Original Article

Binocular Function in Different Gaze Positions

Amir Asharlous1, PhD; Asgar Doostdar1, PhD; Vahid Ghaemi2, MS; Mina Farzi1, MS; Abbasali Yekta3, PhD;
Abolghasem Mortazavi4, MD; Hadi Ostadimoghaddam5, PhD; Mehdi Khabazkhoob6, PhD

1Rehabilitation Research Center, Department of Optometry, School of Rehabilitation Sciences, Iran University of Medical
Sciences, Tehran, Iran

2Noor Research Center for Ophthalmic Epidemiology, Noor Eye Hospital, Tehran, Iran
3Department of Optometry, School of Paramedical Sciences, Mashhad University of Medical Sciences, Mashhad, Iran

4Sina Hospital, Department of Neurosurgery, Tehran University of Medical Sciences, Tehran, Iran
5Refractive Errors Research Center, Mashhad University of Medical Sciences, Mashhad, Iran

6Department of Basic Sciences, School of Nursing and Midwifery, Shahid Beheshti University of Medical Sciences, Tehran, Iran

ORCID:
Amir Asharlous: https://orcid.org/0000-0003-4631-215X
Abbasali Yekta: https://orcid.org/0000-0003-4356-9064

Abstract

Purpose: To evaluate varied aspects of binocular function in multiple gaze
positions.
Methods: In 2018, this cross-sectional study was conducted on 21 participants
(male = 11) with an age range of 19–25 years. Having emmetropia and 10/10
visual acuity in both eyes were conditions of the inclusion criteria for the cross-
sectional study. The following aspects of binocular function including amplitude
of accommodation (AA), near point of convergence, near phoria, and monocular
accommodative facility were evaluated in five gazes (primary, upward, downward,
left, and right) for all subjects.
Results: Near point of convergence values showed significant differences in all
gaze positions (P < 0.001). The lowest near point of convergence value was seen
in the primary gaze (2.69 cm) and the downward gaze (3.47 cm) and the highest
near point of convergence value was seen in the left gaze (7.5 cm). There was also
a significant difference in the amplitude of accommodation among the upward,
downward, and the primary gaze (P < 0.001) positions but no difference was
observed among the temporal, nasal, and the primary gaze positions. There was
a significant difference in near phoria between the upward gaze and the primary
gaze (P = 0.008) while no significant differences were observed among the other
gazes. There was no significant variance in the monocular accommodative facility
among the different gaze positions (P = 0.175).
Conclusion: The results of this study indicated variations that exist in the
convergence and accommodation reflex functions in multiple gaze positions,
which proved to be more prominent in the convergence system. Although the
accommodative sufficiency evaluation was inconsistent among the multiple gaze
positions, the accommodative facility evaluation was consistent in all gazes.

Keywords: Accommodation; Binocular Vision; Convergence; Facility; Gaze; Phoria

J Ophthalmic Vis Res 2022; 17 (2): 209–216

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Binocular Function in Different Gazes; Asharlous et al

INTRODUCTION

Binocular vision incorporates several reflexes
including accommodation and convergence.
Accommodation is a conditional reflex that
provides a clear retinal image at different distances
through regulating the crystalline lens curvature.[1]
Convergence is another conditional reflex of the
visual system that is stimulated by disparity on the
retina. It occurs following diplopia resulting from
stimulation of non-corresponding points in the
fellow eyes and preventing diplopia through the
disconjugate movement of the eyes.[2] Therefore,
convergence is an anti-diplopia reflex while
accommodation is an anti-blur mechanism. These
two reflexes cooperate in forming a single and
clear image at different distances. Suppression
or stimulation of the accommodative reflex
cause changes in the vergence reflex and vice
versa. Therefore, these reflexes have important
codependent interactions where disorders in
either one can disturb the function of the other.[3]

As a result of the multiple gaze positions,
especially in upward and downward gazes, vertical
rectus, horizontal rectus, and oblique muscles are
involved in abduction and adduction processes, so
the amount of convergence may vary at different
directions.[4] The presence of deviations with A,
V, X, and Y patterns indicates that within these
deviations, varied amounts of convergence in
upward and downward gazes results in diverse
amounts of esotropia and exotropia in multiple
directions.[5–7] Since the accommodative system
has a neural link with the vergence system
and there is interaction between them, it is
expected that the accommodative function will
vary in multiple gaze positions, especially in the
vertical direction. A few studies have investigated
accommodation and convergence variances in

Correspondence to:

Abbasali Yekta, PhD. Department of Optometry, School
of Paramedical Sciences, Mashhad University of Medical
Sciences, Mashhad 9177948964, Iran.
Email: yektaa@mums.ac.ir
Received: 10-04-2021 Accepted: 07-09-2021

Access this article online

Website: https://knepublishing.com/index.php/JOVR

DOI: 10.18502/jovr.v17i2.10792

multiple gaze positions in the past.[8–11] Ripple et
al reported marked differences in AA in varied
gaze positions,[8] while Atchison et al found no
significant variances in this regard.[9]

As for convergence, a study by Sheni et
al on nine subjects found multiple values for
convergence in varied gaze positions.[10] The
results of an interesting study by Nguyen et al
in 2008 showed changes in the accommodative
convergence/accommodation results when tested
in different gaze positions.[12]

As mentioned previously, there were
discrepancies in the results of previous studies
which suffered from serious shortcomings and
flaws. One of the main flaws of these studies
was that they only assessed the accommodative
or convergence system exclusively and did not
evaluate both of them and their codependent
effects. In addition, the sample size was very small
in some studies like the one conducted by Nguyen
et al. Another shortcoming was that they only
addressed the amplitude of accommodation
and did not study other functional aspects
like facility. Therefore, it is recommended that
comprehensive studies be conducted to assess
the accommodative system from both aspects of
amplitude and facility in multiple gaze positions
while also comparing the convergence amplitude
in the same gaze directions. In addition, besides
these two reflexes, the amount of phoria should
also be investigated in multiple gaze positions.
Considering the strong interaction among these
parameters, such studies help to understand their
impact on the mechanism of binocular vision in
varied gaze positions. This study was conducted
to evaluate the binocular function aspects of
accommodative and convergence systems as well
as phoria in multiple gaze positions.

METHODS

This cross-sectional study was conducted on
a group of volunteers aged 19–25 years who

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: Asharlous A, Doostdar A, Ghaemi V, Farzi M, Yekta
A, Mortazavi A, Ostadimoghaddam H, Khabazkhoob M. Binocular Function
in Different Gaze Positions. J Ophthalmic Vis Res 2022;17:209–216.

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Binocular Function in Different Gazes; Asharlous et al

met the inclusion criteria in 2019. The inclusion
criteria were the following: a corrected visual acuity
of 10/10 in both eyes; hyperopia, myopia, and
astigmatism of maximum 0.5 diopter; complete
ocular health; lack of strabismus; and no history of
strabismus surgery. The tenets of the Declaration
of Helsinki were observed in this study and its
protocol was approved by the Ethics Committee
of Shahid Beheshti University of Medical Sciences.
The participants were assured of data anonymity
and confidentiality and informed consent was
obtained from all of them.

Primary Examinations

Demographic data of the participants were
recorded and history of ocular and visual problems
was taken. All examinations were conducted by
an expert optometrist. Auto refraction was done
for both eyes to evaluate the inclusion criteria
(TOPCON, KR-8900, Japan) and the visual acuity
of the fellow eyes was measured using a Snellen
chart. Ocular health was then evaluated using a slit
lamp (TOPCON SL-6E, Japan). The patients were
admitted into the study if they met the inclusion
criteria.

Binocular Examinations

All subjects who met the inclusion criteria and
joined the study underwent complete binocular
examinations including the measurement
of accommodative amplitude, near point of
convergence, monocular accommodative facility,
and near-cover test to measure near phoria in the
primary gaze as well as the upward, downward,
left, and right gazes. Positioning for the test target
was determined relative to the primary gaze where
the visual target was presented at an angle of 40º
in each of the various gaze positions.

A protractor and ruler were used to fix the
angle at the different gaze positions. Using a
protractor and placing the zero degree on the
primary position (facing the patient’s pupil), 40º
to the relevant gaze was determined and then a
33-cm long ruler was placed from the center of
the protractor and at a 40º angle position in the
direction of the respective gaze. The target was
then placed at the end of the ruler, in the direction
of the center of the cornea, and the angle and
distance for each test were checked again. All

these measurements were done very carefully. In
all of the studied gazes, great emphasis was placed
on the correct determination of the 40º angle. How
to control the angle and distance is illustrated in
Figure 1.

The order of the tests was randomized within
the various subjects and also within the multiple
gaze positions. A 5-min washout time was applied
between each test and measurements in the varied
gaze positions.

The optotypes on the 20/30 line of a near
Snellen chart were used as the fixation target.
One eye was occluded and the patient was asked
to fixate on the target during the test and try to
keep it single and clear. Negative lenses were
then added at 0.25 diopter steps. When the target
became clear, stronger lenses were introduced.
This process continued until the patient reported a
sustained blur and could not see the target clearly
using the last applied lens. In this condition, the
immediate previous lens’ power was recorded as
the final lens power. The final lens power was then
added to 2.5 diopter and the result was recorded
as the amplitude of accommodation. This process
was done in all of the five gaze positions.

The optotypes on the 20/30 line of a near
Snellen chart were also used as the fixation target
for the near point of convergence measurement.
With both eyes open, the target was moved
towards the patient’s eyes along the nasal bridge
at a speed of 1 cm/s and the patient was asked
to keep the target single and clear. The nearest
distance between the target and the nasal bridge
at which the patient reported a sustained double
vision (subjective) or the examiner noticed an
ocular deviation or a fusion break (objective) was
considered the near point of convergence and its
value was recorded in cm. In addition to the primary
gaze position, this measurement was repeated in
the other four gaze positions at an angle of 40º.

The monocular accommodative facility was
measured using ±2.00 diopter flippers. The 20/30
optotypes were presented to the patient at 40 cm
and the patient was asked to fixate on the target
during the test and try to keep it single and clear
with one eye closed. Positive and negative lenses
were alternately presented to the patient and the
patient was asked to report the moment the target
became clear. A stopwatch was used to measure
the time in seconds from the moment the first lens
was applied. Each instance of clearing both plus

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Binocular Function in Different Gazes; Asharlous et al

and minus lenses was counted as one cycle, and
the number of cycles per 1 min was recorded as the
monocular accommodative facility.

An alternate cover test was applied to measure
near phoria. Ocular recovery movements were
evaluated upon alternate occlusion and the
direction of deviation was determined using the
recovery direction. A prism bar was then used to
measure the amount of deviation using the prism
alternate cover test. Corrective prism was added
until no recovery movements were noticed on the
alternate cover test. Exophoria and esophoria were
recorded as minus and plus values, respectively.

Statistical Analysis

The SPSS software was used for statistical analysis.
Mean and standard deviation were used to
describe the data.

For statistical comparison, data normality was
checked using the Kolmogorov–Smirnov test. To
compare the five gazes, the mean values of the
gazes were used. To evaluate the difference in
variables between males and females, t-test was
used if the data had a normal distribution and
Mann–Whitney was applied if the data had a non-
normal distribution.

For analytical analysis, because the data were
dependent variables, repeated measured analysis
of variance was applied for comparison between
the different gaze positions. P-values <0.05 were
considered significant.

RESULTS

In this study, the data of 21 subjects, including
11 men (mean age = 21.90 ± 1.78 years) were
analyzed. The mean and standard deviation of the
parameters in five gaze positions are presented in
Table 1 and Table 2 according to sex and all cases,
respectively. None of the studied parameters were
significantly different between male and female
[Table 1].

There was a significant variance in the amplitude
of accommodation among the different gaze
positions (P < 0.001). The results indicated
a significant difference in the amplitude of
accommodation among the upward and downward
gaze positions and the primary gaze position (P =
0.002), while there was no significant difference

among the left (P = 0.261) and right (P = 0.149) gaze
positions and the primary gaze position.

There was a significant variance in near point of
convergence among the different gaze positions
(P < 0.001). Pairwise comparison between each
type of gaze and the primary gaze position
indicated significant variances in all gazes (P <
0.018). The smallest and largest near point of
convergence value was seen in the primary and left
gaze position, respectively. Repeated measured
Analysis of Variance (ANOVA) showed a significant
variance in the amount of near phoria among
the five gaze positions (P = 0.026), and post-hoc
revealed that the difference between the primary
gaze and the up-gaze position (P = 0.008) showed
the highest amount of exophoria.

There was no significant difference in the
monocular accommodative facility among the
different gaze positions (P = 0.175).

DISCUSSION

This study compared multiple functions of
binocular vision among different gaze positions.
As mentioned earlier, there was a significant
variance in the near point of convergence among
the varied gaze positions. These findings were
exactly similar to the results of a study by Sheni et
al[10] that reported the minimal vergence amplitude
in 40º left and right gaze positions and the maximal
vergence range between 10º and 20º below the
primary horizontal plane. According to their study,
the vergence range increased from the straight-
ahead gaze position to 20º below the primary
horizontal plane and then decreased from 20º to
40º in the same direction such that the vergence
value was smaller in 40º below the horizontal
plane as compared to the primary gaze.[10]

In addition, near point of convergence findings
showed convergence conditions in multiple
degrees of gaze as compared to the primary
position of gaze in the horizontal plane, while it
was not true for vertical gaze positions. Therefore,
it can be stated that in the various horizontal
gaze positions, the function of the horizontal
rectus muscles, including medial rectus and lateral
rectus, decrease symmetrically in the left and right
gaze positions. It seems that the muscle force
of lateral rectus and medial rectus is similar to
the degrees of the right and left gaze position.
However, this functional symmetry is not seen

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Binocular Function in Different Gazes; Asharlous et al

Table 1. The mean and standard deviation (SD) of indices in different gazes according to sex

Gaze Male Female P-value* P-value**

Mean ± SD Mean ± SD

Phoria (PD)

Primary –4.00 ± 3.69 –2.4.0 ± 2.8 0.118 0.28
Up –4.91 ± 3.81 –4.00 ± 3.16 0.2 0.561

Down –3.18 ± 5.47 –1.00 ± 2.00 <0.001 0.426∗∗∗

Left –4.36 ± 3.44 –2.8 ± 3.26 0.015 0.197∗∗∗

Right –3.73 ± 2.83 –2.60 ± 3.13 0.006 0.426∗∗∗

AA (D)

Primary 9.45 ± 1.46 9.40 ± 1.54 0.056 0.934
Up 9.09 ± 1.58 9.30 ± 1.44 0.016 0.918∗∗∗

Down 9.91 ± 1.56 9.75 ± 1.57 0.152 0.819
Left 9.73 ± 1.46 9.35 ± 1.36 0.2 0.547
Right 9.32 ± 1.35 9.20 ± 1.49 0.2 0.851

NPC (cm)

Primary 22.73 ± 17.94 31.50 ± 16.17 0.044 0.152∗∗∗

Up 73.18 ± 31.01 60.50 ± 31.57 0.2 0.365
Down 26.82 ± 20.03 43.50 ± 18.86 0.123 0.065
Left 67.73 ± 33.86 83.00 ± 27.71 0.2 0.275
Right 74.09 ± 50.59 66.00 ± 29.42 0.2 0.664

MAF (CPM)

Primary 13.18 ± 8.32 7.10 ± 5.63 0.2 0.067
Up 10.82 ± 7.19 8.00 ± 7.13 0.2 0.379

Down 12.00 ± 6.93 7.80 ± 7.05 0.189 0.185
Left 12.09 ± 7.20 7.90 ± 6.64 0.161 0.183
Right 12.64 ± 7.42 8.80 ± 7.58 0.159 0.256

AA, accommodation amplitude; NPC, near point of convergence; MAF, monocular accommodative facility; CM, centimeter; CPM,
cycle per minutes; PD, prism diopters
∗P-value was calculated by Kolmogorov–Smirnov for normality; ∗∗P-value was calculated by independent sampl t-test; ∗∗∗P-value
was calculated by Mann–Whitney U-test

in the vertical plane. Convergence decreased
in the upward and downward gaze positions
as compared to the primary position of the gaze,
which was more noticeable in the up-gaze position.
The reason for this finding may be that horizontal
rectus muscles do not apply a similar muscle force
in varied degrees of the vertical gaze, which was
reported in previous studies as well. Previous
studies also found that the muscle force of LR and
MR decreased in the extreme up and down gaze
positions as compared to the primary gaze.[13,14]
Another reason for decreased convergence
power in up- and down-gaze positions may be the
interaction of superior and inferior oblique muscles
in these positions. Since these muscles are both
abductor muscles, this abduction decreases
convergence in the up-gaze position due to the
function of the inferior oblique muscle and in the

down-gaze position due to the function of the
superior oblique muscle.[15]

The question is why is convergence stronger
in the downward gaze as compared to the
upward gaze position? The first reason may be
the conditional nature of the vergence reflex.[16]
Convergence is a conditional reflex, that is, it is
capable of learning and improving over time.[16,17]
It can be concluded that more ocular work
in the down-gaze position during life due to
normal activities like reading and other near-work
activities, which are usually done in this gaze
position, strengthen the vergence reflex in the
down-gaze position as compared to the up-gaze
position. This is also consistent with the results
of a study by Sheni that reported the maximal
vergence range between 10º and 20º below
horizontal plane, which is the gaze position used

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Binocular Function in Different Gazes; Asharlous et al

Table 2. The mean and standard deviation (SD) of indices in different gazes

Left Right Down Up Primary P-value∗ P-value∗∗

Mean ± SD Mean ± SD Mean ± SD Mean ± SD Mean ± SD
AA (D) 9.54 ± 1.38 9.26 ± 1.38 9.83 ± 1.52 9.19 ± 1.47 9.42 ± 1.46 0.2 0.001
NPC (cm) 7.50 ± 3.13 7.02 ± 4.10 3.47 ± 2.08 6.71 ± 3.11 2.69 ± 1.79 0.2 0.001
MAF (CPM) 10.10 ± 7.09 10.81 ± 7.56 10.00 ± 7.14 9.48 ± 7.13 10.29 ± 7.64 0.099 0.175
Phoria (PD) –3.62 ± 3.36 –3.19 ± 2.96 –2.14 ± 4.29 –4.48 ± 3.45 –3.24 ± 3.21 0.2 0.026

AA, accommodation amplitude; NPC, near point of convergence; MAF: monocular accommodative facility; CM, centimeter; CPM,
cycle per minutes; PD, prism diopters
∗P-value was calculated by Kolmogorov–Smirnov for normality in mean of five gazes; ∗∗P-value was calculated by repeated
measured ANOVA

 

Figure 1. How to adjust angles and distances for measurements at different gaze positions. Cm; centimeter.

for reading and other near-work activities,[18,19] as
compared to the primary position of the gaze.[10]
The second reason may be related to the neural
link of the vergence and accommodative systems,
that is, the ratio of accommodative convergence to
accommodation.[20] Since the results of this study
and some previous studies showed a stronger
accommodative reflex in the down-gaze versus the
up-gaze position,[8,9] it can be expected that the
same may be true for convergence as well. In
fact, because there is more accommodation in the
down-gaze position, accommodative convergence
is also stronger, resulting in higher amplitude of
convergence.

The accommodative findings of the present
study revealed the largest accommodative power
in the down-gaze and the smallest in the up-
gaze position. Some previous studies found similar
results. Ripple et al found that the largest amplitude
of accommodation was for the down-gaze position
followed by the nasal gaze.[8] However, the

dioptric amount of difference was much larger
in their study as compared to the present study
such that the amplitude difference was 3 diopters
between the extremes of the vertical plane
and 1.5 diopter between the extremes of the
horizontal plane. Atchison et al found a higher
amplitude of accommodation at the down-gaze
position as compared to other directions and
reported that this difference, although clinically
unimportant, was statistically significant.[9] Their
findings are consistent with our results. In general,
as for amplitude of accommodation changes
in different gaze positions, it can be stated
that accommodation usually has slightly larger
amplitude in the primary and down-gaze positions
and is weaker in the up-gaze position. A relatively
stronger accommodation in the down-gaze
position may be due to the conditional nature
of the accommodative reflex. Accommodation
is also a conditional reflex and repeated usage
of conditional reflexes during life strengthens

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Binocular Function in Different Gazes; Asharlous et al

them.[16] It may seem logical that because routine
near-work activities are done in the down-gaze
position, this reflex is strengthened in this position
and because the use of accommodation is very
limited in the up gaze, its amplitude is not as large.

Regarding phoria, only the difference in near
phoria between the up-gaze and primary gaze
positions was significant, and this gaze had the
largest amount of exophoria. The highest and
lowest amount of exophoria was seen in the up-
and down-gaze positions, respectively, while there
was no significant difference in the amount of
exophoria between left- and right-gaze positions
and the primary position of gaze. These findings
were consistent with the results of near point
of convergence. A larger range of vergence in
the down-gaze and a smaller range in the up-
gaze position contribute to more exophoria in
the up-gaze position. On the other hand, there
was no difference in near point of convergence
between the left- and right-gaze positions and the
primary position of the gaze, which was similar to
exophoria. An even more interesting finding was
that near point of convergence was slightly larger
in the left gaze versus the right gaze (which was
not statistically significant), indicating a stronger
convergence in the right gaze. This finding was
consistent with the results of phoria in the resent
study, indicating lower exophoria in the right-gaze
position.

Although there were significant differences in
amplitude of accommodation and vergence range
between different gaze positions, no significant
difference was found in accommodative facility.
Therefore, it can be concluded that amplitude of
accommodation has no marked relationship with
facility from a functional point of view and they
have separate functions, which emphasizes that
different aspects of the accommodative function
should be evaluated separately and their findings
should be analyzed independently in the clinical
setting.

Based on the results of the present study, it can
be concluded that amplitude of accommodation
and convergence are inconsistent in multiple
gaze positions. This difference is more apparent
in the vertical plane in the accommodative
system and in both the vertical and horizontal
planes in the vergence system. Convergence
decreases symmetrically from the primary
position of gaze toward left- and right-gaze
positions (horizontal plane) while its changes are

completely asymmetrical in the vertical plane
with a larger decrease in the up-gaze position.
Although amplitude of accommodation varies in
different gaze positions, there is no variance in
accommodative facility among the different gaze
directions. Phoria changes were similar to and
consistent with convergence changes in various
gaze positions: the highest and lowest amount of
exophoria was seen in the upward and downward
gaze positions respectively, while there was no
significant difference in the amount of exophoria
between the horizontal gaze positions and the
primary position of gaze.

Financial Support and Sponsorship

This project was supported by Iran University of
Medical Sciences.

Conflicts of Interest

No conflicting relationship exists for any author.

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