Original Article

Oral Vitamin D Supplementation and Clinical
Outcomes of Intravitreal Bevacizumab Injection for

Macular Edema Secondary to Retinal Vein Occlusions

Saeed Karimi1,2, MD; Farhad Parvizi2, MD; Amir Arabi2, MD; Toktam Shahraki2, MD; Sare Safi3, PhD

1Ophthalmic Research Center, Research Institute for Ophthalmology and Vision Science, Shahid Beheshti University of Medical
Sciences, Tehran, Iran

2Department of Ophthalmology, Torfeh Medical Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran
3Ophthalmic Epidemiology Research Center, Research Institute for Ophthalmology and Vision Science, Shahid Beheshti

University of Medical Sciences, Tehran, Iran

ORCID:
Saeed Karimi: https://orcid.org/0000-0002-3231-8414

Abstract

Purpose: To evaluate the therapeutic response of retinal vein occlusion (RVO)
to intravitreal bevacizumab (IVB) with and without concomitant vitamin D
supplementation.
Method: Seventy eyes of 68 patients with macular edema associated with branch
retinal vein occlusion (BRVO) and central retinal vein occlusion (CRVO) received
three monthly IVB injections. Patients with serum 25-hydroxyvitamin D (25(OH)
D) higher than 30 ng/ml were considered as the sufficient group. Cases with
serum 25(OH) D levels below 30 ng/ml were randomized into the treatment and
control groups. The control group received 50,000 IU of oral vitamin D, weekly for
two months. One month after the last IVB injection, best-corrected visual acuity
(BCVA) and central macular thickness (CMT) were measured and compared with
the preinjection values.
Results: While 43 eyes (61.4%) of 42 patients had BRVO, 27 eyes (38.6%) of
26 patients had CRVO. In BRVO patients, changes of CMT and BCVA were not
significantly different between the sufficient, control, and treatment groups (P =
0.58 and 0.64, respectively). In the CRVO group, CMT reduction in the control
group was significantly less than the sufficient and treatment groups (P = 0.048).
In addition, improvement of BCVA in the control group was significantly less (P =
0.036) than the sufficient and treatment groups.
Conclusion: Oral vitamin D supplement therapy may improve anatomical and
functional outcomes in patients with CRVO and vitamin D deficiency.

Keywords: 25-Hydroxyvitamin D; Bevacizumab; Insufficiency; Intravitreal; Macular Edema,
Retinal Vein Occlusion

J Ophthalmic Vis Res 2022; 17 (3): 376–383

376 © 2022 Karimi et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E

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Vitamin D Supplement and Response to IVB in RVO ; Karimi et al

INTRODUCTION

Retinal vein occlusion (RVO) is a major cause
of vision loss worldwide. Based on the location
of vascular occlusion, RVO can be manifested
as branch retinal vein occlusion (BRVO), central
retinal vein occlusion (CRVO), or hemi-CRVO.[1]
In CRVO, the blockage occurs in the main
retinal vein, whereas a BRVO is begun by an
occlusion in smaller veins, mainly at arteriovenous
crossovers through the retinal circulation. Macular
edema and macular ischemia are the main causes
of visual impairment in RVO, which are more
frequent and less responsive to treatment in
CRVO.[1]

Vitamin D is a nutritional supplement which
plays an important role in various pathways
in the body through the presence of its
receptor in several tissues, including the bones,
vascular myocytes, cardiac cells, hepatocytes,
and immune cells. Recently, the role of this
vitamin in vascular system health has been
established through various studies.[2] Both
animal models and human studies have shown
a positive correlation between vitamin D
insufficiency and hypertension, vascular events,
and mortality.[3, 4]

A few studies have evaluated the relationship
between different kinds of RVO and vitamin D
insufficiency.[1, 5, 6] The results of these studies
suggest the role of vitamin D in preventing ocular
vascular diseases. In the present study, in addition
to the prevalence of vitamin D insufficiency
in RVO cases, we assessed the effects of
supplementing oral vitamin D on the efficacy
of intravitreal bevacizumab (IVB) injections in
RVO.
Correspondence to:

Saeed Karimi, MD. Ophthalmic Research Center,
Research Institute for Ophthalmology and Vision
Science, Shahid Beheshti University of Medical
Sciences, No. 23, Boostan 9 St., Paidarfard St., Pasdaran
Ave., Tehran 16666, Iran.
Email: dr.saeedkarimi@gmail.com
Received: 05-02-2021 Accepted: 25-04-2022

Access this article online

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

DOI: 10.18502/jovr.v17i3.11575

METHODS

The current prospective, interventional, single-
center, randomized comparative study was carried
out at a tertiary care center in Tehran between
March 2018 and February 2019. The study was
approved by the Research Ethics Committees of
School of Medicine, Shahid Beheshti University
of Medical Sciences, Tehran, Iran. The study
followed the tenets of the Declaration of Helsinki.
Written consent was obtained from all of the
patients.

Patients with center-involving macular edema
secondary to perfused BRVO or non-ischemic
CRVO with an onset of less than three months prior
were enrolled in the study. The diagnoses of RVO
were made clinically by a single ophthalmologist
(SK). A diagnosis of center-involving macular
edema was made if the retinal thickness within
central 1-mm of macula was >300 μm as shown
on the optical coherence tomography (OCT)
image (Spectralis OCT, Heidelberg Engineering).
The eyes received treatment if the BCVA was
between 20/40 and 20/320 using the Snellen.
The exclusion criteria were the following:
age less than 18 years; patients on vitamin D
supplementation or therapeutic diets; history of
intravitreal anti-VEGF injections for the studied
eye in the last three months of enrolment; history
of intraocular surgery on the studied eye other
than uncomplicated surgery for senile cataract;
eyes with proliferative diabetic retinopathy or
diabetic macular edema; and patients with
renal, hepatic, and skin disease or chronic
alcoholism.

All patients received IVB (Avastin®) three times
monthly. All injections were performed at the
Torfeh Eye Hospital. During the administration of
the injections, ophthalmologists were masked to
the details of the study groups.

This is an open access journal, and articles are distributed under the terms of
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How to cite this article: Karimi S, Parvizi F, Arabi A, Shahraki T, Safi
S. Oral Vitamin D Supplementation and Clinical Outcomes of Intravitreal
Bevacizumab Injection for Macular Edema Secondary to Retinal Vein
Occlusions . J Ophthalmic Vis Res 2022;17:376–383.

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


Vitamin D Supplement and Response to IVB in RVO ; Karimi et al

Demographic data and clinical parameters
including BCVA and central macular edema (CMT)
were measured for each subject. Visual acuity
measurements were obtained through the Snellen
chart examination by a trained optometrist who
was masked to the study groups. Before the first
injection, 25(OH) D was measured in venous blood
samples. Patients whose measurements of 25-
hydroxyvitamin D revealed to be >30 ng/ml were
considered as the vitamin D-sufficient group, while
those with <30 ng/ml were randomly assigned
to the control and the treatment groups through
simple consecutive randomization. There were
three groups: group 1 (serum vitamin D ≥ 30 ng/ml),
group 2 (vitamin D-insufficient group treated with
vitamin D), and group 3 (control group). The
treatment group received 50,000 IU of vitamin D3
weekly for eight weeks. For patients with bilateral
RVO and macular edema (two patients), both eyes
were enrolled in the same study group.

Follow-up examination and OCT imaging were
performed one month after the completion of the
IVB injection protocol. The mean changes in visual
acuity and macular thickness were considered as
primary and secondary outcomes, respectively.
Oral vitamin D supplementation was prescribed for
the control group at the end of the study protocol.

Statistical Analysis

To present data, mean and standard deviation
were used. Chi-square and Fisher exact tests were
used to compare between qualitative data. T-test
and ANOVA (Bonferroni for pairwise comparison)
were used for comparing quantitative parameters
among the three study groups. To measure the role
of treatment on BCVA and CMT, we used paired
t-test analysis. The differences were considered
as significant if p-value was <0.05. All statistical
analyses were performed by SPSS (IBM Corp.
Released 2017. IBM SPSS Statistics for Windows,
Version 24.0. Armonk, NY: IBM Corp.).

RESULTS

Seventy eyes of 68 patients (55.7% male and 44.3%
female) were enrolled in this study. The mean age
of the patients was 62 ± 8 years. While 43 eyes

(61.4%) of 42 patients were diagnosed with BRVO,
27 eyes (38.6%) of 26 patients had CRVO [Figure
1].

The difference between the mean age of
patients in the sufficient, control, and treatment
groups was not statistically significant (mean
difference = 2.11, P = 0.571, and 95% CI [0.65–5.28]
for CRVO, mean difference = 1.98, P = 0.305, and
95% CI [0.31–7.1] for BRVO). The difference between
the gender of patients and laterality of the affected
eyes was also not statistically significant between
these groups (P > 0.05). The mean age of BRVO
and CRVO patients was 63.40 ± 7.49 and 58.85
± 7.73 years, respectively, and the difference was
statistically significant (mean difference = 5.81, P =
0.017, and 95% CI [3.69–9.37]) [Table 1].

While 28 patients had a sufficient level of 25(OH)
D before the initiation of treatment, 40 patients had
vitamin D deficiency. The prevalence of vitamin D
deficiency in our study was 58.8%. Compared to
the prevalence of vitamin D deficiency in Iranian
population (55%),[7] the prevalence of vitamin D
deficiency in our RVO patients was not significantly
different (P > 0.05).

Twenty-six eyes (60.4%) from the BRVO group
and fifteen (27.2%) eyes from the CRVO group had
insufficient levels of vitamin D. For both the groups,
the prevalence of vitamin D deficiency was not
significantly different from the reported prevalence
among the Iranian population. Additionally, the
levels of serum vitamin D were not significantly
different between BRVO and CRVO patients (mean
difference = 0.65, P = 0.25 and 95% CI [0.15–0.82]).

There was no significant correlation between
serum vitamin D levels and BCVA or CMT at
baseline [Table 2].

The changes of CMT following three monthly IVB
injections were statistically significant in all BRVO
subgroups. There were no significant differences in
CMT changes among the “sufficient”, “control”, and
“treatment” groups [Table 3].

Table 4 shows the changes of BCVA following
three IVB injections in BRVO patients. The
improvement of BCVA in the “sufficient” and
“treatment” groups were statistically significant,
but for the “control” group, this improvement was
not statistically significant (P = 0.179). Changes
of BCVA were not significantly different among

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Vitamin D Supplement and Response to IVB in RVO ; Karimi et al

 

Figure 1. Flowchart of patient’s enrollment. IVB, intravitreal bevacizumab.

Table 1. Characteristics of studied patients.

Parameter CRVO P-value BRVO P-value P-RVO

Sufficient Control Treatment Sufficient Control Treatment

Age 60.5 ±
7.81

56.57 ±
5.06

58.38 ±
9.69

0.571*** 63.41 ±
6.94

65.5 ±
5.49

60.92 ±
9.81

0.305*** 0.017**

25(OH)D
level

40.31 ±
12.74

18.3 ±
7.83

19.49 ±
6.32

<0.001*** 40.68 ±
15.76

23.65 ±
4.72

18.07 ±
8.49

<0.001*** 0.913**

Gender Male 8 (66.7%) 6 (85.7%) 6 (85%) 0.461* 7 (44%) 5 (35.7%) 6 (50.0%) 0.761*

Female 4 (33.3%) 1 (14.3%) 1 (15%) 9 (56%) 9 (64.3%) 6 (50.0%)

Eye OD 7 (58.3%) 2 (28.6%) 3 (37.5%) 0.405* 7 (41.2%) 8 (57.1%) 4 (33.3%) 0.452*

OS 5 (41.7%) 5 (71.4%) 5 (62.5%) 10
(58.8%)

6 (42.9%) 8 (66.7%)

* According to Chi-square test and Fisher exact test; **According to t-test; ***According to ANOVA (Bonferroni for pairwise
comparison); CRVO, central retinal vein occlusion; BRVO, branch retinal vein occlusion.

the “sufficient”, “control”, and “treatment” groups
(mean difference = 0.06, P = 0.64, and 95% CI
[0.01–0.13]).

Three monthly IVB injections significantly
decreased CMT in all CRVO subgroups (P <
0.05). However, the decrement of CMT in the
control group was less than the “sufficient” and

“treatment” groups, and the difference among CMT
changes in the CRVO subgroups was statistically
significant (P = 0.047) [Table 5].

In CRVO patients, improvement of BCVA
following three IVB injections was statistically
significant in the “sufficient” and “treatment”
subgroups (P < 0.05); however, in the “control”

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Vitamin D Supplement and Response to IVB in RVO ; Karimi et al

Table 2. The correlation between vitamin D levels, BCVA and CMT.

Baseline BCVA in
BRVO eyes

Baseline BCVA in
CRVO eyes

Baseline CMT in
BRVO eyes

Baseline CMT in
CRVO eyes

Vitamin D serum
level

Pearson’s correlation –0.042 0.083 0.101 –0.022

P-value 0.715 0.685 0.541 0.741

BCVA, best-corrected visual acuity; CMT, central retinal thickness; CRVO, central retinal vein occlusion; BRVO, branch retinal
vein occlusion.

Table 3. Changes of CMT following IVB in BRVO subgroups.

CMT BRVO Group P-value*

Sufficient Treatment Control

Baseline CMT 469.82 ± 139.2 520 ± 182.03 491.33 ± 165.93

0.578CMT at 3-month visit 355.88 ± 113.06 339.14 ± 101.87 366.83 ± 90.02
Change of CMT –126.44 ± 128.17 –180.86 ± 178.25 –124.5 ± 175.9
P-value** <0.001 <0.001 0.007

*According to ANOVA analysis; **According to paired t-test; CMT, central retinal thickness; BRVO, branch retinal vein occlusion.

Table 4. The Changes of BCVA following three IVB injections in BRVO subgroups.

BCVA (Log MAR) BRVO Group P-value**

Sufficient Treatment Control

Baseline BCVA 0.6 ± 0.33 0.55 ± 0.45 0.57 ± 0.48

0.64BCVA at 3-month visit 0.47 ± 0.34 0.29 ± 0.19 0.39 ± 0.28

Change of BCVA –0.14 ± 0.16 –0.26 ± 0.26 –0.17 ± 0.38

P-value* 0.03 0.0179 0.179

*According to paired t-test; **According to ANOVA; BCVA, best-corrected visual acuity; BRVO, branch retinal vein occlusion.

Table 5. Changes of CMT following three IVB injections in CRVO subgroups groups.

CMT CRVO Group P-value*

Sufficient Treatment Control

Baseline CMT 592.42 ± 272.63 575.14 ± 198.41 596.5 ± 248.69

0.047CMT at 3-month visit 413.58 ± 190.3 403.29 ± 190.92 455.75 ± 97.26

Change of CMT –178.83 ± 216.64 –171.86 ± 112.69 –141.75 ± 290.98

P-value** 0.0012 0.0039 0.016

*According to ANOVA analysis; **According to paired t-test; CMT, central retinal thickness; CRVO, central retinal vein occlusion.

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Vitamin D Supplement and Response to IVB in RVO ; Karimi et al

Table 6. Improvement of BCVA following three IVB injections in CRVO subgroups.

BCVA (Log MAR) CRVO Group P-value*

Sufficient Treatment Control

Baseline BCVA 0.94 ± 0.6 1.11 ± 0.69 1.1 ± 0.43

0.035BCVA at 3-month visit 0.64 ± 0.4 0.69 ± 0.42 1.01 ± 0.31
Change of BCVA –0.3 ± 0.26 –0.42 ± 0.57 –0.09 ± 0.72
P-value** 0.042 0.0236 0.844

*According to paired t-test; **According to ANOVA; BCVA, best corrected visual acuity; CRVO, central retinal vein occlusion.

group, change of BCVA was not statistically
significant (P = 0.84). Improvement of BCVA in
the “control” group was significantly less than the
“sufficient” and “treatment” groups (P = 0.035)
[Table 6].

DISCUSSION

In the present study, although the prevalence of
vitamin D deficiency in patients with BRVO and
CRVO was higher than the overall prevalence of
vitamin D deficiency in the Iranian population,[7]
the difference was not statistically significant. We
did not find significant correlations between serum
vitamin D levels and their effect on the baseline
BCVA and CMT measurements in BRVO and
CRVO patients. In the BRVO subgroups, vitamin
D supplement therapy did not have significant
influence on anatomical and functional outcomes
of the IVB injections. In CRVO subgroups,
however, vitamin D supplement therapy had
significant beneficial effects on both anatomical
and functional outcomes of the IVB injections. The
changes of BCVA and CMT following three IVB
injections were lower in patients with CRVO and
vitamin D insufficiency who were not treated with
oral vitamin D supplement therapy.

Vitamin D, whether as a nutritional supplement
or as a hormone, has numerous roles to play.[8] It
participates in the synthesis of many factors which
are involved in various metabolic mechanisms
other than calcium homeostasis. Vitamin D
insufficiency can be caused by limited UV
exposure, limitations of dietary intake, and by
numerous chronic skin and internal diseases.
Through its dependence on sunlight exposure

and dietary habits, serum levels of vitamin D may
be affected by some cultural and geographic
issues.[9] Recently, a positive correlation has been
postulated between vitamin D insufficiency and
the incidence of different vascular diseases.
This correlation has been established for
cardiac and cerebrovascular diseases, as well
as hypertension.[10] Both epidemiologic and
observational studies have reported higher
mortality due to vascular events in vitamin D-
deficient patients, which may happen during
winter and in regions with less UV-B exposure.[11]
Low serum vitamin D levels may be a risk
factor for vascular diseases.[12] It is notable
that systemic vascular diseases and retinal
vascular occlusions have some risk factors in
common. A non-classical function of vitamin
D, an improvement in the vascular endothelial
function, has been reported following vitamin D
supplement therapy.[13] A meta-analysis reported
that patients with type 2 diabetes mellitus and
vitamin D deficiency have a higher risk of diabetic
retinopathy.[14] Additionally, it is believed that
vitamin D plays a critical role in the modulation of
the immune system. It has been suggested that
25(OH) D dampens the activation of cytokines
and reduces the proliferation of inflammatory
cells.[15]

Vitamin D has received attention for its role in
reducing vascular events, regulating the renin-
angiotensin system and endothelial hemostasis,
controlling coagulation, and promoting anti-
inflammatory properties.[16] The role of 25(OH) D
deficiency in systemic vascular risks, endothelial
homeostasis, and inflammatory conditions could
possibly relate to the pathogenesis of RVO.

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Vitamin D Supplement and Response to IVB in RVO ; Karimi et al

After diabetic retinopathy, RVO is considered
as the most frequent retinal vascular disease.[17]
Macular edema secondary to venous occlusion
is the most common cause of visual loss in
RVO patients.[18] It can happen via inflammatory
mechanisms, vascular endothelial growth factor
production, or mechanical effects of increased
intraluminal pressure. Atherosclerotic and
vascular risk factors, including hypertension
and hyperlipidemia, have been established to
be involved in RVOs.[18] Similarly, the role of
inflammation in progression and complications
of retinal diseases, such as RVO, has been
recognized.[19] The potential role of thrombophilia
in RVO has also drawn attention during recent
years.[20]

According to a recent study by Epstein et al,
vitamin D is deficient in 50% of CRVO patients.[5]
Vitamin D deficiency had been previously reported
in a case of CRVO.[6] The results of a recent study
on a subset of Indian patients pointed toward the
role of vitamin D in ocular vascular mechanisms
and retinal vascular occlusion.[1] These studies
have also suggested a seasonal variation for RVO.

In addition, recently, a probable positive role
has been postulated for short-term vitamin D
supplementation in reducing inflammatory and
oxidative damage of the vascular system.[21] To
the best of our knowledge, this is the first study
evaluating the role of vitamin D supplement
therapy in anatomical and functional outcomes
of IVB injections in RVO patients. For each
RVO subgroup (BRVO and CRVO), the patients
were categorized as vitamin D-sufficient versus
-deficient. The anatomical effects of the IVB
injections were statistically significant in all study
groups. The improvement of BCVA following three
IVB injections were not statistically significant
in patients with BRVO or CRVO along with
vitamin D insufficiency who were not treated with
oral vitamin D supplement therapy. Additionally,
in CRVO subgroups, a positive correlation was
observed between 25(OH) D supplementation and
better anatomical and functional outcome of IVB
injections.

A small sample size is the main limitation of
the present study. Another limitation existed where
serum vitamin D levels were not re-measured

throughout the study to confirm the efficacy of
supplementation therapy. Finally, there may be
some confounding factors such as different dietary
intake of vitamin D among our patients along
with seasonal variations during the study. Future
randomized clinical trials with larger sample sizes
are needed to reveal the exact role of vitamin D in
RVO patients.

In summary, we observed that oral vitamin
D supplement therapy significantly improved
both the functional and anatomical outcomes
of IVB injections in CRVO patients with
vitamin D insufficiency. Patients receiving oral
supplementation experienced more decrease in
CMT and better improvement in BCVA following
IVB therapy, compared to the control group. Oral
vitamin D supplement therapy did not change the
outcomes of IVB injections in the BRVO cases.

Ethical Approval

All procedures performed in the study were in
accordance with the 1964 Helsinki Declaration.
This study was approved by the Ethics Committee
of the Ophthalmic Research Center at Shahid
Beheshti University of Medical Sciences, Tehran,
Iran.

Financial Support and Sponsorship

None.

Conflicts of Interest

None.

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