];126(9):1249-60.Comment in: Ophthalmology. 2019;126(9):1261-2. Available from: Three-year Observation of Children Age 3 to 10 Years Old with Untreated Intermittent Exotropia - PMC (nih.gov)

4. Romanchuk KG, Dotchin SA, Zurevinsky J. The natural history of surgically untrebnmbnmbnated intermittent exotropia-looking into the distant future. J AAPOS. 2006;10(3):225-31.

5. Kushner BJ. Conservative management of intermittent exotropia to defer or avoid surgery. J AAPOS. 2019;23(5):256 e1-e6.

6. Bayramlar H, Gurturk AY, Sari U, Karadag R. Overcorrecting minus lens therapy in patients with intermittent exotropia: Should it be the first therapeutic choice? Int Ophthalmol. 2017;37(2):385-90.

7. Issaho DC, Wang SX, Weakley DR Jr. Intermittent exotropia surgery: results in different age groups. Arq Bras Oftalmol [Internet]. 2017[cited 2020 apr 19];80(6):355-8. Available from: SciELO - Brasil - Intermittent exotropia surgery: results in different age groups Intermittent exotropia surgery: results in different age groups

8. Repka MX, Chandler DL, Holmes JM, Donahue SP, Hoover DL, Mohney BG, Phillips PH, Stout AU, Ticho BH, Wallace DK; Pediatric Eye Disease Investigator Group. The relationship of age and other baseline factors to outcome of initial surgery for intermittent exotropia. Am J Ophthalmol [Internet]. 2020[cited 2021 nov 21];212:153-61. Available from: The Relationship of Age and Other Baseline Factors to Outcome of Initial Surgery for Intermittent Exotropia - PMC (nih.gov)

9. Pediatric Eye Disease Investigator Group; Writing C, Donahue SP, Chandler DL, Holmes JM, Arthur BW, Paysse EA, Wallace DK, Petersen DB, Melia BM, Kraker RT, Miller AM. A randomized trial comparing bilateral lateral rectus recession versus unilateral recess and resect for basic-type intermittent exotropia. Ophthalmology[Internet]. 2019[cited 2021 oct 15];126(2):305-17. Available from: A Randomized Trial Comparing Bilateral Lateral Rectus Recession versus Unilateral Recess-Resect for Basic-Type Intermittent Exotropia - PMC (nih.gov)

10. Wang L, Wu Q, Kong X, Li Z. Comparison of bilateral lateral rectus recession and unilateral recession resection for basic type intermittent exotropia in children. Br J Ophthalmol. 2013;97(7):870-3.

11. Hatt SR, Gnanaraj L. Interventions for intermittent exotropia. Cochrane Database Syst Rev. 2013(5):CD003737.

12. Chen AM, Erzurum SA, Chandler DL, Hercinovic A, Melia BM, Bhatt AR, Suh DW, Vricella M, Erickson JW, Miller AM, Marsh JD, Bodack MI, Martinson SR, Titelbaum JR, Gray ME, Holtorf HL, Kong L, Kraker RT, Rahmani B, Shah BK, Holmes JM, Cotter SA; Pediatric Eye Disease Investigator Group. Overminus lens therapy for children 3 to 10 years of age with intermittent exotropia: a randomized clinical trial. JAMA Ophthalmol [Internet]. 2021[cited 2020 jul 27];139(4):464-76. Comment in: JAMA Ophthalmol. 2021;139(4):476-7. JAMA Ophthalmol. 2022;140(1):97-8. Available from: Overminus Lens Therapy for Children 3 to 10 Years of Age With Intermittent Exotropia: A Randomized Clinical Trial | Cataract and Other Lens Disorders | JAMA Ophthalmology | JAMA Network

13. Heydarian S, Hashemi H, Jafarzadehpour E, Ostadi A, Yekta A, Aghamirsalim M, et al. Non-surgical management options of intermittent exotropia: a literature review. J Curr Ophthalmol [Internet]. 2020[cited 2021 mar 19];32(3):217-25. Available from: Non-surgical Management Options of Intermittent Exotropia: A Literature Review - PMC (nih.gov)

14. Pediatric Eye Disease Investigator Group, Cotter SA, Mohney BG, Chandler DL, Holmes JM, Repka MX, Melia M, Wallace DK, Beck RW, Birch EE, Kraker RT, Tamkins SM, Miller AM, Sala NA, Glaser SR. A randomized trial comparing part-time patching with observation for children 3 to 10 years of age with intermittent exotropia. Ophthalmology [Internet]. 2014[cited 2022 jan 21];121(12):2299-310. Available from: A Randomized Trial Comparing Part-time Patching with Observation for Children 3-10 Years Old with Intermittent Exotropia - PMC (nih.gov)

15. Akbari MR, Mehrpour M, Mirmohammadsadeghi A. The influence of alternate part-time patching on control of intermittent exotropia: A randomized clinical trial. Graefes Arch Clin Exp Ophthalmol. 2021;259(6):1625-33.

16. Paula JS, Ibrahim FM, Martins MC, Bicas HE, Velasco e Cruz AA. Refractive error changes in children with intermittent exotropia under overminus lens therapy. Arq Bras Oftalmol [Internet]. 2009[cited 2020 jun 21];72(6):751-4. Available from: SciELO - Brasil - Refractive error changes in children with intermittent exotropia under overminus lens therapy Refractive error changes in children with intermittent exotropia under overminus lens therapy

17. Spierer O, Spierer A. Unilateral lateral rectus recession is an effective surgery for intermittent exotropia in young children. BMC Ophthalmol [Internet]. 2021[cited 2022 jan 21];21(1):10.Available from: Unilateral lateral rectus recession is an effective surgery for intermittent exotropia in young children | BMC Ophthalmology | Full Text (biomedcentral.com)

18. Sun Y, Zhang T, Chen J. Bilateral lateral rectus recession versus unilateral recession resection for basic intermittent exotropia: a meta-analysis. Graefes Arch Clin Exp Ophthalmol. 2018;256(3):451-8.

19. Wang X, Zhu Q, Liu L. Efficacy of bilateral lateral rectus recession versus unilateral recession and resection for basic-type intermittent exotropia: A meta-analysis. Acta Ophthalmol. 2021;99(7):e984-e990.

20. Fiorelli VM, Goldchmit M, Uesugui CF, Souza-Dias C. Intermittent exotropia: comparative surgical results of lateral recti-recession and monocular recess-resect. Arq Bras Oftalmol [Internet]. 2007[cited 2020 jul 21];70(3):429-32. Available from: SciELO - Brasil - Intermittent exotropia: comparative surgical results of lateral recti-recession and monocular recess-resect Intermittent exotropia: comparative surgical results of lateral recti-recession and monocular recess-resect

Submitted for publication: July 5, 2022.
Accepted for publication: July 6, 2022.

Funding: This study received no specific financial support.

Disclosure of potential conflicts of interest: None of the authors have any potential conflicts of interest to disclose.


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