Original Article

Epidemiological and Clinical Features of Pediatric
Open Globe Injuries: A Report from Southern Iran

Ali Azimi1, MD; Fardad Abdollahi1, MD; Elham Sadeghi1, MD; Amir Reza Farsiani2, MD; Shadi Moshksar1, MD;
Maryam Nadi1, MD

1Poostchi Ophthalmology Research Center, Department of Ophthalmology, School of Medicine, Shiraz University of Medical
Sciences, Shiraz, Iran

2Department of Ophthalmology, Zanjan University of Medical Sciences, Zanjan, Iran

ORCID:
Ali Azimi: https://orcid.org/0000-0001-7744-5858

Elham Sadeghi: https://orcid.org/0000-0003-3802-3219

Abstract
Purpose: To evaluate the epidemiological features of open globe injury (OGI) in a tertiary
ophthalmic center in the south of Iran.
Methods: The medical files of pediatric patients diagnosed with OGI between March
2014 and March 2019 were reviewed retrospectively. Demographic data, laterality, time
of injury, cause of trauma, location and mechanisms, complications, and the involved
tissues, visual acuity, type of operation, and antibiotic therapy were all analyzed. Data
were processed using the SPSS.
Results: In total, 110 eyes of 108 patients were included. Ages <7 years comprised 49.1%,
7–12 years 26.4%, and 13–18 years 24.5% of cases. Of the 108 patients, 76 (70.3%) were
males. No significant difference between right versus left eyes was seen. The incidence
of OGI was lowest in winter and highest in spring, and it had more prevalence on the
weekends. Sharp objects were the most common cause of OGI in ages <7 years, while
blunt objects, accidents and falls, and guns and fireworks were more prevalent in older
children. Home was the most common place of injury overall. The most common type of
injury was penetrating trauma. Upon arrival, most of the children had a visual acuity
<0.1 decimal. Primary wound closure was the most prevalent type of surgery done
predominantly within 24 hr from admission time.
Conclusion: Ages <7 years and male gender were the most common age and sex
of pediatric OGI, respectively, and sharp objects were the predominant etiology. Early
management and primary repair are essential for prevention of complications such as
endophthalmitis and amblyopia.

Keywords: Eye Injury; Ocular Trauma; Pediatric; Open Globe Injury; Epidemiology

J Ophthalmic Vis Res 2023; 18 (1): 88–96

Correspondence to:

Elham Sadeghi, MD. Poostchi Clinic, Zand St., Shiraz 71349,
Iran.
E-mail: elham.sadeghi@rocketmail.com
Received: 12-09-2021 Accepted: 30-08-2022

Access this article online

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

DOI: 10.18502/jovr.v18i1.12729

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: Azimi A, Abdollahi F, Sadeghi E, Farsiani
AR, Moshksar S, Nadi M. Epidemiological and Clinical Features
of Pediatric Open Globe Injuries: A Report from Southern Iran . J
Ophthalmic Vis Res 2023;18:88–96.

88 © 2023 Azimi et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E

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Pediatric Open Globe Injuries; Azimi et al

INTRODUCTION

Twenty to fifty percent of all ocular injuries
occur in the pediatric age group. Due to a
lack of cooperation and poor compliance for
assessment and therapy, this group’s management
is complicated.[1] Pediatric ocular trauma is the most
leading cause of acquired unilateral vision loss
in childhood, especially in developing countries.[2]
Despite all that has been done to reduce the risk of
trauma in children, it remains common worldwide.[3]

Ocular injuries are divided into two main groups:
closed globe injuries and open globe injuries
(OGIs). An OGI is a severe form of trauma leading
to a full-thickness defect in the cornea, sclera, or
both, exposing the intraocular compartments to
the external environment. OGIs are classified into
four groups: penetrating injury (only an entrance
wound or same entrance/exit wound), perforating
injury (separate entrance and exit wounds), rupture
(resulting from blunt trauma causing a full-thickness
defect at the weakest point of the eyewall),
and intraocular foreign body (IOFB). The lack of
treatment in childhood trauma may lead to various
complications such as cataract, retinal detachment,
vitreous hemorrhage, corneal opacity, amblyopia,
IOFB and toxicity due to chronic foreign bodies,
endophthalmitis, and sympathetic ophthalmia.[4]

Knowledge of the epidemiological
characteristics of the OGI can assist in the
prevention of catastrophic damage to children’s
physiological and psychological health. World
Health Organization (WHO) has recognized
childhood blindness as one of the leading causes
of preventable blindness.

Determination of epidemiologic risk factors and
prognosis of OGIs are essential in achieving
a healthier outcome and also reducing its
prevalence.[5] Therefore, we carried out a
retrospective study to evaluate the clinical course
and outcomes in all patients younger than 18 years
old who were admitted to this tertiary referral
university-affiliated ophthalmology center in the
south of Iran due to OGI.

METHODS

In this retrospective study, the medical charts
of pediatric patients suffering from OGIs were
reviewed. The medical records of 110 eyes of 108
children (age ≤18 years) admitted to this hospital

due to ocular trauma and diagnosed by slit-lamp
examination or examination under anesthesia from
March 2014 to March 2019 were evaluated. Patients
who had a full-thickness ocular injury repaired at
other centers were excluded.

In the medical charts, the initial ophthalmology
examination sheets, hospital records, details of the
operation notes, and outpatient follow-up were all
reviewed. Demographic data were collected on
age, sex, injured eye, ocular status before the
trauma, laterality, place of trauma, month and year
of injury, and mechanism of trauma.

The initial best corrected distance visual
acuity (BCDVA), evaluated by Snellen chart,
was recorded. No light perception (NLP) visual
acuity (VA) was confirmed using an indirect
ophthalmoscope with a bright and highest intensity
light source. Clinical data such as intraocular
pressure (IOP) with Goldman tonometer, location
of injury (home, school, and street), type of
injury, uvea and pupil status, hyphema, lens
status, vitreous, retina and choroidal conditions,
involvement of orbit, presence of uveitis or
endophthalmitis, and types of required surgeries
were all recorded. Based on the Birmingham Eye
Trauma Terminology (BETT), cases were classified
into penetrating, perforating, or IOFB injury.

The study protocol was approved by the ethics
committee of the university hospital. It adhered to
the tenants of the Declaration of Helsinki.

Continuous parameters were reported as
mean ± SD. Chi-square and Fisher’s exact tests
were used to compare the categorical data, and
independent t-test and ANOVA tests were used to
compare the continuous data. Statistical analysis
was performed using the SPSS for Windows (SPSS
Inc, Chicago, IL). Data analysis was interpreted
using a significance level of P < 0.05.

RESULTS

A total of 110 eyes of 108 pediatric patients initially
diagnosed as OGI was included in this five-year
study period (from March 2014 to March 2019).
Patients’ mean age was 7.8 ± 5.2 years (range, 6
months to 18 years) with a median of 7 years and
a mode of 2 years. The mean age was 8.7 ± 5.4
years for boys, while the girls’ mean age was 5.8 ±
4.1 years (P = 0.006).

Patients’ eyes were divided into three different
age groups: <7 years (49.1% n = 54), 7–12 years

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Pediatric Open Globe Injuries; Azimi et al

(26.4% n = 29), and 13–18 years (24.5% n = 27). The
majority of our cases were in the preschool age
(<7years) group (P < 0.001).

In our study, 69.1% of eyes were related to the
male gender (n = 76) and 30.9% were related
to females (n = 34). Boys were statistically more
susceptible to experience OGI than girls (ratio 2.2:1;
P < 0.001). This predominance rose sharply from
preschool children to older children 13–18 years old
(1.57:1 to 8:1) (P < 0.001).

As shown in Figure 1, there is a negative
correlation between age and incidence of OGI in
girls.

The rate of right eye involvement was 53.6% (n
= 59), and the left eye was 46.3% (n = 51) with
no statistically significant difference. There were
two cases with bilateral eye involvement caused by
motor vehicle accident and mine explosion.

As shown in Table 1, the incidence of OGI was
lowest in winter and highest in spring with no
statistically significant difference by season (P =
0.76). Incidences were more on the weekends, but
there were no significant differences regarding the
day of the week (weekdays vs weekends; P = 0.37)
[Table 2].

Most of the injuries were caused by sharp
objects (37.3% n = 41), followed by blunt objects
(35.3% n = 39), accidents and falls (17.3% n =
19), and guns and fireworks (10% n = 11). A
statistically significant difference was identified
between causative objects of the injuries and
different age groups (P = 0.027). Sharp objects
comprised a greater number of OGI in the
preschool age group (<7 years), while blunt
objects, accidents and falls, and guns and fireworks
accounted for more injuries in older children (7–18
years). Knives and wooden sticks were the most
common tools among the sharp and blunt objects
that provoked OGI in all children [Table 3].

Home was the most predominant place of injury
(54% n = 60), followed by outdoor environment
(street 25.5% n = 28, farm 7.3% n = 8, industrial
places 0.9% n = 1) and school (11.8% n = 13). Home
was the top place that injuries occurred amid
the preschool age group (<7), while the outdoor
environment was more frequent in older ages (All
Ps < 0.001) [Table 4].

Most of the injuries (68% n = 75) occurred
while playing. In decreasing order of frequency,
accidents (17.3% n = 19), assaults (10% n = 11), and
occupation-related factors (4.5% n = 5) were the
other activities that led to injuries (P < 0.001).

The majority of the injuries in both boys and
girls happened during playing, but assaults and
occupation-related factors encompassed a higher
percentage of injuries in boys (boys to girls’ ratio for
assaults is 7.3:2.7, and for occupational is 3.6:0.9) (P
< 0.001).

The most common types of injury, according to
BETT, were penetrating injuries (60.9% n = 67),
followed by rupture (7.3% n = 8), IOFB (6.4% n
= 7) and perforating injury (0.9% n = 1). Of the
110 traumatized eyes, 25 (22.7%) had multiple eye
involvement and could not be categorized based
on the BETT system. Two (1.8%) cases only had a
partial-thickness laceration of the eye.

Penetrating traumas were the primary type of
injuries in all age groups and genders, however,
rupture injuries were observed mainly in boys and
children over seven years of age (87%, seven out
of eight rupture cases). We had only one case
of perforating injury; a 16-year-old boy hit by a
shotgun while playing on the farm.

Laceration layers in penetrating injuries were
mostly corneoscleral (47.7% n = 32), followed by
corneal (29.8% n = 20) and scleral (22.3% n = 15)
layers. Corneoscleral involvement rose sharply in
boys as compared to girls (25:10 cases). There were
no significant statistical differences in penetrating
injuries between different genders (P = 0.38) and
age (P = 0.16) according to the laceration layers.

The mean size of lacerations in corneal
penetrating injuries was 5.7 ± 3.1 mm with a
median of 5 mm, while it was 3.47 ± 2.3 mm in
scleral penetrating injuries with a median of 3 mm.

In 57 cases of corneal penetrating injuries, the
main site of laceration was nasal (35% n = 20),
followed by temporal (28% n = 16), central (15.8%
n = 9), superior (12.3% n = 7), and inferior (8.8% n =
5).

In 52 cases of scleral penetrating injuries, the
most common site of laceration was nasal (36% n =
19), followed by temporal (28% n = 15), inferior (17%
n = 9), superior (15% n = 8), and central (1.9% n = 1)
[Table 5].

Upon arrival, VA could not be evaluated in
36.4% (n = 40) of the cases because they were
uncooperative. In four cases, VA was recorded
using the CSM method (central, steady, and
maintained eye position), which all of them
presented C+S+M+VA.

BCDVA upon arrival was categorized into three
groups: 0.5–1, 0.1–0.49, and under 0.1 decimal. In

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Pediatric Open Globe Injuries; Azimi et al

Figure 1. Distribution of trauma according to sex and age groups.

Figure 2. Vision categories by sex and age groups.

Table 1. Number of OGI by season.

Season Number Percentage

Spring 34 30.9 P = 0.76

Summer 28 25.5

Fall 25 22.7

Winter 23 20.9

OGI, open globe injury

Table 2. Distribution of trauma by days of the week.

Days of the week N Percentage

Saturday 14 12.7 P = 0.37

Sunday 18 16.4

Monday 15 13.6

Tuesday 12 10.9

Wednesday 11 10.0

Thursday 19 17.3

Friday 21 19.1

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Pediatric Open Globe Injuries; Azimi et al

Table 3. Causative objects of open globe injuries in children.

Objects N (%) Objects N (%)

Knife 23 (20.9%) Belt 3 (2.7%)

Accidents 16 (14.5%) Eye glass 3 (2.7%)

Wood 12 (10.9%) Fall 3 (2.7%)

Metal, wire, nails 8 (7.2%) Fist 3 (2.7%)

Stone 7 (6.4%) Animal horn 2 (1.8%)

Gun 5 (4.5%) Pen 2 (1.8%)

Fireworks 5 (4.5%) Explosion 1 (0.9%)

Needle 4 (3.6%) Others 13 (11.8%)

Table 4. Place of injury according to age groups.

Age groups (yr) Place of injury

Home School Outdoor P-value

N (%)

<7 43 (39.1) 1 (0.9) 10 (9.1) <0.001
7–18 17 (15.5) 12 (10.9) 27 (24.5) <0.001

66 eyes, which had registered VA upon arrival,
most of the eyes had VA under 0.1 (62.1% n = 41),
followed by 0.5–1 (25.7% n = 17) and 0.1–0.49 (12.1%
n = 8).

In under 0.1 categories, VA was counting
fingers in 13 cases, hand-motion in 6 cases, light
perception in 9 cases, and NLP in 13 cases. As
shown in Figure 2, in the male group, the VA
under 0.1 was clearly higher than the female group.
Additionally, the cases between 7 and 18 years
old, compared to patients <7 years old, significantly
presented the VA under 0.1 upon arrival.

Operation was performed on 93.6% of the cases
(n = 103) with an initial diagnosis of OGI. Ninety-five
percent of the operations (n = 98) were performed
within 24 hr from the admission time. Five children
only had an examination under sedation (EUS).
Three children were discharged voluntarily despite
the physicians’ recommendation for surgery.

Out of the 98 patients who underwent surgery,
47.3% were operated on once; 33.6% (n = 37) had
two surgeries; and 12.7% (n = 14) had more than
two surgeries. Primary repair of lacerations was the
most common type of the initial operation (75.7% n
= 78). Peritomy comprised 24.2 % (n = 25) of the
initial operations. Table 6 shows operations that
were done after the initial surgeries. Of the 110 eyes

with OGI, injuries finally led to the enucleation of
the eyes in 7.2% of the cases (n = 8).

About 88% of the patients received antibiotics
during admission to the hospital. Children
in preschool-age received more intravitreal
antibiotics or a combination of both intravitreal and
intravenous antibiotics, while antibiotic therapy in
older aged children was mainly via the intravenous
route (P = 0.008) [Table 7]. About 84% of the
patients (n = 93) received intravenous antibiotics.
The mean days of receiving antibiotics were
3.4 ± 1.2 days, with a median of three days. A
combination of ceftazidime and vancomycin were
the most common antibiotics used intravenously
(75% n = 70), followed by cefazolin and gentamicin
(22% n = 21) and ceftriaxone and vancomycin (2.1%
n = 2). From 20 cases who received intravitreal
antibiotics during operation, cefazoline was the
main choice (18 out of 20), and two other cases
received intravitreal gentamycin and imipenem.

DISCUSSION

Pediatric OGI can cause lifelong complications and
unilateral blindness.[6] Since prevention is better
than cure, solutions must be found to reduce it. Our
study revealed an increase in OGI in preschool-
aged children (<7 years). This is similar to the

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Pediatric Open Globe Injuries; Azimi et al

Table 5. Complications and eye layers involvement.

Complication N (%) Complication N (%)

Corneal laceration 59 (53) Retina: hemorrhage 5 (4.5)

Scleral laceration 55 (50) Retina: edema 3 (2.7)

Uvea in wound 5 (4.5) Retina: tear 2 (1.8)

Hyphema 76 (69) Retina: dialysis/detachment 3 (2.7)

Iris injury 28 (25) External muscles 2 (1.8)

Hypotony 108 (98.18) Lid 19 (17.2)

Optic nerve injury 26 (23) Lacrimal system 2 (1.8)

Lens: cataract 40 (36) Orbit: fracture 5 (4.5)

Lens:
subluxated/dislocated

3 (2.7) Orbit: foreign body 1 (0.9)

Vitreous: hemorrhage 17 (15.4) Orbit: hemorrhage 4 (3.6)

Vitreous: prolapse 2 (1.8) Inflammation: uveitis 9 (8.1)

Choroid: hemorrhage 2 (1.8) Inflammation: endophthalmitis 5 (4.5)

Choroid: rupture 1 (0.9)

Table 6. Operations after the initial surgeries.

Operation N (%) Operation N (%)

Lensectomy 21 (19) Pupiloplasty 4 (3.6)

Deep Viterectomy 21 (19) Phaco 2 (1.8)

Anterior Viterectomy 2 (1.8) Tarsoplasty 2 (1.8)

Suture removal 9 (8.1) Iris cystectomy 2 (1.8)

Enucleation 8 (7.2) Lateral canaloplasty 1 (0.9)

IOFB removal 6( 5.4) Dacryocystorhinostomy 1 (0.9)

IOL implantation 5 (4.5) ERMs removal 1 (0.9)

PCIOL implantation 3 (2.7) Posterior capsulectomy 1 (0.9)

Lid reconstruction 4 (3.6) Orbital wall repair 1 (0.9)

study by El-Sebaity et al,[7] but some reports have
found increasing OGI risk in the 7–12 years old age
group.[8–10]

Different studies showed different ratios of
female OGL, but all agree that males’ injury is
statistically higher than females’ injury, which is
related to the propensity of the male gender to
higher risk activities with less parental supervision
as part of their natural growth.[4, 11–15] Besides, the
differences between the sexes among the older
age groups (12–18 years) increased significantly,
and there was a negative correlation between age
and incidence of OGI in females. It suggests that
girls’ dangerous and risky activities may reduce
with aging.

There was no significant difference between
the right and the left eyes. This is similar to the
results of the study by Tan et al,[16] however, some
reports have revealed that in adult cases, the right
eye is more susceptible to injuries because, in
adults, most injuries occur in the workplace.[17, 18]
It must also be kept in mind that severe traumatic
accidents, explosions, or intentional assault injuries
may induce bilateral ocular involvement.

We have reported the OGI trend during vacation,
as mentioned in other studies.[19, 20] A higher
incidence of OGI on Fridays shows that children
have more dangerous activities on the weekend.
The risk increase in spring is a result of Norouz
holidays in Iranian culture. At this time, the
weather becomes warmer, and children tend

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Pediatric Open Globe Injuries; Azimi et al

Table 7. Route of antibiotic injection by age groups.

Age groups (yr) Route of antibiotic P-value

Intravitreal Intravenous Both 0.008

N (%)

<7 11 (11.3) 27 (27.8) 12 (12.4)
7–18 3 (3.1) 39 (40.2) 5 (5.2)

to play outdoor group games without parental
supervision. It may be avoided with parental
supervision, keeping dangerous devices out of
children’s reach, and educating children about
proper safety considerations.

The prevailing etiological agent causing OGI in
the preschool age group is sharp material such as
knives, which correlates with previous studies.[6,
21, 22] Ocular trauma with knives usually happens
accidentally. It is crucial to either decrease access
to sharp objects or replace them with round
blunt-tipped knives.[1] Older children are injured
more by blunt objects, accidental falls, guns,
and fireworks, predominantly in males related
to practicing more aggressive behavior. These
injuries can be prevented with proper training and
using protective eyewear. Ocular trauma during car
and motor accidents were the cause of 14.5% of
OGI, and it is usually due to glass particles or blunt
trauma. Using seatbelts and helmets may reduce
the risk of experiencing ocular trauma during a
road accident.

Prior studies have revealed that ocular injuries
most frequently occur at home.[4, 12, 23] In this
study, home was the main place for the incidence
of ocular injuries occurring in preschool-aged
children. As this age group spends most of their
time at home, the use of toys with blunt edges
and increased parental supervision may reduce the
ocular trauma risk. Covering the sharp edges of
household items with protective equipment may
also be useful. Further awareness of parents and
babysitters is recommended to prevent preschool-
age OGI.[24] Some reports have shown that outdoor
spaces are the most common place for OGI
occurrences in pediatrics.[25, 26] In our study,
the outdoor environment is the primary place for
older children, especially in the male group, due to
accidents, assaults, and occupation-related factors.
Educating children to follow safety principles and
practice anger management can be useful in

reducing the occurrence of accidents, assaults, and
occupational hazards that may lead to OGI.

Analysis of OGI in this report revealed that
penetrating injuries were the most common type
of ocular trauma (60.9%), which was consistent with
data published by Puodžiuvienė et al.[8] The rate of
globe ruptures was 7.3%, which was lower than the
data reported by Court et al.[27] OGI with IOFB is
more often experienced in adults. However, it is not
rare in children.[28] The rate of IOFB injuries in our
study was 6.4%. Compared to other types of OGI in
pediatrics, perforating injury is not common in this
group[29] as this type of injury is most often caused
by shotgun usage which is not normally used in this
age group. In our study, one patient was 16 years
old with perforating OGI caused by firing a shotgun
while playing on the farm.

The majority of wounds involve both cornea
and sclera (47.3%), and hypotony is the most
common presentation (98.18%). Two patients did
not have hypotony because the laceration was
partial thickness. Hyphema was the second most
common sign (69%). One study had shown that
hyphema was significantly related to closed globe
injuries.[30] The other prevalent signs in OGI are
traumatic cataract, iris injury, optic nerve injury, lid
laceration, and vitreous hemorrhage.

In this study, 37.3% of cases had <0.1 VA upon
arrival where 78% were males. This measurement
is justified as more severe injuries occur in males
due to their inherently more aggressive behavior.

Primary repair of the wound and repositioning
of the prolapsed tissue is the most common
surgery performed initially, usually within 24 hr
from admission.[4] Endophthalmitis is one of the
most serious and poor prognosis complications
after OGI, which is preventable by primary wound
closure.[31] About one-third (33.6%) of cases
underwent surgeries twice, and 12.7% of them
underwent surgeries three times. Lensectomy and
deep vitrectomy were the most common types of
surgery performed after the initial operation. In

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Pediatric Open Globe Injuries; Azimi et al

an effort to prevent sympathetic ophthalmia, 7.2%
of cases underwent enucleation and conformer
placement surgery due to devastating injury and
NLP VA.

Antibiotics administration plays a role in
prophylaxis and treatment of endophthalmitis.[32]
Traumatic endophthalmitis is usually seen in
delayed wound closure, IOFB, posterior capsule
rupture, delayed initiation of prophylactic antibiotic
therapy after 24 hr from ocular trauma, and wound
contamination with organic material.[33, 34] The
antibiotic selected for treatment should have a
broad spectrum acting against a larger group of
microorganisms.[35]

The visual prognosis in pediatric OGI is not
good. Statistics show that patients with ocular
trauma in one eye are susceptible to trauma
in the fellow eye.[36] Assessing ocular trauma
is more important in the pediatric group due
to longer lifespans and the more incidence
of ocular complications in this group including
cataract, retinal detachment, vitreous hemorrhage,
corneal opacity, amblyopia, IOFB and toxicity due
to chronic foreign bodies, endophthalmitis, and
sympathetic ophthalmia; hence emphasizing that
prevention is better than treatment. Education of
parents, babysitters, and school teachers about
children’s supervision and choosing suitable toys
according to child’s age is needed. Keeping
dangerous objects with sharp edges out of the
reach of children is essential. Using protective
eye glasses may play a useful role in preventing
ocular trauma, while playing or working with sharp
objects. To prevent eye injuries during an accident,
using safety measures like suitable child seats, seat
belts, and helmets are effective. Older children
should be educated to avoid using guns, fireworks,
and explosive devices.

This report is a retrospective and non-
randomized study with some limitations because it
was limited to medical files during hospitalization.
Further studies may be needed to determine the
overall burden of disease, post-discharge follow-up
data, final VA, and delayed complications.

The second limitation is that as ocular trauma
patients were referred to multiple centers, the
actual number of patients with OGI recorded in this
report is incomplete.

In summary, the results suggest the importance
of prevention in reducing the frequency of
ocular trauma in children due to longer lifespan.

Also, it has recommended early primary wound
closure to reduce or prevent devastating ocular
complications. Additionally, it has counsel that
extended follow-up is necessary to reduce and
manage further complications such as amblyopia.
More studies are recommended to accurately
evaluate the prognosis of OGI in the long-term.

Acknowledgements

This work was supported by Shiraz University of
Medical Sciences and Poostchi Ophthalmology
Research Center.

Financial Support and Sponsorship

None.

Conflicts of Interest

The authors declare that they have no conflict of
interest.

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