Risk Factors for Accommodative Esotropia among Hypermetropic Children

doi:10.1167/iovs.04-0618

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Risk Factors for Accommodative Esotropia among Hypermetropic Children

Eileen E. Birch,¹^,2 Sherry L. Fawcett,¹^,2 Sarah E. Morale,¹ David R. Weakley, Jr,² and Dianna Hughbanks Wheaton¹

^¹From the Retina Foundation of the Southwest, Dallas, Texas; and the ^²Department of Ophthalmology, University of Texas Southwestern Medical Center, Dallas, Texas.

Abstract

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Abstract
Methods
Results
Discussion
References

PURPOSE. Identification of risk factors for accommodative esotropiamay help to determine which children with hyperopia may benefitfrom early spectacle correction or preventive therapy.

METHODS. Participants in the family history study were 95 consecutivepatients, aged 18 to 60 months, with accommodative esotropia.Participants in the binocular sensory function study were asubgroup of 41 children enrolled in the family history studywithin 1 month of onset, while the esodeviation was still intermittent.Participants in the hypermetropia study were 345 consecutivepatients, ages 12 months to 8 years, with refractive error of+2.00 D or greater and no esodeviation before age 12 months.

RESULTS. In the family history study, 23% of children with accommodativeesotropia had an affected first-degree relative, and 91% hadat least one affected relative. In the binocular sensory functionstudy, random-dot stereoacuity was abnormal in 41% of children,whereas an abnormal motion VEP, Worth 4-dot, or positive 4-PDbase-out prism responses were present in 4% or less of the children.In the hypermetropia study, patients with a mean spherical equivalentof < +3.00 D and significant anisometropia had a 7.8-foldincreased risk for accommodative esotropia over nonanisometropicpatients.

CONCLUSIONS. A positive family history, subnormal random-dotstereopsis, and hypermetropic anisometropia each pose a significantrisk for the development of accommodative esotropia. Assessmentof these risk factors in conjunction with refractive screeningshould help to identify those children who are most likely tobenefit from early spectacle correction or preventive treatment.

Treatment with spectacle correction of $≥$ +4.00 D of hypermetropiahas been shown to reduce the prevalence of accommodative esotropiain children aged 4 years by >50% and potentially reducesthe risk of hypermetropic ametropic amblyopia.¹ Despite thepotential benefit of early intervention, this treatment approachhas not been widely adopted for at least two reasons. First,the prevalence of accommodative esotropia among children whohad hypermetropia of $≥$ +4.00 D during infancy is low (10%–20%),¹² and so the placement of spectacles on all children with $≥$ +4.00D hypermetropia would result in the treatment of many childrenwho are not at risk for development of accommodative esotropia.Unnecessary treatment with spectacle correction during infancyand early childhood is expensive, places a compliance burdenon families, and may interfere with emmetropization, especiallyif refractive error is fully corrected.³ Atkinson et al.⁴ found a significantly slower course of emmetropization amonghyperopic infants who were undercorrected by 1 D, although thiswas a transient effect. By 36 months of age, emmetropizationwas similar in the two groups. Full correction of refractiveerror may have a larger impact on emmetropization, since thegreater reduction in accommodative demand may minimize the visualfeedback from optical defocus that is thought to play a rolein compensatory eye growth.⁵ ⁶ ⁷

Second, many children who have accommodative esotropia havehypermetropic refractive errors less than +4.00 D and wouldnot be treated with this approach. For example, more than halfof the patients in a group of 68 children with accommodativeesotropia reported by Raab⁸ had less than +4.00 hypermetropiaon the initial visit.

Identification of additional risk factors for accommodativeesotropia could play an important role in determining whichchildren with hypermetropia <+4.00 D may benefit from earlypreventive treatment with spectacles. The purpose of this studywas to examine three potential risk factors, commonly associatedwith accommodative esotropia⁹ ¹⁰ ¹¹ that might be used alongwith refractive screening to identify children at highest riskfor accommodative esotropia. The risk factors examined werefamily history, abnormal binocular sensory function, and significant(>1.00 D) anisometropia.

Methods

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Abstract
Methods
Results
Discussion
References

Subjects
Participants in the family history study were 95 consecutivepatients with accommodative esotropia, ages 18 to 60 months,enrolled in a prospective study of accommodative esotropia.Participants in the binocular sensory function study were asubgroup of those enrolled in the family history study who hada visit within 1 month of detection of the esotropia by theparent or pediatrician and within 1 month of diagnosis of accommodativeesotropia by a pediatric ophthalmologist, while the esodeviationwas still intermittent (n = 41). The rationale for selectingthis subgroup for study was that any binocular sensory abnormalitiespresent at this early stage (when the child still enjoyed orthophoriathroughout most of the waking hours) may have been present beforethe onset of the intermittent deviation and therefore representeda true risk factor.

All participants in the studies of family history and binocularsensory function had onset of accommodative esotropia at 18to 48 months of age associated with hypermetropia and/or highaccommodative convergence/accommodation (AC/A) ratio. They werediagnosed by a pediatric ophthalmologist and referred to theRetina Foundation of the Southwest for participation in researchstudies of sensory outcomes after treatment during the years1988 to 1998. None of the patients had known neurologic defectsor other coexisting disease.

Participants in the hypermetropia study were drawn from a separatecohort composed of 345 consecutive new patients >1 year ofage presenting to the Ophthalmology Service of Children’s’Medical Center, Dallas Texas for the 42-month period from January1, 1995, to June 30, 1998.¹² ¹³ ¹⁴ Patients were eligible ifthey had an overall refractive error of +2.00 D or greater (meanspherical error calculated as spherical error + 0.5 x astigmaticerror; average of both eyes), and no history of or documentedesodeviation before age 12 months; 345 patients were includedin this study. Patients enrolled ranged in age from 12 monthsto 8 years.

Informed consent was obtained from one or both parents beforethe child’s participation. The research protocol conformedto the tenets of the Declaration of Helsinki and was approvedby the Institutional Review Board of the University of TexasSouthwestern Medical Center.

Family History
Parents of children with accommodative esotropia were askedto fill out a brief questionnaire about the family history ofstrabismus and other ocular disorders among close-degree relativesof the affected child (siblings, parents, grandparents, aunts,uncles, and cousins). These data were used to construct a preliminarypedigree. A staff member reviewed the pedigree with the parent(s),and corrections were made as needed. Accompanying siblings wereexamined.

On follow-up visits to the laboratory and/or by telephone, directedinterviews were conducted with the parents or other relativesto provide further additions and clarifications to the pedigrees.Experienced staff conducted all interviews. Directed interviewsincluded detailed questions on the nature of the strabismicdeviation, the age of onset of strabismus, any surgical or nonsurgicaltreatment, refractive error, age at which glasses were initiallyprescribed, and whether there were any other familial medicalconditions.

Only family members who were reported to have eyes that weremisaligned toward the nose, who had had onset during the preschoolage range (18 months to 48 months), and who had been treatedwith glasses that magnified the eyes were classified as affectedby accommodative esotropia. Family members with other formsof strabismus or amblyopia or for whom insufficient detail wasavailable regarding the character of the strabismic deviation,the age at onset of strabismus, or the type of treatment theyreceived were not classified as affected. Although ophthalmicexaminations of all family members may have provided other usefulinformation, in some cases neither hypermetropia $≥$ +4.00 D noresotropia persisted into adulthood after a successful early-childhoodcourse of treatment. Pedigree analysis was performed to determinethe prevalence of affected relatives as a function of degreeof relationship with the proband.

Binocular Sensory Function
All children wore spectacle correction that fully correctedtheir intermittent esodeviations during binocular sensory testing.Random-dot stereoacuity was evaluated, using the Randot test(version 2) and the Preschool Randot Stereoacuity Test (forchildren aged $≥$ 3 years) or the Randot Stereocards¹⁵ (for children<3 years of age) (all from Stereo Optical, Inc., Chicago,IL). Fusion was assessed with the Worth 4-dot test at near (33cm) and, when possible, based on the child’s age, at distance(3 m) and by the 4-PD base-out test. Monofixation (absence offoveal fusion) was determined by examining the asymmetry ofthe motion VEP in response to a 1-cyc/deg sine wave gratingundergoing quadrature motion at 6 Hz. Asymmetry in the motionVEP response has been shown to be strongly associated with suppressionof the W4D at distance but not at near fixation, deficient orabsent stereopsis, and a positive 4-PD base-out test (i.e.,with the clinical hallmarks of monofixation syndrome).¹⁶ ¹⁷ Data were summarized by calculating the proportion of childrenwith abnormal results on each test.

Hypermetropia Study
Each patient was evaluated, using cycloplegic refraction, todetermine overall spherical equivalent refraction and overallspherical equivalent of anisometropia. In addition, an ocularmotility examination was performed to determine the presenceor absence and constancy of esotropia, and acuity or fixationpreference testing was completed to determine presence or absenceof amblyopia. Significant anisometropia was defined as being1.00 D or more. This amount of anisometropia was chosen as "significant,"because it has been reported to increase the prevalence of amblyopiaand reduces binocularity in patients without strabismus.¹² The effects of moderate ( $≥$ 1 to <2 D) and large ( $≥$ 2 D) anisometropiawere also compared with each other and with patients withoutanisometropia. The relative risk (derived from the odds ratio)of developing esotropia was determined.¹⁸

Logistic regression analysis was used to estimate the odds ratiofor the adverse outcome of esotropia between subjects with andwithout anisometropia using a statistical analysis program (SASInstitute, Cary, NC). Age, mean spherical equivalent, and amblyopiawere found to be associated with esotropia and considered tobe possible confounders in the analysis. Adjusted odds ratiosfor esotropia were computed in a logistic regression model,with esotropia (yes/no) as the dependent variable; anisometropia(yes/no), age, and mean spherical equivalent as continuous variables;and presence of amblyopia (yes/no) as the independent variable.Because esotropia was not a rare outcome, the adjusted oddsratios were corrected to relative risks.

Results

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Methods
Results
Discussion
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Family History
Of the 95 families invited to participate, 9 were excluded fromthe analyses. Two parents refused to provide sufficient information,two of the probands were adopted, three probands had one adoptedparent, and two probands had a family history of other heritableconditions that might be associated with strabismus (one craniofacialdisorder and one neurologic disorder). In the remaining 86 familiesstudied, all interviews were completed to the level of the first-and second-degree relatives (including parents, siblings, grandparents,aunts, and uncles), and 44 of the pedigrees were completed tothe level of the third- to fifth-degree relatives (includinggreat grandparents, cousins, and more distant blood relatives).

Data from a total of 2828 blood relatives were obtained, witha mean of 54 blood relatives per family. The total number ofaffected individuals was 214 (106 male, 108 female). Resultsare summarized in Table 1 . Overall, 19 of 86 probands (22%)had affected first-degree relatives and 66 of 86 probands (77%)had affected first- and/or second-degree relatives. In the 44pedigrees completed to the level of third- to fifth-degree relatives,40 (91%) of 44 probands had at least one affected relative.

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TABLE 1. Family History by Directed Interview

Binocular Sensory Function
The mean (±SD) age of the 41 children tested at the onsetof intermittent accommodative esotropia was 2.4 ± 0.6years, and the range was 1.5 to 3.6 years. The percentage ofchildren with normal and abnormal outcomes on each of the fourtests is summarized in Table 2 . Not all children were cooperativefor all four tests. The number of children who successfullycompleted each test is provided. At the onset of intermittentesodeviation, random-dot stereoacuity was abnormal in 41% ofchildren. No abnormal results were found for motion VEP responsesymmetry or fusion assessed by the Worth 4-dot test. Only 4%of children showed an abnormal 4-PD base-out prism test response.

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TABLE 2. Binocular Sensory Function at the Onset of Intermittent Accommodative Esotropia

Hypermetropia
Anisometropia ( $≥$ 1.00 D) was present in 28% (97/345) of patients,whereas esotropia was present in 61% of patients (210/345).The relative risk (RR) for development of accommodative esotropia(either intermittent or constant) when anisometropia was presentcompared with when it was absent is summarized in Table 3 .Anisometropia ( $≥$ 1.00 D) increased the RR for development of accommodativeesotropia to 1.68 when adjusted for age, overall spherical equivalent,and amblyopia. This increased RR was the same for patients with1.00 to <2.00 D of anisometropia as for patients with $≥$ 2.00D of anisometropia.

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TABLE 3. Anisometropia and Relative Risk of Esotropia

When the data were stratified by mean hypermetropic sphericalequivalent (Table 4) , anisometropia was found to significantlyincrease the RR of development of accommodative esotropia atlower amounts of hypermetropia. Patients with a mean SE of <+3.00D and anisometropia had a 7.8 times increased RR for accommodativeesotropia compared with nonanisometropic patients with the sameoverall SE. This was significantly higher than the effect ofanisometropia on the RR for development of accommodative esotropiain more hypermetropic individuals (RR = 1.49 for >+3.00 Dspherical equivalent; P = 0. 017). When the data were furtherstratified into 1-D groups, the largest effect on RR for developmentof accommodative esotropia was again most notable in patientswith lower hypermetropic refractive error (Table 4) .

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TABLE 4. Anisometropia ( $≥$ 1 D), Mean Spherical Equivalent, and Relative Risk of Esotropia

Anisometropic patients were more likely to be amblyopic thannonanisometropic patients (82%, 79/97 vs. 35%, 87/248). In additionesotropic patients were also much more likely to be amblyopicthan nonesotropic patients (73%, 153/210 vs. 10%, 13/135). However,because of the significant association between amblyopia andanisometropia (82% of anisometropic patients were amblyopic)and the strong correlation between both of these variables andesotropia (82% of anisometropic patients and 93% of amblyopicpatients were esotropic), there was little opportunity to examinethe effect of anisometropia free of amblyopia. Nevertheless,in the 179 nonamblyopic patients, anisometropia increased theRR for esotropia to 2.14, consistent with anisometropia as anindependent risk factor.

Discussion

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Abstract
Methods
Results
Discussion
References

Family history, subnormal random-dot stereopsis, and, in childrenwith hypermetropia < +4.00 D, anisometropia, each resultedin a significant increase in the risk for the development ofaccommodative esotropia. More than 75% of children with accommodativeesotropia had an affected parent, sibling, grandparent, aunt,or uncle, and >90% of children with accommodative esotropiahad at least one affected relative. The 22.9% prevalence offirst-degree affected relatives reported herein is similar tothe 18% reported by Aurell and Norrsell.¹⁹

Although the data support family history as a significant riskfor the development of accommodative esotropia, this does notimply that all children with a positive family history necessarilyare candidates for intervention. On the one hand, the 22% prevalenceof accommodative esotropia among parents and siblings clearlyimplies significant risk; on the other hand, approximately 75%of first-degree relatives are likely to be unaffected. Thus,although family history poses a significant risk, it must beevaluated in the context of other ophthalmic and sensory examinationdata. It should be noted that strabismus is a common condition(affecting 2%–4% of the population) and, in the absenceof a control group, it is difficult to determine whether theprevalence of affected second- to fifth-degree relatives issignificantly higher among patients with accommodative esotropiaversus the general population.

Classification of family members as affected or unaffected inthe pedigree analysis was accomplished with data gathered indirected interviews. Although ophthalmic examinations of allfamily members may appear at first glance to be a superior methodology,the disease of accommodative esotropia may be uniquely difficultto assess in this manner. In particular, accommodative esotropiathat has been successfully treated during childhood may leaveno detectable symptoms in adulthood. Neither esodeviation norhyperopia may be present and binocular sensory function maybe normal. Indeed, the interview approach that we used may haveunderestimated the prevalence of accommodative esotropia amongrelatives, since those who appeared to have other forms of strabismusor amblyopia or for whom insufficient detail was available regardingthe character of the strabismic deviation, the age at onsetof strabismus, or the type of treatment they received were notclassified as affected.

The finding of subnormal random-dot stereopsis within a groupof patients with recent diagnosis of intermittent accommodativeesotropia suggests that, for at least some patients with accommodativeesotropia, binocular sensory abnormalities may precede, andpossibly contribute to, the onset of strabismus. This resultis similar to results of two earlier studies of children withor at risk for accommodative esotropia which found that abnormalbinocularity (fusion or stereopsis) precedes the onset of esotropiain some cases, but is not a necessary condition for the onsetof esotropia.² ²⁰

The increased risk for development of accommodative esotropiaassociated with anisometropia is particularly striking for childrenwith lower amounts of hypermetropia. This suggests that screeningfor anisometropia among hypermetropic children may identifya subgroup which is at higher risk for development of accommodativeesotropia than the overall group of hypermetropic children.Detection of anisometropia in children with hypermetropia <+4.00 D may provide an avenue for identifying those childrenwho are at significant risk but would be missed if only sphericalequivalent criteria were applied.

One caveat in the interpretation of the anisometropia data mustbe noted. As reported in the results section, there was a significantassociation between the presence of amblyopia and both anisometropiaand esotropia. For the purpose of analysis of relative risk,amblyopia was not considered a baseline risk factor but ratherwas assumed to be an outcome of esotropia, anisometropia, orboth. Nevertheless, even in nonamblyopic patients, anisometropiaincreased the RR for esotropia to 2.14, consistent with anisometropiaas an independent risk factor. Moreover, from a practical standpoint,it may not matter whether the anisometropia or the amblyopiaposes the greater risk for the development of accommodativeesotropia. Given the high rate of co-occurrence, it may be simplerto screen for anisometropia than for amblyopia, particularlyin preverbal children.

In conclusion, the present study identified positive familyhistory, subnormal random-dot stereopsis before developmentof a constant deviation, and, in children with hypermetropia< +4.00 D, anisometropia as significant risk factors forthe development of accommodative esotropia. Assessment of thepresence or absence of these additional risk factors in conjunctionwith the overall amount of hypermetropia should help to identifythose children who are most likely to benefit from preventivetreatment before the onset of esotropia.

Footnotes

Supported by National Eye Institute Grant EY05236 (EEB).

Submitted for publication May 28, 2004; revised September 13,2004; accepted November 7, 2004.

Disclosure: E.E. Birch, None; S.L. Fawcett, None; S.E. Morale,None; D.R. Weakley, Jr, None; D.H. Wheaton, None

The publication costs of this article were defrayed in partby page charge payment. This article must therefore be marked"advertisement" in accordance with 18 U.S.C. $§$ 1734 solely toindicate this fact.

Corresponding author: Eileen E. Birch, Retina Foundation ofthe Southwest, 9900 N. Central Expressway, Suite 400, Dallas,TX 75231; ebirch{at}retinafoundation.org.

References

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