Original Article

Interocular Axial Length Difference and Treatment
Outcomes of Anisometropic Amblyopia

Monireh Ghasempour1, MS; Masoud Khorrami-Nejad2,3, PhD; Aidin Safvati4, PhD; Babak Masoomian3, MD

1Department of Neuroscience, Faculty of Advanced Technologies in Medicine, Iran University of Medical Sciences, Tehran, Iran
2Optometry Department, School of Rehabilitation, Tehran University of Medical Sciences, Tehran, Iran

3Translational Ophthalmology Research Center, Farabi Eye Hospital, Tehran University of Medical Sciences, Tehran, Iran
4School of Optometry and Vision Science, University of New South Wales, Sydney, Australia

ORCID:
Masoud Khorrami-Nejad: https://orcid.org/0000-0002-8270-9704
Monireh Ghasempour: https://orcid.org/0000-0002-3088-9758

Abstract

Purpose: To evaluate the effect of interocular axial length (AL) difference on
outcomes of treatment for anisometropic amblyopia in comparison with normal
participants.
Methods: In this historical cohort study, 83 patients with anisometropic
amblyopia were divided into two age groups, 70 children (mean, 7.86 ± 1.56 and
range, 5–15 years) and 13 adults (mean, 26.46 ± 10.87 and range, 16–45 years).
The control group consisted of 43 non-amblyopic children and 17 non-amblyopic
adults. Treatment outcomes after a period of one year were defined as successful
or unsuccessful when posttreatment amblyopic corrected distance visual acuity
(CDVA) was reported as ≤0.9 versus CDVA ≤ 0.8, respectively. AL was measured
using a Lenstar LS900 (Haag-Streit AG, Switzerland).
Results: Fifty-nine patients showed satisfactory treatment outcomes (55 children
and 4 adults), while unsuccessful treatment outcomes were observed in 24
patients (15 children and 9 adults). The mean of amblyopia treatment duration
was 1.24 ± 0.76 years. The mean of interocular AL difference in all patients,
control, successful and unsuccessful treatment outcome groups were 0.49 ±
0.70mm (range, 0.00–3.89 mm), 0.12 ± 0.07 mm (range, 0.02–0.41), 0.33 ±
0.23 mm (range, 0.00–0.99 mm), and 1.81 ± 0.80 mm (range, 1.14–3.89 mm),
respectively. In both age groups, the mean of interocular AL difference in patients
with unsuccessful treatment outcomes was greater than those with successful
treatment outcomes and that of the control group (P < 0.001).
Conclusion: The results of this study suggest that the outcome of anisometropic
amblyopia treatment may depend on the interocular AL difference.

Keywords: Anisometropic Amblyopia; Axial Length; Refractive Error

J Ophthalmic Vis Res 2022; 17 (2): 202–208

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Axial Length and Amblyopia Treatment; Ghasempour et al

INTRODUCTION

Anisometropic amblyopia is one of the most
common types of amblyopia,[1–3] which is
secondary to differences in refractive errors
between the two eyes.[4, 5] Amblyopia is a type
of incomplete development of the visual system
occurring in early childhood.[5, 6] It is one of the
main causes of lifelong visual impairment[3] and is
the most common cause of vision loss in childhood
affecting 3.5% of children.[7] If amblyopia is not
diagnosed or treated in due course, there will be
a higher risk of vision impairment by conditions
such as macular degeneration that may potentially
occur in the non-amblyopic eye. Based on a Danish
study, about 1.2% of patients with amblyopia will
eventually suffer from severe visual impairment.[10]

One of the main causes of amblyopia is
uncorrected refractive error, which is hard to
detect when compared to amblyopia caused
by strabismus.[5, 7, 11] In fact, the initial factor
causing anisometropic amblyopia (monocular blur)
is the uncorrected refractive error. It leads to the
inequality of image size between the two eyes.
The blurriness of the image encumbers proper
stimulation of the visual system and thus functions
as an underlying cause of amblyopia.[4,5] Although
exceptions exist, various studies have reported that
higher amounts of anisometropia may result in
amblyopia with increased severity.[12, 13]

Despite the body of knowledge existing about
the major risk factors such as the age of onset,
the severity of anisometropia and the type of
treatment, treatment of anisometropic amblyopia
is reportedly unsuccessful in 65% to 94% of
patients.[5] Therefore, one could postulate that
unknown risk factors may be involved, warranting
further investigation into this area.

Correspondence to:

Masoud Khorrami-Nejad, PhD. Enghelab St., School of
Rehabilitation, Tehran University of Medical Sciences,
Tehran, Iran.
Email: Dr.khorraminejad@gmail.com
Received: 26-06-2020 Accepted: 23-07-2021

Access this article online

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DOI: 10.18502/jovr.v17i2.10791

Anisometropia is defined as a difference in
refractive error of ≥1.00 diopter (D) between the
two eyes.[6, 14] Various studies have shown that with
an increase in anisometropia, a higher difference
in the axial length (AL) between the two eyes may
occur as well.[15–17] The severity of amblyopia is
also one of the major risk factors for the failure of
anisometropic amblyopia treatment.[7, 11, 18, 19]

It seems a combination of these risk factors may
influence the results of anisometropic amblyopia
treatment, but it is not clear which factor is the most
effective.

The aim of this study was to evaluate the effect
of the interocular AL difference of each individual
on the outcomes of anisometropic amblyopia
treatment.

METHODS

This historical cohort study was conducted at
Najafzadeh Eye Clinic, Karaj, Iran from September
2016 to October 2018. In this study, data
were collected observationally. The study was
performed in accordance with the tenets of the
Declaration of Helsinki and approved by the ethics
committee of our clinic.

Eighty-three patients with anisometropic
amblyopia with no congenital anomalies,
organic lesions, fixation disorders, strabismus, or
glaucoma, were included in this study. They were
divided into two age groups, 5–15 years (n = 70)
and 16–45 years (n = 13). We also included a control
group consisting of 43 non-amblyopic children and
17 non-amblyopic adults. Anisometropic amblyopia
was defined as a difference of at least two lines in
corrected distance visual acuity (CDVA) between
the two eyes with the CDVA being equal to or
worse than 20/30 due to uncorrected refractive
error also with a difference of >1.50 D in spherical
refractive error between the two eyes.[2, 17]

With each age group we had two treatment
outcomes: (1) a successful treatment outcome

This is an open access article distributed under the Creative
Commons Attribution License, which permits unrestricted use,
distribution, and reproduction in any medium, provided the original
work is properly cited.

How to cite this article: Ghasempour M, Khorrami-Nejad M, Safvati A,
Masoomian B. The Effect of Interocular Axial Length Difference on Treatment
Outcomes of Anisometropic Amblyopia. J Ophthalmic Vis Res 2022;17:202–
208.

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Axial Length and Amblyopia Treatment; Ghasempour et al

(group A); whereby satisfactory CDVA (≥0.90) was
achieved following treatment of amblyopia using
corrective glasses alone or with occlusion therapy
and (2) an unsuccessful treatment outcome with
residual amblyopia (group B), defined as CDVA ≤
0.8 after at least one year of treatment. Control,
non-amblyopic participants, were those who had
CDVA ≥ 1.00 and at least ±0.50 D anisometropia.

Routine ophthalmic examinations detailed
below were performed for all participants. CDVA
was performed using an E-Snellen chart at a
distance of 6 m, and the findings were presented
in decimals. Alternate cover tests, versions and
duction tests were performed to rule out strabismus
and extraocular muscle movement limitations. A
slit�lamp (SL-202®, Shin-Nippon, Japan) was used
to perform biomicroscopy and funduscopy for all
amblyopic and normal participants.

Dry and cyclo refraction were measured by
a Nidek ARK-710A auto keratorefractometer
(Nidek Co. Ltd, Gamagori, Japan) and
confirmed by retinoscopy (HEINE Optotechnic,
Hersching, Germany). All participants underwent
cyclorefraction by administering cyclopentolate 1%
(two drops, 5 min apart, followed by refraction 30
min after the last drop).

Amblyopia treatment in all patients was started
with at least three months of full-time wearing of
corrective glasses. As described by the Pediatric
Eye Disease Investigator Group (PEDIG) studies,
supplementary amblyopia therapies were provided
at the end of three months.[20] In patients with
unsuccessful treatment, the amblyopia treatment
program was continued for at least one year.
The mean duration of amblyopia treatment was
also calculated. Depending on the severity of
amblyopia, treatment was continued until the
resolution of the amblyopia. Upon discontinuation
of treatment, patients were followed-up for at least
six months. In the last visit of patients, the AL of
both eyes was measured (Lenstar LS900, Haag-
Streit AG, Switzerland), and the average of five
measurements was recorded.

Statistical analysis was performed using SPSS
v22 software for Windows (IBM Inc., Armonk, New
York, NY, USA). P-values < 0.05 were recorded
as statistically significant. The Shapiro–Wilk test
was used to evaluate the normal distribution of the
interocular AL difference, and the Kruskal–Wallis
test was performed to compare the interocular AL
differences between the three groups (successful

treatment outcome, unsuccessful treatment
outcome, and control group).

RESULTS

Eighty-three patients with anisometropic
amblyopia were tested for this study (35 females
and 48 males) with a mean age of 10.77 ± 8.10
years (range, 5–45). They were divided into two
age groups, 5–15 years (group A, n = 70, mean
7.86 ± 1.56) and 16–45 years (group B, n = 13, mean
26.46 ± 10.87). Additionally, 60 participants were
selected as a control group consisting of non-
amblyopic anisometropic participants (43 children
aged 5–15 years with a mean age of 10.42 ± 2.95
years and 17 adults aged 16–45 years with a mean
age of 22.47 ± 4.73 years). In the children’s group
(group A), the time of diagnosis and first treatment
was between the ages of 4 and 6 years, while in
the adult group, it was at 15 years old and above.
For all patients, the mean duration of amblyopia
treatment was 1.24 ± 0.76 years, with a maximum
of 2.50 years. This treatment period included at
least three-months of full-time refractive correction
(without any other active or passive modes of
treatment for amblyopia). Hours of patching for
mild, moderate, and severe amblyopia were 2, 4,
and 6 hr, respectively. All amblyopic patients had
refractive anisometropic amblyopia. Amblyopia
was successfully treated in 59 (71.1%) patients (55
children and 4 adults), while 24 (28.9%) patients
demonstrated an unsuccessful treatment outcome
with residual amblyopia (15 children and 9 adults).

The comparison of the pretreatment CDVA
(LogMAR) between children and adult groups,
categorized based on amblyopia treatment
outcomes in anisometropic amblyopic patients,
are shown in Table 1. The mean of pretreatment
CDVA in the children and the adult group was 0.51
± 0.28 (range, 0.18–1.30) and 0.56 ± 0.31 (range,
0.18–1.30), respectively. After the treatment of
amblyopia, the mean of CDVA in the children and
the adult group was 0.12 ± 0.29 (range, 0.00–1.30)
and 0.30 ± 0.37 (range, 0.00–1.30), respectively.

The mean of anisometropia in all anisometropic
amblyopia patients, children and adult groups were
2.94 ± 1.94 D (range, 1.75–11.50), 2.77 ± 1.85 D
(range, 1.75–11.50), and 3.88 ± 2.14 D (range, 1.75–
8.25), respectively. Table 2 shows the comparison
of the mean of anisometropia between the children
and the adult groups, categorized by the treatment
outcome.

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Axial Length and Amblyopia Treatment; Ghasempour et al

Table 1. The comparison of the pretreatment of corrected distance visual acuity (LogMAR) between children and adult groups,
based on amblyopia treatment outcomes in anisometropic amblyopic patients.

Amblyopia treatment outcomes Age
group
(yr)

Number Minimum Maximum Mean ± SD Mean
standard
error

P-value

Good treatment outcome 5–15 55 0.18 1.00 0.43 ± 0.19 0.02 0.152
16–45 4 0.18 0.48 0.28 ± 0.14 0.07

Failure of successfully
treatment outcome

5–15 15 0.40 1.30 0.78 ± 0.35 0.09 0.499
16–45 9 0.40 1.30 0.68 ± 0.29 0.09

SD, standard deviation; yr, year

Table 2. Comparison of the mean anisometropia (diopter) among children and adult groups based on amblyopia treatment
outcomes.

Age group
(yr)

Number Minimum Maximum Mean ± SD Mean
standard
error

P-value

Control group 5–15 43 0.50 1.50 0.86 ± 0.25 0.04 0.279
16–45 17 0.50 1.75 0.92 ± 0.33 0.08

Good treatment outcome 5–15 55 1.75 3.00 2.01 ± 0.33 0.05 0.536
16–45 4 1.75 3.25 2.25 ± 0.68 0.34

Failure of successful
treatment outcome

5–15 15 3.50 11.50 5.57 ± 2.43 0.63 0.329
16–45 9 2.25 8.25 4.61 ± 2.19 0.73

SD, standard deviation; yr, year

The mean of the interocular AL differences in
all patients was 0.63 ± 0.78 mm. Figures 1 and 2
show the box plot distribution of the interocular
AL differences and amount of anisometropia,
categorized by treatment outcomes in the children
and the adult groups. As shown in Figure 1,
the interocular AL difference in the unsuccessful
treatment outcome group was >1 mm (in both age
groups).

The mean of the interocular AL difference was
significantly larger in the anisometropic amblyopia
group when compared to the control group (P
< 0.001). Also, there was a significant difference
between the control group, the unsuccessful and
successful treatment outcome groups (P < 0.001).
In both age groups, the mean of the interocular AL
difference in the unsuccessful treatment outcome
group was significantly greater than the successful
treatment outcome group (P < 0.001).

In the children group, when a successful
treatment outcome was achieved, the mean AL
was larger than the control group (z = –5.539;
P < 0.001; 2-tailed); however, in the adult group

this difference was not statistically significant (t
= –1.360; df = 3.323; P = 0.259). Table 3 shows
the comparison of the mean of the interocular AL
difference between children and adult groups as
categorized by treatment outcome.

DISCUSSION

The findings of this study indicate that the
interocular AL difference in patients with
unsuccessful treatment outcomes was significantly
larger than patients with successful treatment
outcomes and those of the control group.
Recent studies have indicated the existence
of a significant correlation between anisometropia
and the interocular AL difference in anisometropic
amblyopia patients.[13, 15, 17, 21, 22]

Studies suggest that amblyopia cannot be
treated beyond a critical age because of the lack
of adequate plasticity in the adult brain.[23] In this
study, amblyopia was treated successfully in four
adults. The findings of this study indicate that
even in children, amblyopia may not be treated

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Axial Length and Amblyopia Treatment; Ghasempour et al

Table 3. Comparison of the mean of the interocular axial length difference (mm) between the children and adult group based
on amblyopia treatment outcomes.

Age group
(yr)

Number Minimum Maximum Mean ± SD Mean
standard
error

P-value

Control group 5–15 43 0.02 0.41 0.12 ± 0.08 0.01 P = 0.458
16–45 17 0.03 0.28 0.13 ± 0.06 0.02

Good treatment outcome 5–15 55 0.00 0.99 0.34 ± 0.25 0.03 P = 0.407
16–45 4 0.05 0.38 0.22 ± 0.14 0.07

Failure of successful
treatment outcome

5–15 15 1.14 3.89 1.90 ± 0.91 0.24 P = 0.788
16–45 9 1.16 3.00 1.69 ± 0.61 0.20

SD, standard deviation; yr, year

 

Figure 1. The box plot distribution of the interocular axial length difference (mm), categorized based on amblyopia treatment
outcomes in the children (A) and adults (B) groups.

successfully in all patients. Bonacorci et al reported
that due to the flexibility of the visual system,
the results of anisometropic amblyopic treatment
could vary depending on the age of treatment.[23]
Meanwhile, Lia et al have not mentioned age as
a main factor in treatment outcomes.[24] We report
that the mean of the interocular AL difference
was larger when treatment was unsuccessful
(compared to the successful treatment group and
the controls). This finding was consistent for both
the children and the adult group. In both age
groups, it seems that the interocular AL difference

may assist in predicting the outcomes of the
amblyopia treatment.

In our study, the interocular AL difference was
larger in the group with unsuccessful treatment
outcomes when compared to the group with
successful treatment and the controls. The
higher interocular AL difference in the group
with unsuccessful treatment outcomes confirms
that the hypermetropic amblyopic eye had an
AL that was shorter than the non-amblyopic eye.
Lempert et al in a study involving 927 aniso-
hypermetropic amblyopic patients aimed at
examining the AL to the optic nerve disk area ratio

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Axial Length and Amblyopia Treatment; Ghasempour et al

Figure 2. The box plot distribution of the anisometropia (diopter), categorized based on amblyopia treatment outcomes in the
children (A) and adult (B) groups.

(AL/DA).[25] According to the report, the area of
the optic nerve disc in the amblyopic eyes was
significantly smaller than that of the non-amblyopic
eyes. Also, the size of the optic nerve disc and AL
in the more hypermetropic eye was smaller than
the optic disc and AL of the non-amblyopic eye.
Furthermore, in a study on monkeys, Swadlow et
al have reported that the diameter of axons with
the highest transmission speed was 20 microns. In
comparison, the axons with the slowest speed of
transmission had a diameter of about 0.1 micron.[26]
Based on these two studies, it can be postulated
that the speed of transmission of neural impulses
may be linked to the diameter of axons. It can
also be suggested that perhaps interocular AL and
optic disc size differences lead to some sort of
interference in the speed of transmission of retinal
images between the retina and the visual cortex,
thus creating an abnormal development of the
visual cortex of the amblyopic eyes.

Our results suggest that in anisometropic
amblyopes who achieve better treatment
outcomes as well as in controls, AL shows smaller
differences between the two eyes. Interestingly,
this finding was similar across the two tested
age groups. Based on the results of this study,
the difference of AL between the two eyes of
each individual may assist with the prediction of
treatment outcomes in anisometropic amblyopic
patients. Although our study has successfully
determined the existing relationship between
interocular AL difference and treatment outcomes
for anisometropic amblyopia, further studies using
larger sample sizes are warranted to expand our
knowledge on the topic.

Financial Support and Sponsorship

Nil.

Conflicts of Interest

None declared.

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