Original Article

Prevalence and Burden of Refractive Errors at National
and Sub-national Levels in Iran

Seyed Farzad Mohammadi1, MD- FICO; Farshad Farzadfar2, MD; Parinaz Mehdi Pour2, MS
Elham Ashrafi1, PhD; Alireza Lashay1, MD; Bahram Mohajer2, MD; Mohsen Asadi Lari3, MD

1Translational Ophthalmology Research Center, Farabi Eye Hospital, Tehran University of Medical Sciences, Tehran, Iran
2Non-Communicable Diseases Research Center, Endocrinology and Metabolism Research Institute, Tehran University of

Medical Sciences, Tehran, Iran
3Department of Epidemiology, School of Public Health, Iran University of Medical Sciences, Tehran, Iran

ORCID:
Seyed-Farzad Mohammadi:0000-0002-9209-3034

Elham Ashrafi:0000-0001-8640-0168

Abstract

Purpose: To estimate the prevalence, burden of refractive errors and their
associated trend from 1990 to 2018 and geographic inequalities in Iran.
Methods: Data regarding the epidemiology of refractive errors was extracted
from three different sources: systematic review of published literature, data from
visual school screening programs, and data from Iran’s national health survey
(NHS). The pool of all available data on refractive errors as well as demographic,
location, and socioeconomic status covariates were fitted in spatio-temporal and
Gaussian process regression models to predict the prevalence of refractive errors
from the years 1990 to 2018 in 31 provinces grouped by age and sex in order to
calculate years lived with disability (YLDs).
Results: In 2018, the age-adjusted prevalence of refractive errors was 16.32%
(95% uncertainty interval [UI]: 12.44–21.48%) in both sexes, 17.98% (95% UI: 13.74–
23.61%) in women, and 14.66% (95% UI: 11.14–19.36%) in men. The prevalence of
refractive errors reveals that it increases with age. Refractive errors contributed to
441.41 and 348.38 YLDs in men and women, respectively. The age-standardized
prevalence growth was 31.30% in females and 24.32% in males from the years
1990 to 2018. Significant geographical heterogeneity was observed. The age-
standardized YLDs rates of refractive errors represent an increasing trend of
28.9% increase from 1990 to 2018.
Conclusion: Over 28 years, the prevalence of refractive errors increased
significantly. Women tend to have higher rates of prevalence. The prevalence
increased in older ages. Border provinces had the lowest prevalence. Age-
standardized YLDs rates of refractive errors increased by about 30%.

Keywords: Burden; Disability-adjusted Life Years; Iran; Prevalence; Refractive Errors

J Ophthalmic Vis Res 2022; 17 (1): 78–88

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Refractive Errors in Iran; Mohammadi et al

INTRODUCTION

Refractive errors are recognized as approximately
half of the causes of visual impairment (VI)
and the second leading cause of functional
blindness.[1] It impinges on patients’ quality of life
through functional, psychosomatic, and cosmetic
issues while also causing economic burden.[2]
Refractive errors are listed among one of the
four non-fatal disorders classified in the 20 top
causes of disability-adjusted life years (DALYs).[3]
Since refractive disorders mostly initiate early in
life, remarkable morbidity assessed by years of
living with disability (YLDs) is associated more
with this eye disorder as compared to other
ocular diseases.[3] Compared to other causes
of VI, refractive errors in most cases is easily
treatable by prescribing glasses which is one
of the most cost-effective interventions in eye
care. If left uncorrected, refractive errors can
affect performance, reduce employability, and
productivity, and compromise the entire life of
patients.[2–5]

Uncorrected refractive disorders relative to
the total DALYs increased by 42% globally when
compared to 1990,[6] and refractive disorders
were responsible for the loss of healthy life
of approximately 44.8 years per 100,000
population globally with an increasing trend
and with an advance in age from 40 years
onward.[7, 8] The Eastern Mediterranean region
has the second-highest DALY recorded from
refractive errors among world regions. This is
the consequence of a higher prevalence (188.7;
95% uncertainty interval [UI]: 125.3–276.9%) of
refractive error in addition to the suboptimal
implementation of prevention/treatment options.
Therefore, cost-effective prevention programs
are recommended to address this epidemiological

Correspondence to:

Elham Ashrafi, PhD. Translational Ophthalmology
Research Center, Farabi Eye Hospital, Tehran
University of Medical Sciences, Qazvin Square, Tehran
1336616351, Iran.
E-mail: eashrafi@sina.tums.ac.ir
Received 29-05-2021; Accepted 21-09-2021

Access this article online

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

DOI: 10.18502/jovr.v17i1.10173

priority.[6] Refraction/accommodation (functional)
disorders in Iran accounted for 0.42% DALY in 1990
and 0.47% in 2010, where the associated costs
and issues were greater than that of other causes
of VI, namely cataract, glaucoma, and macular
degeneration.[9]

Providing reliable evidence and situational
analysis is required for promoting good health
practices. Global Burden of Disease (GBD) 2017
has presented estimates for the economic and
social burden of refractive errors; which, however,
lack subnational estimates and comprehensive
inclusion of the present national surveys data in
Iran.

This study aims to estimate the incidence,
prevalence, burden, and trend of refractive errors
during the period of 1990 to 2018 at the national
and sub-national levels in Iran.

METHODS

Data Sources

This research represents secondary data analysis
on three data sources; the systematic review of
published literature, data from the Ministry of
Health and Medical Education (MoHME) screening
programs, and Iran’s National Health Survey (NHS)
data [Figure 1]. A detailed explanation of the search
strategy and cleaning process of all data sources is
presented in a supplementary document.[10]

Systematic review

Published literature between January 1980 and
December 2018 present in Medline (PubMed), ISI
Web of Science, Scopus, Iranian Digital databases
of SID (http://www.sid.ir), Barakat knowledge
network system (http://health.barakatkns.com),
and in the national ophthalmic literature
database by Noor Ophthalmology Research
Center (http://iraneyedoc.com) were all searched.

This is an open access journal, and articles are distributed under the terms of
the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 License, which
allows others to remix, tweak, and build upon the work non-commercially, as
long as appropriate credit is given and the new creations are licensed under the
identical terms.

How to cite this article: Mohammadi SF, Farzadfar F, Pour PM, Ashrafi E,
Lashay A, Mohajer B, Lari MA. Prevalence and Burden of Refractive Errors at
National and Sub-national Levels in Iran. J Ophthalmic Vis Res 2022;17:78–
88.

JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 1, January-March 2021 79

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http://health.barakatkns.com
http://iraneyedoc.com


Refractive Errors in Iran; Mohammadi et al

Additionally, the abstract books of the Iranian
ophthalmology annual congresses from the years
2008 through 2010 were screened and included
only if the inclusion criteria was satisfied. A
detailed explanation of the study selection criteria
and critical appraisal is described in the protocol
paper.[10] A crosswalk method was applied in
extracting the pertinent data where cases related
to myopia/hyperopia/astigmatism were combined
to those of refractive error and modified the
rural/urban scope. A total of 146 data points from
10 provinces were extracted from the systematic
review and included in the analysis [Table 1].

Refractive error screening programs

Unpublished official data for the prevalence of
refractive errors occurring in the years 2007,
2010, and 2012 were gathered from screening
programs performed in the elementary schools of
all the provinces. A total of 1156 data points were
extracted [Table 1].

National Health Survey

The National Health Survey (NHS) includes two
self-reporting questions about spectacles use (“Do
you use glasses?”) and spectacles need (“Do
you need glasses to see clearly?”) in all age
groups and provinces in the years 1990 and
2000. After an adjustment of the NHS data by
MoHME/Systematic Review Data while using a
crosswalk method and adjusting for missing data,
a total of 1488 data points were generated [Table
1].

Statistical Analysis

A total number of 2790 data points were included
from the above data sources. We aimed to
estimate the prevalence of refractive errors for
different age groups, between the two sexes, at
national level, and in 31 provinces, from the years
1990 to 2018. Generalized Linear Mixed Model
(GLMM) was applied to impute missing values
of these age-sex-location-time combinations. In
this model, we predicted the prevalence of
refractive errors with fixed covariates, including
years of schooling, wealth indices, urbanization
ratios, as well as the random effects of the
location of the provinces. Urbanization ratios and

population data were retrieved from the national
censuses, which were conducted by the Statistical
Center of Iran (SCI). To calculate other covariates
in the statistical models, we used Household
Expenditure and Income surveys from the years
1990 to 2018, which were also conducted by the
SCI. The second step after applying the GLMM
was the application of an age-spatio-temporal
(AST) model capturing all variations for time,
location (province), and age groups of residuals
from the first model. In the AST model, we
assumed that there were unmeasured variations
in residuals that were derived from GLMM. To
estimate these variations, we weighted adjacent
years, provinces, and ages by three matrices and
used neighboring elements of the matrix that
had more correlation with each other where this
measure decreased by increasing their distances.
The weighted residuals were then added back
to GLMM predictions and final estimates of
prevalence were produced. In order to have robust
estimates with certainty, using estimated rates,
we employed Gaussian Process Regression (GPR)
which is a Bayesian technique. It defines a flexible
model with hierarchical priors for its parameters
and it also has a mean and covariance function.
In this study, these functions were defined in the
AST model and the Matérn function, respectively.
Gaussian Process Regression (GPR) samples were
drawn from the posterior distribution by using
the Markov Chain Monte Carlo method and we
calculated the median for the final estimates of
prevalence and 2.5 and 97.5 percentiles for its
uncertainty.[10]

The data collected from the 2018 record of
the national population in Iran was used as the
standard population in a direct age-standardized
analysis to facilitate the statistical comparisons
between provinces.

Since refractive errors do not have fatal
consequences, DALYs were considered equal
to YLDs, which were estimated by multiplying the
prevalence by the reported disability weight for
refractive errors in the GBD study, and the duration
of symptoms.

RESULTS

Prevalence of Refractive Errors

At national level, in the year 2018, the age-adjusted
prevalence of refractive errors was estimated at

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Refractive Errors in Iran; Mohammadi et al

Table 1. Data source specifications.

Source Sex Age (yr) Province Year Coverage Number of data
point

Systematic Review Male/female All ages 10 1999–2014 Sub-national 146 (5.23%)

Ministry of Health Male/female 7–15 31 2007, 2010,
2012

National/sub-
national

1156 (37.6%)

National Health Survey Male/female All ages 31 1990, 2000 National 1049 (41.43%)

Table 2. Prevalence of refractive errors by sex and age group in year 2018.

Age group (yr) Sex Prevalence Lower limit Upper limit

0–6 Female 1.25 1.1 1.41

0–6 Male 1.01 0.9 1.13

7–11 Female 4.26 3.04 5.97

7–11 Male 3.33 2.34 4.75

12–14 Female 7.6 5.56 10.39

12–14 Male 6.1 4.42 8.42

15–17 Female 7.31 5.22 10.27

15–17 Male 5.58 3.91 7.95

18–24 Female 12.32 9.62 15.75

18–24 Male 9.48 7.17 12.54

25–34 Female 11.42 8.69 14.98

25–34 Male 8.53 6.57 11.05

35–44 Female 16.35 12.96 20.66

35–44 Male 13.1 10.12 17.02

45–54 Female 27.16 21.51 34.23

45–54 Male 25.62 19.56 33.56

55–64 Female 30.71 24.55 38.45

55–64 Male 23.12 18.1 29.6

65–74 Female 32 24.99 40.95

65–74 Male 26.43 21.05 33.17

75–84 Female 36.22 26.91 48.93

75–84 Male 27.94 20.57 38.14

85 Female 29.22 20.72 41.31

85 Male 25.75 19 34.95

16.32% (95% UI: 12.44%, 21.48%). It is 17.98% (95%
UI: 13.74–23.61%) in women and 14.66% (95%
UI: 11.14–19.36%) in men. The age-standardized
prevalence increased by 31.30% in females and
24.32% in males during the years 1990 to 2018.

The prevalence of refractive errors showed an
increasing trend with age in both sexes, with the
highest prevalence among women older than 85

years with a prevalence of 29.22% (95% UI: 20.72–
41.31%) in 2018. The highest rise is seen in ages 35
to 44 years [Table 2; Figures 2 & 3].

Geographic Distribution of Refractive Errors

The age-standardized prevalence of refractive
errors in different provinces is reported in
Figure 4. Provinces heterogeneity was observed

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Refractive Errors in Iran; Mohammadi et al

Table 3. Age-standardized DALYs per 100,000 in different years and sex.

Year Male Female

1990 144.95 177.86

1995 172.69 213.64

2000 205.87 257.28

2005 255.14 319.81

2010 302.38 381.64

2018 348.38 441.41

Figure 1. Analysis process for YLDs calculation. DALY, disability-adjusted life years; YLD, years lived with disability.

consistently during the study period. The highest
age-standardized prevalence recorded in 2018
was 20.4% in North Khorasan while the lowest was
discovered in Tehran with a prevalence of 13.8%.
Country provinces located at the borders tend to
have lower levels of refractive errors while central
provinces showed higher levels, particularly in
recent years. The data also show a negative
association with the wealth index (r: 0.6; P: 0.032).

The Burden of Refractive Errors (Per 100,000)

Refractive errors contributed to 441.41 and 348.38
YLDs in men and women, respectively. The YLDs in
2018 in age and gender groups are summarized in
Table 3. The highest number of years of life lost was
seen in women over 85 years with 499.55 YLDs.

Nationally, the age-standardized YLDs rates of
refractive errors reveal an increasing trend of 28.9%
during this period [Figure 5].

DISCUSSION

This study represented a national first effort to
collect data from multiple sources at the individual

level to estimate the prevalence of refractive
errors over an extended period in Iran. It revealed
that a total of 13 million Iranian citizens are
affected by refractive errors. Similar to the global
patterns, advancing age, female gender, and
lower socioeconomic status were identified as risk
factors.[6, 11]

Refractive error prevalence carries an inherent
“age-related” feature; where it was determined
through the study that the possibility of developing
some kind of refractive error increases with age.
While in viewing the data of the decade one age
category a prevalence of under 10% refractive
error was noticed in 2018 throughout the country,
it increased to approximately 17% in the ninth
decade age category. Several phenomena may
explain this, juvenile myopia generally commences
before 6 years of age and continues to occur
and increase in severity up to 16 years or
more. In later years, keratoconus incidence in the
second and third decades contributes modestly to
increased refractive error. In later years especially
where people approach their 40s, presbyopia
and latent hyperopia may develop and manifest
in patients. The incidence of the presbyopia

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Refractive Errors in Iran; Mohammadi et al

Figure 2. Refractive errors prevalence at national level by sex and age group from 1990 to 2018.

and hyperopia conditions fluctuates to a higher
level during the middle aged category of the
population which is clearly reflected in the study
diagrams. Decoupling of lenticular astigmatism
(from corneal astigmatism) and emergence of
nuclear sclerosis may also contribute to the age-
related changes. The latter should explain the

trend in the >70 years (index myopia) category.
Diabetes mellitus is another source for incidental
refractive error in the middle to older ages as it
may induce refractive index shifts in the crystalline
lens.

The increasing trend in the prevalence of
refractive errors is consistent with other reports in

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Refractive Errors in Iran; Mohammadi et al

Figure 3. Trend of refractive errors prevalence at national level by sex and age groups from 1990 to 2018.

the world and region.[6, 11] However, our prevalence
estimates in Iran are lower as compared with
corresponding figures in the region. In addition,
relative to global estimates, refractive errors
prevalence estimated in Iran reflects a more
positive outcome.[11]

It is known that the world is experiencing a
pandemic of refractive errors.[12] In 2010, about 28%
of the world’s population was affected by short-
sightedness. This is predicted to rise to 34% by
2020 and then to approximately 50% by 2050.[13]
The aging population has many more people
with refractive errors (demographic transition).
Presbyopia and manifest hyperopia are the two
major contributors in older ages. The myopia
epidemic, on the other hand, may be caused
by epidemiologic transition factors; daily habits
that encompass the use of digital, sight-intensive,
and night and near vision-oriented activities may
affect the state of vision in molecularly vulnerable
people where they may become more prone to
myopia. Many ecological studies suggested a

correlation between indoor and nightlife activities
with the prevalence of myopia and its related
severity.[14–16] In addition, lifestyle changes
involving the execution of more intense visual
tasks such as using a computer or a smartphone
led to glasses being prescribed even for patients
diagnosed with minimal myopia. An increase in
the prevalence of refractive errors in Iran may be
attributed to lifestyle changes due to technological
advancements and behavioral factors relating to
specific age groups. The initial and progressive
pace of juvenile myopia in recent years were both
attributed to near-work activities and digital life.
Cohort studies have proven the axial growth in the
eyes in the global population.[17] The COVID-19
pandemic due to the lifestyle restrictions has
exacerbated the use of digital apparatus and
the need for indoor entertainment where now
there are frequent studies revealing more myopia
incidence and progression.[18] However, it should
also be mentioned that based on particular studies
this phenomenon seems to not be consistent

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Refractive Errors in Iran; Mohammadi et al

Figure 4. Geographic distribution of age-standardized prevalence in different years (a: Females, b: Males).

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Refractive Errors in Iran; Mohammadi et al

Figure 5. Age-adjusted DALYs (YLDs) per 100,000 at national level by sex from 1990 to 2018.

among all races, Asians being the most sensitive
while Africans seem unsusceptible.[11] The age-
standardized prevalence estimates of refractive
error in our study from the years 1990 to 2018
translate into >100% rise which mostly follows the
trend of juvenile myopia.[13, 19]

The authors of the current study would like
to indicate the challenge experienced in the
conducting the assignment of the disability
index for VI to refractive errors. Refractive errors
are highly heterogeneous and their severity is
divergent. Although some refractive errors are
essentially a variation of normality, others are so
disabling that without correction they constitute
clear handicap and “functional” blindness. As a
result of our analysis, we recommend that the
approach to addressing the global burden of this
disease needs major improvement in this regard
including cost estimation and social attribution of
the disability.

DALYs attributed to refractive disorders
increased 52% worldwide as compared to 1990
and increased by 82% in Iran.[9] Our study showed
a higher prevalence and DALY as compared to
Institute for Health Metrics and Evaluation (IHME).
This might be due to the nature of IHME estimation
and imputation of missing data by neighboring data
because of security and insufficient evidences from
Iran in prior years. Imputation from neighboring
countries’ evidence may constitute another source
of disparity.

In our study, it was revealed that the prevalence
of refractive errors in central provinces which
generally possess better socioeconomic status
(better education and more indoor occupations)
is higher than those of the marginal provinces.
Prior studies on the prevalence of refractive errors
have already confirmed higher myopia prevalence
in environments that possess more advanced
levels of education, income, and professional
occupations.[20] Modern careers tend to be

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Refractive Errors in Iran; Mohammadi et al

associated with sight-intensive work. In several
epidemiological studies[21–26] as a consequence
of the mentioned trends, increased attention is
now directed to addressing unmet refractive error
correction and control of myopia conditions.

In summary, the challenging data extraction
process in our current study proved useful in
determining the prevalence of the refractive errors
phenomena in Iran. This study has provided the
required evidence in determining the associated
burden (economic and social) of these conditions
and the basis for the recommendation to the
respective health authorities about the necessity
to address these issues. Over a span of 28
years, the prevalence of refractive errors has
increased significantly in Iran by 16.32% (the
age-standardized prevalence growth was 31.30%
in females and 24.32% in males from the years
1990 to 2018). Prevalence in females was 3.5%
higher than that of males. The prevalence rates
increased in older ages. Significant geographical
heterogeneity was observed where border
provinces possessed a lower prevalence of
refractive errors. The age-standardized YLDs rates
of refractive errors showed an increasing trend
of 28.9% during the period. Lifestyle changes
and behavioral adaptions due to technological
advancements and other social restrictions
continues to perpetuate the onslaught of myopia
and other VI issues globally, which further
emphasizes the need to manage diagnoses,
their prevention and treatment of these related
issues.

Financial Support and Sponsorship

This work was partially supported by the Tehran
University of Medical Sciences under Grant number
24423.

Conflicts of Interest

There are no conflicts of interest.

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