untitled


Prevalence and risk factors for diabetic
retinopathy in rural India. Sankara
Nethralaya Diabetic Retinopathy
Epidemiology and Molecular Genetic
Study III (SN-DREAMS III), report no 2

Rajiv Raman,
1
Suganeswari Ganesan,

1
Swakshyar Saumya Pal,

1

Vaitheeswaran Kulothungan,
2
Tarun Sharma

1

To cite: Raman R,
Ganesan S, Pal SS, et al.
Prevalence and risk factors
for diabetic retinopathy in
rural India. Sankara
Nethralaya Diabetic
Retinopathy Epidemiology
and Molecular Genetic Study
III (SN-DREAMS III), report
no 2. BMJ Open Diabetes
Research and Care
2014;2:000005. doi:10.1136/
bmjdrc-2013-000005

PRÉCIS The prevalence of
DM and DR in a rural south
Indian population was 10.1%
and 10.3%, respectively. The
risk factors for DR were male
gender, longer duration of
diabetes, higher HbA1c,
insulin use, and higher
systolic BP.

Received 25 November 2013
Revised 22 April 2014
Accepted 29 April 2014

1Shri Bhagwan Mahavir
Vitreoretinal Services,
Sankara Nethralaya, Chennai,
Tamil Nadu, India
2Department of Preventive
Ophthalmology, Sankara
Nethralaya, Chennai,
Tamil Nadu, India

Correspondence to
Dr Tarun Sharma;
drtaruns@gmail.com

ABSTRACT
Objective: The study was aimed at estimating the
prevalence of type 2 diabetes mellitus and diabetic
retinopathy in a rural population of South India.
Design: A population-based cross-sectional study.
Participants: 13 079 participants were enumerated.
Methods: A multistage cluster sampling method was
used. All eligible participants underwent
comprehensive eye examination. The fundi of all
patients were photographed using 45°, four-field
stereoscopic digital photography, and an additional 30°
seven-field stereo digital pairs were taken for
participants with diabetic retinopathy. The diagnosis of
diabetic retinopathy was based on Klein’s classification.
Main outcome measures: Prevalence of diabetes
mellitus and diabetic retinopathy and associated risk
factors.
Results: The prevalence of diabetes in the rural Indian
population was 10.4% (95% CI 10.39% to 10.42%);
the prevalence of diabetic retinopathy, among patients
with diabetes mellitus, was 10.3% (95% CI 8.53% to
11.97%). Statistically significant variables, on
multivariate analysis, associated with increased risk of
diabetic retinopathy were: gender (men at greater risk;
OR 1.52; 95% CI 1.01 to 2.29), use of insulin (OR
3.59; 95% CI 1.41 to 9.14), longer duration of diabetes
(15 years; OR 6.01; 95% CI 2.63 to 13.75), systolic
hypertension (OR 2.14; 95% CI 1.20 to 3.82), and
participants with poor glycemic control (OR 3.37; 95%
CI 2.13 to 5.34).
Conclusions: Nearly 1 of 10 individuals in rural South
India, above the age of 40 years, showed evidence of
type 2 diabetes mellitus. Likewise, among participants
with diabetes, the prevalence of diabetic retinopathy
was around 10%; the strongest predictor being the
duration of diabetes.

The epidemic of diabetes mellitus (DM), in
particular type 2 DM, is assuming significant
proportions in developing countries, such as
India.1 2 The International Diabetes
Federation (IDF) has projected that the

number of people with diabetes in India
would rise from 65.1 million in 2013 to 109
million in 2035.3 DM, being a lifestyle disease,
is on the rise in urban areas; we reported that
the prevalence of DM in the population older
than 40 years, in urban India, was around 28%
(Sankara Nethralaya Diabetic Retinopathy
Epidemiology and Molecular Genetic Study
(SN-DREAMS) I, report 2).4 5 However, in a
study carried out in South India where the
population was hybrid, both rural and urban,
the prevalence of DM was around 11%.6 The
Indian Council of Medical Research-India
Diabetes (ICMR-INDIAB) Study, which was
carried out in three states (Tamil Nadu,
Maharashtra, and Jharkhand) and one union
territory (Chandigarh), reported a varied
prevalence of diabetes: 10.4% in Tamil Nadu,
8.4% in Maharashtra, 5.3% in Jharkhand, and
13.6% in Chandigarh.1 An epidemiological
study estimating the prevalence of DM and dia-
betic retinopathy (DR) in rural India is not
available; second, the changing lifestyle and
urbanization of rural culture are gradually
influencing the rural population as well.6 7

Therefore, the present study, SN-DREAMS III,
a population-based cross-sectional study, using
multistage random sampling was designed to
estimate the prevalence of DM and DR in
rural India and elucidate risk factors influen-
cing DR.

Key messages

▪ The prevalence of type 2 DM in the rural Indian
population: 10.4%.

▪ The prevalence of DR in this cohort: 10.3%.
▪ The prevalence of DR in newly diagnosed DM:

2.8%.
▪ The most significant variable associated with DR

was: Longer duration of DM, 15 years.

BMJ Open Diabetes Research and Care 2014;2:000005. doi:10.1136/bmjdrc-2013-000005 1

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PATIENTS AND METHODS
The study design and research methodology of
SN-DREAMS III are described in detail elsewhere.8 The
study was approved by the Institution Review Board, and
a written informed consent was obtained from the parti-
cipants according to the Declaration of Helsinki. The
details of the study were explained to the patient in the
local vernacular language; the translated local language
consent form was either signed (literate) or a thumb
impression obtained (illiterate).

Study areas and sample size calculations
The study was conducted in the rural areas of the dis-
trict Kanchipuram and district Thiruvallur, Tamil Nadu,
India (figure 1). A multistage cluster sampling method
was used. We randomly selected 26 villages, divided into
26 clusters, 13 clusters from each district, and a cluster
was defined as having a population of 1200–2000. The
estimated sample size was 11 760, assuming a 2% preva-
lence of DR based on estimation from previous
studies,9 10 keeping a design effect of 2 with a precision
of 80% and compliance of 80%.

Diagnosis of diabetes mellitus
The following definitions were used:
▸ Known diabetes: If they were using antidiabetic agents,

either oral or insulin or both, along with dietary
recommendations.

▸ Newly diagnosed DM: As a first step, all patients under-
went estimation of fasting blood glucose by the capil-
lary method (Accutrend α) in the field, and those

noted to have a reading of >100 mg/dL were invited
for oral glucose tolerance test (OGTT—by enzymatic
assay) in the mobile van; an OGTT value of
≥200 mg/dL was considered as newly diagnosed
diabetes.11

▸ Sight-threatening DR (STDR): STDR was defined as the
presence of severe non-proliferative DR (NPDR),
PDR, and clinically significant macular edema
(CSME).12

Evaluation of patients in a mobile van
All eligible patients were interviewed by trained bilingual
interviewers. All instruments were developed initially in
English and later translated into Tamil (the regional
spoken language), ensuring that the contents and the
meanings were preserved. A comprehensive eye examin-
ation was performed in a mobile van which was
equipped with an Early Treatment of Diabetic
Retinopathy Study (ETDRS) chart and a fundus camera
(Carl Zeiss) and other equipment (figure 2); this was
performed to ensure that a participant need not travel
to the city, as that would increase the compliance rate.
The fundi of all patients were photographed using 45°,
four-field stereoscopic digital photography; however, an
additional 30°, seven-field stereo digital pairs were taken
for those who showed any evidence of DR. The diagnosis
of DR was based on Klein’s classification (modified
ETDRS Scales).13 The clinical grading of digital photo-
graphs was performed by two independent observers
(experienced retinal specialists) in a masked fashion
(k=0.82).

Figure 1 Study areas.

2 BMJ Open Diabetes Research and Care 2014;2:000005. doi:10.1136/bmjdrc-2013-000005

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Step-by-step enumeration and enrollment
Figure 3 shows the step-by-step enrollment of the study
population. A house-to-house enumeration was com-
pleted for 13 079 participants, aged 40 years or above.
Participants with diabetes secondary to other conditions
(secondary diabetes) were excluded based on the
medical history of comorbid conditions. Likewise, those
on medications which could possibly alter the blood
glucose or cause changes in the retina mimicking DR
were also excluded. Of the 13 079 enumerated partici-
pants, 12 172 (93.1%) responded to the estimation of
first fasting glucose. Of these 12 172 participants, 2730
(22.4%) were considered to have DM, 1075 partici-
pants with known diabetes and 1655 participants with
fasting blood sugar ≥100 mg/dL. Of the 1655 partici-
pants, 1365 (82.5%) reported for OGTT; 335 (24.5%)
were then confirmed to have newly diagnosed DM. So,

1234 participants with DM (899, known; 335, newly
diagnosed) had their fundus photographed; 44 partici-
pants (34, known; 10, newly diagnosed) were excluded
as the fundus pictures were adjudged to be ungrad-
able. Thus, all together, 1190 participants (865,
known; 325, newly diagnosed) were analyzed in the
study.

Statistical analysis
Statistical analyses were performed using statistical soft-
ware (SPSS for Windows V.14.0; SPSS Science, Chicago,
Illinois, USA). The results were expressed as mean±SD if
the variables were continuous and as percentage if the
variables were categorical. The Student t test for compar-
ing continuous variables and the χ2 test to compare pro-
portions among groups were used. Newly diagnosed
participants with diabetes were given a value of 0 for

Figure 2 (A) A customized

mobile van for comprehensive

eye examination in rural areas.

(B) Inside the mobile van:

recording visual acuity using the

EDTRS chart.

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duration of diabetes. Univariate and multivariate logistic
regression analyses were performed to study the effect of
various risk factors using DR as a dependent variable.

RESULTS
Of the 2730 participants with DM, 1075 were known dia-
betes, and 1655 were provisional diabetes (figure 3);
these subjects were invited for eye evaluation and OGTT,
respectively. Of the 1075 participants with known dia-
betes, 899 responded to the eye evaluation, and of the
1655 participants with provisional diabetes, 1365
responded to OGTT. Thus, the data included 2264
responders and 466 non-responders; table 1 compares
the data between responders and non-responders with
regard to mean age, gender, and diabetes status. No stat-
istically significant differences were observed.
The age-adjusted and gender-adjusted prevalence of

DM in rural India was 10.4% (95% CI 10.39% to
10.42%; table 2). The prevalence was higher in those
between the age group of 50–59 years and no gender

difference was observed. The prevalence of any DR was
10.3% (95% CI 8.53% to 11.97%; table 3). The preva-
lence of any DR was higher among participants with
known diabetes (13.1% vs 2.8%; p<0.0001), participants
with age between 50 and 69 years (25.4% vs 6.2%;
p=0.007), male gender (12.8% vs 8.1%; p=0.008),

Figure 3 Flow chart showing a step-by-step enrollment of the study population.

Table 1 Comparison of responders and non-responders

in the study population

Responders Non-responders

Variable (n=2264) (n=466) p Value

Mean age,

years

53.03±9.77 53.28±10.97 0.623

Male, n (%) 953 (42.1) 201 (43.1) 0.717

Female,

n (%)

1311 (57.9) 265 (56.9)

KD, n (%) 899 (39.7) 176 (37.8) 0.466

NDD, n (%) 1365 (60.3) 290 (62.2)

KD, known diabetes; NDD, newly diagnosed diabetes.

4 BMJ Open Diabetes Research and Care 2014;2:000005. doi:10.1136/bmjdrc-2013-000005

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duration of DM of more than 15 years (37.1% vs 6.3%;
p<0001), higher glycosylated hemoglobin (HbA1c; 15.4
vs 5.1%; p<0.0001), use of insulin (44% vs 9.5%;
p<0.0001), systolic blood pressure of >140 mm Hg
(19.8% vs 8.6%; p<0.0001), and diastolic blood pressure
of >90 mm Hg (15.5% vs 8.8%; p=0.002). The preva-
lence of STDR was 3.8% (95% CI 2.70% to 4.86%;
table 3). The prevalence of STDR was higher among

participants with known diabetes (5.0% vs 0.6%;
p<0.0001), participants with age between 50 and
69 years (p=0.001), duration of DM of more than
15 years (p<0001), higher HbA1c (6.0% vs 1.5%;
p<0.0001), and use of insulin (28% vs 3.8%; p<0.0001).
Table 4 shows the univariate and multivariate regres-

sion analyses of factors related to any DR. In the univari-
ate analysis, increased association was observed in those

Table 2 Age-wise and gender-wise distribution of prevalence of diabetes mellitus

Prevalence of diabetes mellitus

n (%) (95% of CI) p Value

Age group (years)

Overall (n=2172) 1234 (10.14) (9.60 to 10.67)

Adjusted* 1234 (10.41) (10.39 to 10.42)

40–49 (n=5452) 398 (7.30) (6.60 to 7.99)

50–59 (n=2801) 399 (14.24) (12.95 to 15.94) <0.0001

60–69 (n=2810) 332 (11.81) (10.62 to 13.01)

70+ (n=1109) 105 (9.47) (7.74 to 11.19)

Gender

Male (n=5675) 556 (9.80) (9.02 to 10.57)

Female (n=6497) 678 (10.44) (9.69 to 11.18) 0.245

*Adjusted to age and gender as per the Tamil Nadu rural population census of 2001.

Table 3 Prevalence of DR in various subgroups

Prevalence of DR Prevalence of STDR

N n (%) (95% CI) p Value n (%) (95% CI) p Value

Overall 1190 122 (10.3) (8.53 to 11.97) 45 (3.8) (2.70 to 4.86)

Known diabetes 865 113 (13.1) (10.81 to 15.31) <0.0001 43 (5.0) (3.52 to 6.42) <0.0001
Newly diagnosed 325 9 (2.8) (0.99 to 4.55) 2 (0.6) (-0.23 to 1.47)

Age groups (years)

40–49 390 24 (6.2) (3.77 to 8.53) 4 (1.0) (0.03 to 2.03)

50–59 390 50 (12.8) (9.50 to 16.14) 0.007 23 (5.9) (3.56 to 8.24) 0.001
60–69 318 40 (12.6) (8.94 to 16.22) 17 (5.3) (2.88 to 7.82)

>69 92 8 (8.7) (2.94 to 14.46) 1 (1.1) (-1.03 to 3.21)

Gender

Female 651 53 (8.1) (6.04 to 10.24) 0.008 20 (3.1) (1.74 to 4.40) 0.159
Male 539 69 (12.8) (9.98 to 15.62) 25 (4.6) (2.86 to 6.42)

Duration group (years)

<5 916 58 (6.3) (4.75 to 7.91) 19 (2.1) (1.15 to 2.99)

5–10 160 29 (18.1) (12.16 to 24.10) <0.0001 11 (6.9) (2.96 to 10.80) <0.0001
10–15 79 22 (27.8) (17.97 to 37.73) 9 (11.4) (4.38 to 18.40)

>15 35 13 (37.1) (21.13 to 53.15) 6 (17.1) (4.65 to 29.63)

HbA1c

<7.0 593 30 (5.1) (3.30 to 6.82) 9 (1.5) (0.54 to 2.50)

>7.0 597 92 (15.4) (12.51 to 18.31) <0.0001 36 (6.0) (4.12 to 7.94) <0.0001
Insulin status

User 25 11 (44.0) (24.54 to 63.46) 7 (28.0) (10.40 to 45.60)

Non-user 1165 111 (9.5) 7.84 to 11.22 <0.0001 38 (3.3) 2.242 to 4.28 <0.0001
Systolic BP

<140 1013 87 (8.6) (6.86 to 10.32) 38 (3.8) (2.58 to 4.92)

>140 177 35 (19.8) (13.9 to 25.64) <0.0001 7 (4.0) (1.08 to 6.82) 0.896
Diastolic BP

<90 932 82 (8.8) (6.98 to 10.62) 34 (3.6) (2.45 to 4.85)

>90 258 40 (15.5) (11.08 to 19.92) 0.002 11 (4.3) (1.80 to 6.72) 0.646
BP, blood pressure (mm Hg); DR, diabetic retinopathy; HbA1c, glycosylated hemoglobin (%); STDR, sight-threatening DR.

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participants between the age group of 50 and 59 years
(OR 2.24) and between 60 and 69 years (OR 2.19), male
gender (OR 1.66), duration of DM >15 years (OR 8.74),
HbA1c of >7.0 (OR 3.41), use of insulin (OR 7.46),
systolic blood pressure (OR 2.62), and diastolic blood
pressure (OR 1.90). A multivariate model identified
five variables: male gender (OR 1.52), duration of DM
of >15 years (OR 6.01), HbA1c >7.0 (OR 3.37), use of
insulin (OR 3.59), and systolic blood pressure of
>140 mm Hg (OR 2.14).
Table 5 shows the relationship between types of DR

(non-proliferative, proliferative and maculopathy) and
known versus newly diagnosed DM; non-proliferative DR
and diabetic maculopathy were present in higher pro-
portion in those with known DM. Of the 122

participants with DR, 3 (0.02%) participants with known
diabetes were previously diagnosed to have DR; all had
STDR and had received laser photocoagulation.
Table 6 shows the relationship between types of DR

(non-proliferative, proliferative, and maculopathy) and
the duration of DM; all types of DR were present in
higher proportions in those having duration of diabetes
of more than 15 years.

DISCUSSION
In this study, the prevalence of diabetes and DR in a
rural South Indian population aged 40 years or more
was 10.1% and 10.3%, respectively. The prevalence of
STDR was 3.8% (known diabetes: 5% and newly

Table 4 Analysis of risk factors for diabetic retinopathy

Univariate analysis Multivariate analysis

OR (95% CI) p Value OR (95% CI) p Value

Age (years)

40–49 1 1

50–59 2.24 (1.35 to 3.73) 0.002 1.63 (0.95 to 2.83) 0.075
60–69 2.19 (1.29 to 3.73) 0.004 1.34 (0.75 to 2.39) 0.319
>69 1.45 (0.63 to 3.35) 0.381 0.89 (0.36 to 2.19) 0.797

Gender

Female 1 1

Male 1.66 (1.14 to 2.42) 0.009 1.52 (1.01 to 2.29) 0.045
Duration (years)

<5 1 1

5–10 3.27 (2.02 to 5.30) <0.0001 2.19 (1.29 to 3.73) 0.004
10–15 5.71 (3.26 to 9.99) <0.0001 3.91 (2.08 to 7.35) <0.0001
>15 8.74 (4.19 to 18.24) <0.0001 6.01 (2.63 to 13.75) <0.0001

HbA1c

<7.0 1 1

>7.0 3.41 (2.22 to 5.23) <0.0001 3.37 (2.13 to 5.34) <0.0001
Insulin status

Non-user of insulin 1 1

User of insulin 7.46 (3.31 to 16.83) <0.0001 3.59 (1.41 to 9.14) 0.007
Systolic BP

<140 1 1

>140 2.62 (1.71 to 4.03) <0.0001 2.14 (1.20 to 3.82) 0.010
Diastolic BP

<90 1 1

>90 1.90 (1.27 to 2.85) 0.002 1.36 (0.79 to 2.35) 0.273
BP, blood pressure (mm Hg); HbA1c, glycosylated hemoglobin (%).

Table 5 Severity of DR in known versus newly diagnosed DM

Mild NPDR Moderate NPDR Severe NPDR PDR CSME Any DR

DM n (%) p Value n (%) p Value n (%) p Value n (%) p Value n (%) p Value n (%) p Value

Overall

(n=1190)

32 (2.7) 54 (4.5) 24 (2.0) 12 (1.0) 25 (2.1) 122 (10.3)

Known

(n=865)

29 (3.4) 0.021 49 (5.7) 0.002 24 (2.8) 0.002 11 (1.3) 0.139 24 (2.8) 0.008 113 (13.1) <0.0001

Newly

diagnosed

(n=325)

3 (0.9) 5 (1.5) 0 (0.0) 1 (0.3) 1 (0.3) 9 (2.8)

DM, diabetes mellitus; CSME, clinically significant macular edema; NPDR, non-proliferative diabetic retinopathy.

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diagnosed: 0.6%). Table 7 shows the prevalence of dia-
betes and DR among the rural population in India and
the Asia-Pacific region.14–23 The previous population-
based studies from India, which estimated the preva-
lence of DR and DM, had a diagnosis of diabetes by
fasting blood sugar.17 18 20 The present study used the
gold standard, OGTT, for diagnosis of diabetes, and
standard fundus photography for diagnosis of DR. The
prevalence of diabetes in other Asia-Pacific region coun-
tries like China and Australia was similar to that in the
Indian rural population; however, the prevalence of DR
was much higher in these countries (21.4% in Australia
and 43.1% in the Chinese rural population).22 23 The
relative roles of genetic and lifestyle factors in these
ethnic differences remain unexplored.
We have earlier reported a nearly threefold prevalence

of diabetes and twofold prevalence of DR in the urban
population in South India.5 Diamond24 had also
described a similar trend of the prevalence of diabetes
being higher among the affluent, educated, urban
Indians than among the poor, uneducated, rural people.
The sedentary lifestyle and unhealthy food prefer-

ences could be the possible reasons for this urban–rural
divide.25–28

On multivariate analysis, the risk factors for DR were
male gender, longer duration of diabetes, poor glycemic
control, participants with diabetes on insulin, and

higher systolic blood pressure. These risk factors are
similar to those reported in the urban population and
also in other ethnic populations.5 22 23

The prevalence of any DR was more in participants
with known DM than in those who were newly diagnosed
(13.1% vs 2.8%, table 5). When data of the rural popula-
tion were compared with those of the urban population,
which were reported earlier, a higher prevalence of any
DR in the newly diagnosed was found in urban com-
pared with rural populations (6% vs 2.8%). However,
the prevalence of STDR (NPDR, PDR, CSME) was quite
low in those with newly diagnosed diabetes (2/325,
0.6%, table 5); a low prevalence of 0.4% was also noted
in the urban Indian population.5 Others have also noted
a somewhat low prevalence, ranging from around 2% to
3% in this subset.20 29–33

The strength of this study is that it uses OGTT for
diagnosis of diabetes and photography and standard
grading techniques for detecting DR. This study used a
unique customized mobile van with all equipments
required for standard collection of clinical data, which
also had easy access to rural areas. Furthermore, the
study is representative of a large population, and results
could be extrapolated to the rural population of Tamil
Nadu. In view of the lack of previous reports on the
rural prevalence of DR and STDR, this study is of
importance. The study limitations included the potential

Table 6 Severity of diabetic retinopathy in relation to duration of diabetes mellitus

Duration

(years)

Mild

NPDR p Value

Moderate

NPDR p Value

Severe

NPDR p Value PDR p Value CSME p Value Any DR p Value

<5 16 (2.7) 0.001 23 (3.9) <0.001 6 (1.0) <0.0001 4 (0.7) 0.008 13 (2.2) 0.046 49 (8.3) <0.001
5–10 5 (3.1) 13 (8.1) 6 (3.8) 5 (3.1) 5 (3.1) 29 (18.1)

10–15 6 (7.6) 7 (8.9) 8 (10.1) 1 (1.3) 1 (2.5) 22 (27.8)

≥15 2 (5.7) 6 (17.1) 4 (11.4) 1 (2.9) 4 (11.4) 13 (37.1)
CSME, clinically significant macular edema; NPDR, non-proliferative diabetic retinopathy.

Table 7 Prevalence of diabetes mellitus (DM) and diabetic retinopathy (DR) among the rural population in India and the

Asia-Pacific region

Location Year Population Sample Age

Assessment

of DM

Prevalence

of DM (%)

Prevalence

of DR (%)

India

India
14

1993 Population 467 >40 OGTT 4.90 Not reported

India
15

1999 Population 6091 >40 OGTT 1.74 Not reported

India
16

2003 Self-reported 3949 >50 FBS> 140 Nil 20.30

India
17

2004 Population 4917 >40 PPBS>180 4.40 5.30

India
18

2005 Population 4535 >30 FBS≥110 13.20 Not reported
India

19
2006 Self-reported 26 519 >30 Known DM Nil 17.60

India
20

2006 Population 25 969 >30 FBS>126 8.50 10.20

India
21

2007 Self-reported 5212 >50 Known DM 5.10 26.80

Present study 2010 Population 13 079 >40 OGTT 10.41 10.3

Asia-Pacific

China
22

2009 Population 6830 >30 FBS>126 6.90 43.10

Australia
23

2007 Population 1608 >40 HbA1c 4.90 21.40

FBS, fasting blood sugar; HbA1c, glycosylated hemoglobin; OGTT, oral glucose tolerance test; PPBS, postprandial blood sugar.

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of bias in ascertaining history-related variables and no
cause–effect relationship, being a cross-sectional study;
longitudinal studies would be needed to establish such a
relationship.
On extrapolating the data on the South Indian popu-

lation of Tamil Nadu based on the population projec-
tions of the Census of the Government of India,34 the
estimated population of diabetes in rural Tamil Nadu
over the age of 40 years would be nearly 9.5 lakhs and
those with DR would be nearly 1 lakh. It is also import-
ant to know that of the 865 participants with known dia-
betes, only 3 of them were known to have DR, and the
rest were newly detected on eye examination. This infor-
mation has a great impact on the public health aware-
ness programme—highlighting the need for regular eye
examination—in educating masses with DM. It is heart-
ening that we could identify several of the patients with
STDR in participants with known or newly detected DM.
These data stress the need for regular diabetic screening
programmes not only in urban areas but also in rural
areas in India.

Contributors SG, SSP, and RR researched the data. SG, VK, and RR wrote
the manuscript and researched the data. TS reviewed/edited the manuscript.
RR and TS contributed to the discussion.

Funding This work was supported by the Jamshetji Tata trust, Mumbai,
India.

Competing interests None.

Patient consent Obtained.

Ethics approval Vision Research foundation, Chennai.

Provenance and peer review Not commissioned; externally peer reviewed.

Data sharing statement No additional data are available.

Open Access This is an Open Access article distributed in accordance with
the Creative Commons Attribution Non Commercial (CC BY-NC 3.0) license,
which permits others to distribute, remix, adapt, build upon this work non-
commercially, and license their derivative works on different terms, provided
the original work is properly cited and the use is non-commercial. See: http://
creativecommons.org/licenses/by-nc/3.0/

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	Prevalence and risk factors for diabetic retinopathy in rural India. Sankara Nethralaya Diabetic Retinopathy Epidemiology and Molecular Genetic Study III (SN-DREAMS III), report no 2
	Abstract
	Patients and methods
	Study areas and sample size calculations
	Diagnosis of diabetes mellitus
	Evaluation of patients in a mobile van
	Step-by-step enumeration and enrollment
	Statistical analysis

	Results
	Discussion
	References