Original Article

Rapid Assessment of Avoidable Visual Impairment in
Two Coastal Districts of Eastern India for Determining

Effective Coverage: A Cross-Sectional Study

Amit Bhardwaj1, MSW; Praveen Vashist1, MD; Suraj Singh Senjam1, MD; Vivek Gupta1, MD; Noopur Gupta2, MD
Souvik Manna1, MD

1Community Ophthalmology, Dr. Rajendra Prasad Centre for Ophthalmic Sciences, All India Institute of Medical Sciences, New
Delhi, India

2Department of Ophthalmology, Dr. Rajendra Prasad Centre for Ophthalmic Sciences, All India Institute of Medical Sciences,
New Delhi, India

ORCID:
Amit Bhardwaj: https://orcid.org/0000-0002-7689-072X
Souvik Manna: https://orcid.org/0000-0002-8870-8542

Abstract
Purpose: To measure the prevalence and causes of visual impairment (VI) among the 40+ age
population in two coastal districts of India and to determine the levels of effective cataract surgical
coverage (eCSC) and effective refractive error coverage (eREC) in the study population.
Methods: A cross-sectional study was done on 4200 people chosen using cluster sampling in
two coastal districts of Odisha, an eastern state in India. A team consisting of trained optometrists
and social workers conducted the ocular examination which included unaided, pinhole, and aided
visual acuity assessments followed by examination of the anterior segment and lens.
Results: Overall, 3745 (89.2%) participants were examined from 60 study clusters, 30 in each
district. Among those examined, 1677 (44.8%) were men, 2554 (68.2%) were educated and
number? (17.8%) used distance spectacles during the survey. The prevalence of VI adjusted for
age and gender was 12.77% (95% CI 11.85–13.69%). Multiple logistic regression showed that older
age (OR 3.1; 95% CI 2.0–4.7) and urban residence (OR 1.2; 95% CI 1.0–1.6) were associated with
VI. Being educated (OR 0.4; 95% CI 0.3–0.6) and using glasses (OR 0.3; 95% CI 0.5–0.2) were
found to provide protection; therefore, resulting in lower instances of VI. Cataract (62.7%) and
uncorrected refractive errors (27.1%) were the two main causes of VI. The eCSC was 35.1%, the
eREC for distance was 40.0%, and the eREC for near was 35.7%.
Conclusion: VI remains a challenge in Odisha, as the prevalence is high and the surgical coverage
is poor. Nearly 90% of VI is avoidable indicating that targeted interventions are required to
address this problem.

Keywords: Blindness; Cataract; Refractive Error

J Ophthalmic Vis Res 2023; 18 (2): 182–191

Correspondence to:

Souvik Manna, MD. Community Ophthalmology, Dr.
Rajendra Prasad Centre for Ophthalmic Sciences, AIIMS,
New Delhi 110029, India.
Email: souvikmanna311@yahoo.com
Received: 06-01-2022 Accepted: 06-11-2022

Access this article online

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

DOI: 10.18502/jovr.v18i2.13185

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: Bhardwaj A, Vashist P, Senjam SS,
Gupta V, Gupta N, Manna S. Rapid Assessment of Avoidable
Visual Impairment in Two Coastal Districts of Eastern India
for Determining Effective Coverage: A Cross-Sectional Study. J
Ophthalmic Vis Res 2023;18:182–191.

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RAAB in India; Bhardwaj et al

INTRODUCTION

Vision impairment (VI), including blindness, is
an alarming global public health issue with a
disproportionately larger prevalence in low- and
middle-income countries (LMICs). As per the recent
WHO estimates, globally, approximately 2.2 billion
people have near and distance VI of which
almost 50% need either prevention or treatment
measures.[1] In October 2019, WHO launched the
first World Report on Vision to draw attention to the
increasing need for eye care.[2]

India has the second largest population
in the world with nearly 4.8 million of the
population suffering from blindness and 74 million
experiencing VI.[3] Cataract and uncorrected
refractive errors (URE) are the two commonest
reasons for VI in India.[3] In a country like
India, where the population is diverse and
heterogeneous, it is imperative to have regionally
representative, valid, and robust public health data
so that appropriate public health strategies can
be planned at the local level. Rapid assessment
of VI (RAVI) surveys are less expensive and less
time-consuming as compared to detailed and
resource-intensive epidemiological studies. For
tracking progress at country and regional levels,
RAVI surveys are needed at periodic intervals
to assess baseline status and progress toward
targets. Effective refractive error coverage (eREC)
and effective cataract surgical coverage (eCSC)
are also tracer indicators that gauge the eye care
scenario in a country.[4] The global targets include
a 30% increase in eCSC and a 40% increase in
eREC, by 2030.[4, 5]

RAVI surveys have been completed in many
areas of southern, western, central, and northern
India; however, relevant data on the magnitude
of the VI burden, especially in the remote
underprivileged population from Eastern India is
missing. A RAVI study was conducted in the
population aged 40+ in two coastal districts
of Odisha with the purpose of assessing the
magnitude and causes of VI in the two districts and
to determine the levels of eCSC and eREC in the
study population.

METHODS

Two coastal districts were selected in the state
of Odisha: Ganjam which is predominantly rural

and Khordha which is predominantly urban.[6,
7] The sample size of 2100 per district was
selected using a prevalence of 15% VI in the
40+ age group, a relative precision of 15%,
confidence interval (CI) of 95%, 1.75 design
effect (cluster size 70), and a nonresponse rate
of 20%.[8] The study protocol was reviewed
and approved by Institute Ethics Committee of
All India Institute of Medical Sciences, New
Delhi, India under the approval number IEC-
562/02.12.2016,RP/8/2016, OP-10/06.03.2020. In
addition, the protocol of the study complied with
the guidelines for human studies and the World
Medical Association Declaration of Helsinki.

Sampling was done in multiple stages using
cluster random techniques. In urban regions of
India, the district is divided into municipal wards,
whereas in the rural areas the administrative
divisions are villages. A list of all the municipal
wards and villages in the district was obtained
from the Census Office, India. In the first stage
of sampling, all the subdivisions were selected,
and within each subdivision, a list of 30 PSUs
(primary sampling units) comprising of urban
wards and villages was chosen based on the
probability proportionate to size (PPS) techniques.
The PSUs had a maximum population size of
2000. If a village or ward had a population greater
than 2000, it was divided into smaller PSUs of
size 2000, each of which was independently
entered into the sampling frame. Within each PSU,
the selection of households involved a compact
segment sampling technique in which the selected
PSU was divided into multiple segments of 300–
500 people and one such segment was chosen
randomly by a draw of chits. In the selected
segment, the survey proceeded from one corner
and all contiguous houses were visited until 70
people were enumerated. By covering a total of 30
such segments, the target sample of 2100 in each
district was achieved.

The sample population comprised of all those
who were aged 40+ and were habitual residents
of the selected districts (living in the area for at
least six months). Two teams were dispatched
to visit 30 clusters in each district. Before the
commencement of the study, a two-day training
was given to the team regarding standard study
protocols, method of cluster selection and coding,
enumeration methods, clinical examination, and
barrier information. Inter-observer variations
among the optometrists for clinical diagnosis,

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RAAB in India; Bhardwaj et al

distant and near vision examinations were checked
in the clinic and community. The inter-observer
agreement was good (kappa > 0.8) for all survey
procedures among optometrists as each team
consisted of members from local areas who were
helpful in overcoming any language or cultural
barriers.

The survey was conducted using the standard
RAVI questionnaire. It captured data on the
avoidable reasons for blindness and VI in people
aged 40+. This questionnaire was modified
from the standard RAAB (Rapid Assessment of
Avoidable Blindness), and had extra sections for
near vision, use of glasses, and unaided visual
acuity.

Presenting binocular near vision was measured
using a simplified “E” chart having N60 and
N6 optotypes with five letters in one line. The
procedure was performed at a distance of 40
cm, which was ensured by using a headband
attached to a rope 40 cm in length. Near vision
was calculated first using the N60 optotype and
then using the N6 optotype. The criterion for
determining the category of vision at a certain level
was selection of four correct letters out of five from
the simplified “E” chart.

Distance visual acuity (VA) was tested utilizing
tumbling “E” charts both with and without
spectacles. VA was examined with “E” Snellen
optotypes of different sizes for VA of 6/12, 6/18,
and 6/60 at 6 m. The criterion for measuring vision
at any of the levels was the selection of four
correct answers consecutively, or four correct out
of five tumbles. If the person wore spectacles for
distance vision, the pinhole was placed in front of
the spectacles. The lens assessment was done in
an undilated pupil with a pen torch [Figure 1].

The primary outcome measure was VI, which
was defined as presenting visual acuity (PVA) <
6/12 according to the International Classification of
Diseases (ICD-10 as revised by WHO)).[9]

The main cause of PVA < 6/12 was separately
ascertained for each eye, and the more avoidable
cause was taken as the diagnosis for each
person. In cases with multiple causes for VI, the
disease that was more preventable/amenable to
treatment to achieve VA ≥ 6/12 was considered
as the principal cause. The data entry was
done in specially designed Epi-data 3.1-based
database with all checks in place for validation
and data consistency. Double data entry was

done to minimize errors and data cleaning
was done to remove all inconsistent findings
and outliers. Data analysis was done using
the Stata 15.1 software package (Stata Corp.,
College Station, Texas, USA). Age and gender
disaggregated prevalence of VI along with 95%
CI were calculated. Univariate and multivariate
analyses were done to find factors associated with
VI. The sample prevalence (unstandardized) was
directly standardized using the age-sex distribution
of the combined population of the two districts,
using Stata software. Association of VI with age,
gender, education, and locality was checked by
using multiple logistic regression analysis.

RESULTS

Overall, 4200 individuals aged 40+ were
enumerated, of whom 3745 (89.2%) were
examined. The number of males was 1677 (44.8%)
and that of females was 2068 (55.2%). The
response rate was better among females (91.6%)
than males (86.4%), as far as clinical examination
was concerned. Out of the 455 not examined,
441 were either not available or were unable
to communicate and 14 refused to undergo
examination. There was no significant difference
between the socio-demographic profile of the
sample and target population (Odisha state) (P =
0.57) [Table 1].

The age and sex standardized prevalence
of VI including blindness was 12.77% (95% C.I.
11.85–13.69). Although the prevalence of VI
(including blindness) was higher in males (16.33%,
95% CI: 14.56–18.11) than females (14.74%, 95%
CI:13.21–16.27), the difference was not statistically
significant (P = 0.181). The standardized prevalence
of moderate VI (MVI: presenting visual acuity
<6/18 to 6/60 in the better eye) and severe VI
(SVI: presenting visual acuity <6/60 to 3/60 in
the better eye) in study subjects was 4.84% and
1.13%, respectively. The blindness prevalence in
the study population was 1.14% (95% C.I. 0.84–1.45)
[Table 2].

The prevalence of VI and URE exhibited a rising
trend with age. Maximum VI (including blindness)
was seen in females above the age of 80 years
(68.3%) [Figure 2 & Table 3]. Out of the 3745
study participants, 343 (9.2%) had URE. Another
155 (4.1%) had corrected refractive errors (RE) giving
a total of 498 individuals with any form of RE (13.3%).

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RAAB in India; Bhardwaj et al

Table 1. Socio-demographic profile of 40+ sample population in Khordha and Ganjam districts compared with Odisha state.

Variable Sample Odisha

Male (%) Female (%) Total (%) Male (%) Female (%) Total (%)

Age groups (yr)

40–49 449 (26.7) 705 (34.1) 1154 (30.8) 26,00,286 (41.3) 24,25,218 (40.1) 50,25,504 (40.7)

50–59 438 (26.1) 550 (26.6) 988 (26.4) 17,01,815 (27.0) 16,29,717 (26.9) 33,31,532 (26.9)

60–69 440 (26.2) 510 (24.7) 950 (25.4) 12,25,484 (19.5) 12,28,102 (20.3) 24,53,586 (19.9)

70–79 260 (15.5) 240 (11.6) 500 (13.4) 5,63,929 (8.9) 5,68,941 (9.4) 11,32,870 (9.2)

≥80 90 (5.4) 63 (3.0) 153 (4.1) 2,04,857 (3.3) 1,93,135 (3.2) 3,97,992 (3.2)

Total 1677 2068 3745 62,96,371 60,45,113 1,23,41,484

Education

Illiterate 274 (16.3) 917 (44.3) 1191 (31.8) 18,76,376 (29.8) 36,96,032 (61.2) 55,72,408 (45.2)

Up to 4𝑡ℎ 380 (22.7) 548 (26.5) 928 (24.8) 12,06,268 (19.2) 8,34,639 (13.8) 20,40,907 (16.6)

5𝑡ℎ–9𝑡ℎ pass 419 (24.9) 351 (16.9) 770 (20.6) 18,98,155 (30.2) 10,83,901 (17.9) 29,82,056 (24.2)

>10𝑡ℎ pass 604 (36.0) 252 (12.2) 856 (22.9) 13,06,345 (20.8) 4,24,874 (7.0) 17,31,219 (14.0)

Total 1677 2068 3745 62,87,144 60,39,446 1,23,26,590

Table 2. Prevalence of visual impairment and blindness among 40+ population in Khordha and Ganjam districts of Odisha.

Combined % (95% CI) Unstandardized
prevalence (%)

Standardized
prevalence (%)

Definition Male (N = 1677) Female (N = 2068) Total

Blind PVA < 3/60 in BE* 27 1.61 (1.00–2.21) 27 1.30 (0.81–1.79) 54 1.44 (1.06–1.95) 1.14 (0.84–1.45)

SVI PVA < 6/60 – 3/60 in BE* 23 1.37 (0.81–1.93) 30 1.45 (0.93–1.96) 53 1.41 (1.15–1.73) 1.13 (0.83–1.43)

MVI PVA < 6/18 – 6/60 in BE* 107 6.38 (5.20–7.55) 113 5.46 (4.48–6.44) 220 5.87 (5.10–6.75) 4.84 (4.22–5.46)

Mild VI PVA < 6/12 – 6/18 in BE* 117 6.97 (5.75–8.19) 135 6.52 (5.46–7.59) 252 6.72 (5.74–7.86) 5.64 (4.96–6.33)

VI PVA< 6/12 in BE* 274 16.33 (14.56–18.11) 305 14.74 (13.21–16.27) 579 15.46 (14.06–16.96) 12.77 (11.85–13.69)

*PVA, presenting visual acuity; BE, better eye with available correction or with best correction or pinhole (BCVA or PINVA); SVI, severe visual impairment; mvi,
moderate visual impairment; VI, visual impairment; CI, confidence interval.

Table 3. Age-wise prevalence of visual impairment and uncorrected refractive error among 40+ population in Khordha and
Ganjam districts of Odisha.

Age group (yr) Prevalence of VI (PVA < 6/12 in better eye) (%) Prevalence of
uncorrected refractive
error (%) with 95% CI

Male Prev (%) Female Prev (%) Total Prev (%) Odds ratio P-value

40–49 11 2.4 20 2.8 31 2.7 1 0.000 3.1 (2.19–4.29)

50–59 44 10.0 37 6.7 81 8.2 3.28 (2.15–5.00) 0.000 7.7 (6.11–9.53)

60–69 83 18.9 106 20.8 189 19.9 9.06 (6.13–13.38) 0.000 14.4 (12.25–16.82)

70–79 82 31.5 99 41.2 181 36.2 20.38 (13.65–30.42) 0.000 14.2 (11.26–17.57)

80+ 54 60.0 43 68.3 97 63.4 62.75 (38.62–101.95) 0.000 15.0 (9.77–21.70)

Total 274 16.3 305 14.7 579 15.5 9.2 (8.25–10.13)

*Prev, prevalence; VI, visual impairment; CI, confidence interval; PVA, presenting visual acuity

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RAAB in India; Bhardwaj et al

 

Figure 1. Examination protocol of the RAAVI Study in Khordha and Ganjam districts of Odisha.

 

Figure 2. Age-wise prevalence of visual impairment among 40+ population in Khordha and Ganjam districts of Odisha.

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RAAB in India; Bhardwaj et al

Table 4. Cataract surgical coverage and effective coverage among 40+ population in Khordha and Ganjam districts of Odisha.

CSC (persons) Male (%) Female (%) Total (%)

PinVA < 3/60 88.29 88.11 88.19
PinVA < 6/60 84.30 79.88 81.72
PinVA < 6/18 66.67 59.83 62.74
PinVA < 6/12 49.08 46.04 47.40
eCSC 33.70 36.09 35.02

eREC for distance 38.10 41.91 40.08

eREC for near 40.01 32.83 35.65

*CSC, cataract surgical coverage; PinVA, pinhole visual acuity; eCSC, effective cataract surgical coverage; eERC, effective
refractive error coverage

Table 5. Multiple logistic regression analysis for finding determinants of visual impairment in Khordha and Ganjam districts of
Odisha.

Variable Odds ratio 95% Confidence Interval z-value P-value

Age groups (yr)

40–49 1

50–59 3.07 2.00–4.69 5.16 <0.001
60–69 7.71 5.16–11.51 9.97 <0.001
70–79 16.48 10.86–25.03 13.15 <0.001
≥80 51.19 30.61–85.60 15.00 <0.001
Gender

Male 1

Female 0.79 0.64–0.99 –1.98 0.048

Locality

Rural 1

Urban 1.26 1.02–1.57 2.18 0.03

Education

Illiterate 1

Up to 4𝑡ℎ 0.62 0.48–0.81 –3.53 <0.001
5𝑡ℎ–9𝑡ℎ pass 0.62 0.45–0.84 –3.09 0.002

>10𝑡ℎ pass 0.39 0.27–0.56 –5.04 <0.001
Use of distance glasses

No 1

Yes 0.31 0.46–0.21 –5.84 <0.001

*RAAVI, rapid assessment of avoidable visual impairment; VA, visual acuity; VI, visual impairment; CO, corneal opacity.

Prevalence of URE among males was 9.5% (95%
CI: 8.12–10.99) and among females was 8.9% (95%
CI: 7.71–10.21); the difference was not significant (P
= 0.538) [Table 3]. The prevalence of VI in rural
participants was 16%, which was higher than that of

urban participants (14.6%). Cataract was the single
most important cause of blindness (72.2%) and VI
(62.7%) in this region [Figure 3].

A total of 536 cataract surgeries were reported
among people from the study population. More

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RAAB in India; Bhardwaj et al

 

Figure 3. Causes of blindness and visual impairment (PVA < 6/12 in better eye) among 40+ population in Khordha and Ganjam
districts of Odisha.

females reported surgery (288) as compared to
males (248). The proportion of surgeries with an
intraocular lens (IOL) implant was 94.0%. Out of the
377 persons (536 eyes) who underwent cataract
surgery, 159 were bilaterally operated while 218
had undergone unilateral cataract surgery. It was
observed that the majority of unilateral and bilateral
cataract surgeries were performed in people aged
60 years and above.

When visual outcomes were assessed in the
operated eye, it was seen that 355 eyes (66.2%)
had very good outcomes (≥6/12), 54 (10.1%) had
good outcomes (<6/12 to 6/18), 57 (10.6%) had
borderline outcomes (<6/18 to 6/60), and 70 (13.1%)
had poor outcomes (<6/60). Poor outcomes were
caused by operative complications in 50 (71.4%)
eyes, ocular comorbidity in 18 (25.7%), and RE in
2 (2.9%) eyes. Nearly half of the surgeries, that is,
253 (47.2%) were performed in the last five years.
The visual outcomes were better among surgeries
reported in the last five years as compared to
surgeries performed before that, and the difference
was statistically significant (P = 0.014). The CSC
(Cataract Surgical Coverage) in two districts of
Odisha for 40+ population was 47.4% by 6/12 cut-
off and 88.19% for pinhole vision <3/60. The eCSC
was 35.1%, eREC for distance was 40.0%, and eREC
for near was 35.7% for the same population [Table
4].

Out of the 536 cataract surgeries, 300 (55.9%)
took place in non-governmental organizations
(NGO)/private sector as compared to 236 (44.0%) in
the public sector, and 287 (53.5%) of the surgeries
were paid irrespective of the place of surgery.

The usage of distance glasses was reported
by only 518 (13.8%) study participants (males 265
[15.8%] and females 253 [12.2%]). Similarly, near
glasses were being used by only 666 (17.8%)

participants (males 364 [21.7%] and females 302
[14.6%]). Out of a total of 735 participants who
received refraction services, 505 (68.7%) had their
last refraction more than two years back. Most
refractions, that is, 557 (75.8%) took place in
the NGO/private sector (males 74.7% and females
77.3%). The majority (89.7%) of participants reported
having to pay for their glasses irrespective of place
of refraction.

Barriers to not wearing glasses among those
who were identified as having URE/presbyopia or
uncorrected aphakia were assessed. The most
common barriers were need not felt (57.5%),
financial constraints (13.8%), uncomfortable
glasses (8.2%), various local reasons like no
one to accompany them, and other personal
preoccupations (11.0%) in addition to lack of
awareness (5.0%).

Multiple logistic regression was done to find
determinants of VI in the study population. The
odds of VI increased significantly in higher ages
and were greater among the urban population (OR
1.2; 95% CI 1.0–1.6). Being educated (OR 0.4; 95%
CI 0.3–0.6) and use of glasses (OR 0.3; 95% CI 0.5–
0.2) were protective. All these risk factors are well-
established as associated with VI [Table 5].

DISCUSSION

The current study utilized the novel RAVI
methodology to determine the prevalence and
causes of VI in two districts of Odisha, India.
According to the National Blindness Survey
(NBS), the prevalence of blindness in the 50+
age population in India was 1.99% and cataract
(66.2%) was the most important cause of blindness
followed by corneal opacity (8.2%).[10]

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RAAB in India; Bhardwaj et al

In the current study, the age-sex-adjusted
prevalence of blindness was 1.14%; MVI was 4.84%,
and VI was 12.77% among the 40+ age population
in Odisha. The NBS was conducted among the 50+
age population in one district of Odisha (Nayagarh)
and the prevalence of blindness and MVI reported
were 1.77% and 13.4%, respectively.[3, 10] Although
the prevalence figures in the current study are
lower as compared to NBS, it might be due to the
lower age group (40+) and other differences among
the survey participants. Despite this, the VI due to
cataract and RE needs to be managed promptly
as the study clearly highlights poor coverage for
cataract and RE services in Odisha.

The study demonstrated that the risk of VI
increased significantly with age, which is being
corroborated by numerous studies done in both
South and North India.[8, 11, 12] A previous study
on blindness had reported that females were at 1.41
times higher risk of blindness in urban areas and
1.51 times in rural areas, compared to their male
counterparts.[13] However, no significant difference
was observed by gender in the current study.
Cataract is a major cause of VI and blindness
in the current study. These findings are similar
to the findings from South India.[14] Cataract and
REs combined contributed to >90% of VI both of
which are amenable to treatment as compared
to the other causes. Cataract surgery has been
identified as surgical intervention that costs <$200
per disability-adjusted life years averted.[15]

The CSC of Odisha for the 40+ age population
was determined as 47.4%. In the NBS, a CSC
(persons) of 50.0% at a VA cut-off of 6/18 was
reported in Nayagarh, Odisha.[3] Another RAAB
study by SightSavers in the Kalahandi district
of Odisha reported a CSC of 45.5%.[16] In both
studies, males had higher CSC than females,
similar to the findings of the current study. A
study from rural Northern India reported higher
CSC in females than males, with CSC of 43.2%
at 6/60 cut-off.[17] Lower CSC and thereby higher
prevalence of cataract and VI was observed in
rural areas in many countries.[18, 19] The eCSC
determined in the current study was 35.02%
and it was higher in females as compared to
males. Very few studies have reported eCSC from
the Indian subcontinent. A preliminary analysis
(unpublished) of 47 population-based surveys from
11 countries revealed a significant range in eCSC
between countries, from 2.8% to 88.5%.[4] Data
from repeated population-based surveys within

four LMICs revealed an average annual percentage
point increase in eCSC of 1.1% (range = 0.8% - 1.4%).
In addition, gender inequities in eCSC have been
reported: it is estimated that globally, women were
1.21 times more susceptible to having cataract VI as
compared to men, and the mean level of inequality
amongst women in eCSC is 4.6%.[20, 21]

In order to know the exact number of people
with VI due to RE, uncorrected visual acuity needs
to be measured, that is, without spectacles or
contact lenses.[4] The current study employed this
methodology, and the prevalence found was 9.2%.
In the current study, the eREC for distance was
40.1%, while for the near vision it was 35.6%. Rates
of eREC for near is lower than 20% in sub-Saharan
Africa, while the same figures in North America are
reported to be higher than 90%.[22]

The impact of REs is manifold and includes loss
of livelihood, schooling, and financial resources.[23]
Estimates of global economic burden of distant
VI due to URE is huge (US$ 202 billion).[24]
Globally, nearly 800 million people suffer from
distance VI (i.e., myopia and hypermetropia) or
near VI (i.e., presbyopia) who need just a pair
of spectacles, while another 100 million persons
have moderate-to-severe distance VI or blindness
that is amenable by cataract surgery.[25] The
sustainability of programs for treatment of cataract
and RE need huge expenditure in terms of
equipment, manpower, and spectacles. Hence,
sale of customized spectacles can also be explored
as an alternative source of revenue by hospitals
that want to scale-up their cataract surgical and
refractive services, as envisioned by the Vision
2020 Right to Sight Initiative. The Government of
India launched the National Program for Control
of Blindness and Visual Impairment (NPCB&VI) in
1976 and it currently has the provision of free
services for cataract and other subspecialties;
however, with the increase in the number of
RE, there is a need to introduce a provision of
subsidized/free spectacles also into the program to
alleviate some of the additional costs ensued.[26]
Generation of demand for services and addressing
various barriers for accessing those services is
necessary to scale-up the provision of cataract
surgical and refractive error services to the
population.

The WHO has given targets for achieving
universal eye health coverage (UHC) by 2030, that
is, a 30% point increase in eCSC and 40% increase
in eREC from baseline.[4] This means that Odisha

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RAAB in India; Bhardwaj et al

needs to achieve an eCSC and eREC of 65.0%
and 80.1%, respectively, by 2030, from the baseline
figures reported in the current study. This can be
possible only if the management of VI is prioritized
in Odisha in a systematic way. Shortage of trained
human resources and resource constraints are
always bottlenecks for such ambitious targets. The
National Program for Control of Blindness and
Visual Impairment (NPCBVI) can provide effective
RE and cataract surgical services free of cost or at
subsidized rates, which can be incorporated in the
health insurance packages available to the people.

The current RAAVI study has a few limitations.
First, it is not adequately powered to determine
the prevalence of blindness. The sample size was
deduced based on the prevalence of VI in previous
studies and would only provide accurate estimation
of the prevalence of VI. Second, the findings of
the study cannot be extrapolated to other districts
of Odisha, and separate surveys need to be
conducted in each of the districts to accurately
gauge the magnitude of the problem in the entire
state. The burden of VI needs prompt attention in
Odisha, majority of which is caused by cataract and
RE. The findings suggest that the absolute number
of people susceptible to avoidable blindness is
enormous, and free or subsidized cataract and RE
services is the need of the hour. It is hoped that this
baseline study from Odisha will be instrumental in
planning eye care services in the state in the future.
Some of the major recommendations from the
current study include, graded scaling up of cataract
and RE services over the next decade to achieve
UHC targets by 2030, reducing cost of services by
incorporating services in insurance packages and
prioritizing vulnerable individuals like the elderly,
illiterate, and urban poor. RAAVI studies need to be
conducted in all the districts of Odisha, and district-
specific interventions need to be planned.

Ethical Considerations

The study protocol was reviewed and approved
by Institute Ethics Committee of All India Institute
of Medical Sciences, New Delhi, India under the
approval number IEC-562/02.12.2016,RP/8/2016,
OP-10/06.03.2020. In addition, the protocol
of the study complied with the guidelines for
human studies and the World Medical Association
Declaration of Helsinki. A participant information
sheet (PIS) in local language Odia was given to
each participant. In case of illiterate or visually

impaired participants, the PIS was read out to the
participant. Written consent was obtained from
each participant before they were included in
the study. In case of illiterate persons, left thumb
impression was obtained. Participants who were
identified with treatable or curable conditions
were provided referral services to the nearest
secondary/tertiary eye hospital.

Acknowledgements

Dr. Sabyasachi Pattanayak from DHS Odisha and Lt.
Dr. Mihir Bal from ECOS Eye Hospital, Brahmapur.

Financial Support and Sponsorship

Financial support for this study was provided by
CBM, India. Consent for publication was taken
according to the ICMJE recommendations for
protection of research participants.

Conflicts of Interest

None.

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