Original Article

Outcomes Following Pars Plana Vitrectomy for Severe
Ocular Trauma

Natalia K. Bober1,2, MBBS; Neruban Kumaran1, PhD, FRCOphth; Tom H. Williamson1,2, MD, FRCOphth

1St Thomas’ Hospital, London, UK
2King’s College Medical School, London, UK

ORCID:
Natalia K Bober: https://orcid.org/0000-0002-2190-3992
Tom H Williamson: https://orcid.org/0000-0002-1879-449X

Abstract
Purpose: To investigate outcomes and presenting characteristics for subjects undergoing
pars plana vitrectomy for ocular trauma.
Methods: Retrospective study of 113 patients who underwent pars plana vitrectomy for
severe ocular trauma at [name deleted to maintain the integrity of the review process]
between 1999 and 2018. Data were collected on age, gender, initial and final visual acuity
(LogMAR), mode of injury, type of injury, number of surgeries performed, follow-up duration,
type of tamponade, presence of phthisis, and retinal detachment. The Birmingham Eye
Trauma Terminology System (BETTS) was employed.
Results: We identified assault and contusion injuries to be the most common mode and
type of ocular injury in our cohort. Furthermore, through follow-up we noted a varied
number of operations required by patients presenting with ocular trauma and a statistically
significant improvement in visual acuity from 1.73 (±0.86) LogMAR to 1.17 (±1.03; p <0.01)
LogMAR. A statistically significant difference in final visual acuity was also noted between
BETTS classified type of injury groups (p < 0.01). Notably, only 7.3% and 8.2% of patients
developed phthisis or a persisting retinal detachment, respectively, during follow-up.
Conclusion: Our study demonstrates that ocular trauma requiring pars plana vitrectomy
can require a varied number of operations with a guarded visual prognosis. However, a
small percentage will proceed to develop phthisis following intervention.

Keywords: Ocular Trauma; Visual Outcome; Vitrectomy

J Ophthalmic Vis Res 2021; 16 (3): 408–414

INTRODUCTION

Ocular trauma can cause severe visual impairment
with substantial impact on quality of life.

Correspondence to:

Tom H. Williamson, MD. Department of Ophthalmology,
St Thomas’ Hospital, Westminster Bridge Road, London,
SE1 7EH, UK.
Email: tom@retinasurgery.co.uk
Received: 05-05-2020 Accepted: 29-03-2021

Access this article online

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

DOI: 10.18502/jovr.v16i3.9449

Globally, ocular trauma accounts for blindness in
approximately 1.6 million people with a further
2.3 million suffering from bilateral low vision and
approximately 19 million with unilateral blindness
or low vision.[1] Furthermore, it is estimated that
there can be around 120,000 of presentations
to the Accident and Emergency department due
to ocular injuries, annually in the United Kingdom,[2]

This is an open access journal, and articles are distributed under the terms of
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allows others to remix, tweak, and build upon the work non-commercially, as
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identical terms.

How to cite this article: Bober NK, Kumaran N, Williamson TH. Outcomes
Following Pars Plana Vitrectomy for Severe Ocular Trauma. J Ophthalmic
Vis Res 2021;16:408–414.

408 © 2021 Bober et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E

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Vitreoretinal Surgery for Ocular Trauma; Bober et al

with hospital admissions estimated to be 8.14 per
100,000 people.[3]

Surgical intervention following ocular trauma
has two main objectives, firstly to protect ocular
integrity and secondly to improve/stabilize vision.
The majority of ocular injuries that causes
substantial visual loss involve the posterior
segment of the eye and as a result these patients
often undergo posterior segment (vitreoretinal)
surgery.

Pars plana vitrectomy (PPV) allows the
reconstruction of the posterior segment of
the eye, clear visually significant vitreous
opacities, control inflammation, and where
appropriate treat retinal detachment. It can
also be used to manage posterior segment
complications of closed-globe/contusion injuries
including retinal detachment, macular hole, and
vitreous hemorrhage.[4] PPV was found to have
a good prognosis, contributing to significant
improvements in visual outcomes following ocular
trauma.[5, 6] When used as a primary procedure,
it resulted in more eyes achieving the final vision
of light perception (LP) or better, compared to
those that did not undergo the surgery.[5] An
important complication of open globe trauma
and associated retinal detachment is proliferative
vitreoretinopathy, an intraocular scarring process,
which can lead to recurrent retinal detachment,
associated with poor final visual outcomes.[7]

Many groups have investigated independent
prognostic factors for ocular trauma. Commonly
reported poor prognostic factors include poor
initial visual acuity, relative afferent pupillary
defect, multiple surgeries, posterior ocular (zone
III, >5 mm posterior to the limbus) injury, vitreous
hemorrhage, hyphema, lid laceration, and posterior
wound location.[5, 6, 8–10] This was taken further by
one group, who developed Ocular Trauma Score
(OTS).[11] This score system uses the information
of the initial visual acuity, presence of globe
rupture, endophthalmitis, perforating injury, retinal
detachment, and relative afferent pupillary to
estimate the visual outcomes.

Furthermore, given a lack of standardization
of classifications and definitions used in ocular
trauma studies, the Birmingham Eye Trauma
Terminology System (BETTS) was created,
introducing a simple and consistent way of
classifying ocular trauma, allowing easier and
more objective comparison.[12]

The epidemiology of eye injuries is known to
vary depending on the population studied and is
influenced by multiple factors including lifestyle,
socioeconomic status, traffic state, and recreational
activities.[13]

A number of studies have investigated the
epidemiology of ocular trauma. Knowledge
of specific risk factors associated with ocular
injuries in a population can contribute to targeted
campaigns that aim to reduce the incidence of
ocular trauma in the community.[14] This in turn may
involve specifically designed programs to increase
the workplace safety and awareness of ocular
injuries.[15]

Herein, we aim to investigate the frequency of
both different modes and types (based on BETTS)
of ocular trauma and surgical outcomes of PPV.

METHODS

A retrospective analysis of 113 patients who had
undergone PPV at St Thomas’ Hospital, London,
UK between July 23, 1999 and June 25, 2018
was conducted using the VITREOR database
(Microsoft Access, Albuquerque, USA). The study
was completed in adherence to the tenets of the
Declaration of Helsinki and received appropriate
local approvals. All patients underwent PPV for
posterior segment complications requiring surgical
intervention. Data were collected on age, gender,
visual acuity (LogMAR), mode of injury, type of
injury, type of tamponade, number of surgeries
performed, and time of follow-up. Furthermore,
outcomes of phthisis and retinal detachment
were noted. Mode of injury was classified into
assault, domestic, industrial, road traffic accidents,
and sport-related injury. Similarly, the type of
ocular injury was categorized as per the BETTS
classification, that is, as follows: contusion (without
a full-thickness wound to the eye), intraocular
foreign body (IOFB), penetrating (entrance wound
alone), perforating (entrance and exit wound),
and rupture (full thickness wound caused by a
blunt trauma).[12] All patients included in the study,
including those with ocular contusions, underwent
PPV.

All statistical analysis was performed using the
SPSS Statistics software package (IBM, New York,
USA). The perforating injury group was excluded
from analysis due to its comparatively low number.
A Chi-square test of independence was used to

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Vitreoretinal Surgery for Ocular Trauma; Bober et al

investigate the difference in frequency of ocular
trauma between men and women. The mean
preoperative and postoperative visual acuities
were compared using a paired t-test. A one-way
analysis of variance (ANOVA) and a subsequent
Tukey’s post-hoc test were used to investigate
whether there was a difference in the age of
presentation between each mode of injury and
whether different BETTS classified types of injury
were associated with the need for greater or fewer
operations and a better or worse final visual acuity.
Multiple regression analysis was undertaken to
investigate age, gender, initial visual acuity, and
type of ocular injury (as defined by the BETTS
classification) on final visual acuity.

The study was completed in adherence to the
tenets of the Declaration of Helsinki and received
appropriate local approvals.

RESULTS

Cohort Demographics

The study included 113 patients, of whom 99 were
male and 14 female. Age ranged from 6.2 years
to 87.7 years with a mean age of 42.7 years (SD:
±18.8 years). Longitudinal data were available for
110 patients with follow-up ranging from 1 day to 12.1
years with a mean follow-up of 1.8 years (±2.5).

Men were found to have a statistically
significantly higher risk of ocular trauma,
contributing to 87.6% of all analyzed cases (p
< 0.01).

In terms of mode of injury, assault (35 cases)
and industrial (33 cases) were the most common
modes of injury, followed by domestic (25 cases)
and sport (14 cases). Least common were road
traffic accidents (6 cases). As per the BETTS
classification, contusion was the most common
type of injury recorded (47 cases), followed by
IOFB (25 cases). Notably, all IOFB injuries included
posterior segment involvement. As demonstrated
in Figure 1, contusion injuries appeared to be
most common in those suffering an assault (16
cases) while IOFB were most common in industrial
injuries (16 cases). Furthermore, we identified
a statistically significant difference in age of
presentation between mode of injury groups (p <
0.01). Post-hoc analysis revealed a higher mean age
at presentation in domestic injuries (54.1 ± 25.0
years) when compared to the sports-related injuries

(33.6 ± 19.4 years, p < 0.01) and industrial injuries
(38.0 ± 12.3 years, p < 0.01).

Surgical Outcomes

The number of operations required varied from one
to five with a mean number of 1.8 (±1.0) operations
performed. We identified a statistically significant
difference in the number of operations required
between the BETTS classified types of injury (p
= 0.02). The statistically significant difference was
found when comparing the number of operations
required for contusion injury, mean 1.51 (±0.91) with
IOFB injury, mean 2.28 (±1.24, p = 0.02), which are
also the groups with respectively the smallest and
biggest average numbers of surgeries performed
per BETTS group.

In our cohort, on follow-up, an improvement from
presenting visual acuity was noted in 73 patients
(66%); however, 25 patients (23%) were found
to have a deterioration in visual acuity, while 12
patients (11%) were found to have no change.

Furthermore, the mean preoperative visual
acuity in our cohort was 1.73 (±0.86) LogMAR which
was noted to improve postoperatively to a mean of
1.17 (±1.03; p < 0.01) LogMAR.

Overall, all BETTS groups were noted to
have improvement in final visual acuity, with
the only exception of perforating group [Table
2]. Interestingly, as demonstrated in Figure 2,
a statistically significant difference in final visual
acuity was noted between BETTS classified type of
injury groups (p < 0.01). Post-hoc analysis revealed
that final visual acuity was statistically significantly
better in the contusion group 0.92 (±0.91) LogMAR
compared to the rupture group 1.68 (±1.08, p =
0.02) LogMAR. Visual acuity was also found to be
better in the IOFB group 0.78 (±0.92) LogMAR
when compared to the penetrating group 1.55
(±1.00, p = 0.05) LogMAR and rupture group (p =
0.01).

Patients who underwent PPV in our study
required gas, oil, or no tamponade. Gases used
include SF6, C2F6, C3F8, and Air. Oil tamponade
was found to be most commonly used in all BETTS
groups 43.6% (n = 48) except contusion, followed
by gas tamponade 30.9% (n = 34). PPV without
tamponade was least commonly performed 25.5%
(n = 28). Best final visual acuity was found in a
group with no tamponade 0.63 (±0.84) LogMAR,
followed by gas tamponade 0.81 (±0.90) LogMAR.

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Vitreoretinal Surgery for Ocular Trauma; Bober et al

Figure 1. Histograms showing BETTS classified type of injury in each mode of injury. This demonstrates increased frequency of
contusion injuries in those suffering an assault and an increased incidence of intraocular foreign bodies in industrial injuries.

Figure 2. Combined stacked scatterplots and box plots of final visual acuity outcomes in each BETTS classified type of injury.
Shown are stacked scatterplots and box plots for contusion injuries (45 eyes), intraocular foreign bodies (25 eyes), penetrating
injuries (18 eyes), perforating injuries (3 eyes), and globe rupture (19 eyes). Box plots with box spanning interquartile range with
maximum and minimum values (excluding outliers) are provided. Black and blue lines represent median and mean, respectively.

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Vitreoretinal Surgery for Ocular Trauma; Bober et al

Table 1. Demographics showing number of patients and age (mean and standard deviation) for each mode of injury

Mode of injury Number of patients Mean age Standard deviation

Assault 35 41.3 15.0

Domestic 25 54.1 25.0

Industrial 33 38.0 12.3

Road traffic accident 6 49.5 19.0

Sport 14 33.6 19.4

Total 113 42.7 18.8

Table 2. Initial pre-op and final post-op visual acuity with overall visual acuity change in different BETTS groups (mean and
standard deviation)[LogMAR]

Cause of PPV Pre-op VA (Mean ±±± SD) [LogMAR] Post-op VA (Mean ±±± SD) [LogMAR] VA change
Contusion 1.52 ± 0.85 0.92 ± 0.91 0.60 ± 0.19
IOFB 1.40 ± 1.01 0.78 ± 0.92 0.62 ± 0.27
Penetrating 1.95 ± 0.67 1.55 ± 1.00 0.40 ± 0.28
Perforating 2.43 ± 0.29 2.70 ± 0.35 –0.27 ± 0.26
Rupture 2.03 ± 0.59 1.68 ± 1.08 0.35 ± 0.28

PPV, pars plana vitrectomy; IOFB, intraocular foreign body; VA, visual acuity; LogMAR, logarithm minimum angle of resolution;
SD, standard deviation

As expected, oil tamponade was associated with
the worst final visual acuity 1.70 (±0.97) LogMAR
[Table 3].

In our cohort, eight patients (7.3%) developed
phthisis during their follow-up, with associated poor
visual outcomes (with documented visual acuity
ranging from hand movement to no LP). Out of all
eight patients, three noted no change and five had
visual deterioration. Furthermore, of the phthisis
cases, four patients presented with ocular rupture –
three with perforating injury and one in IOFB injury,
as per the BETTS classification system. Retinal
detachment persisted in nine patients (8.2%) with
results of visual acuity improvement in one patient,
no change in three patients, and deterioration in
five patients.

A multiple regression analysis was run to predict
final VA from age, gender, initial visual acuity, and
type of ocular injury. Presenting VA (p < 0.01) and
type of ocular injury (p = 0.046) were identified as
statistically significant in predicting final VA.

DISCUSSION

Ocular trauma is known to be an important cause
of visual loss with varying groups investigating

ocular trauma in different countries in different
settings.[5, 6, 16] In this study, we investigated both
cross-sectional and longitudinal data in a large
cohort of patients presenting with ocular trauma to
a large tertiary referral center in London, UK.

We identified men to have a statistically
significantly increased risk of ocular trauma,
in keeping with multiple other studies.[3, 5, 10, 16]
Furthermore, we identified a novel finding of
assault as the commonest cause of ocular
trauma in our cohort. Assault has previously
been described as a risk factor for poor visual
outcomes.[17] While other groups have identified
home[3] and workplace[6] as common locations,
little has been known about the nature of ocular
trauma outside of a conflict setting.[10] Similarly,
we also identified sports-related ocular injury to
be more common in younger patients. This further
emphasizes the importance of education on eye
protection during sporting activities.

Through investigating outcomes using the
BETTS classification,[12] we identified contusion
injuries to be the most common, and furthermore
required the least number of operations, achieving
a statistically significantly better final visual acuity,
when compared to the rupture group. Contusion
injuries by definition do not have a full-thickness

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Vitreoretinal Surgery for Ocular Trauma; Bober et al

Table 3. Frequency of different types of tamponade use in BETTS groups with overall final visual acuity[LogMAR]

Cause of PPV Percentage requiring
gas tamponade

Percentage requiring
oil tamponade

Percentage requiring
no tamponade

Mean final visual
acuity [LogMAR]

Contusion 37.8% (n = 17) 28.9% (n = 13) 33.3% (n = 15) 0.92 ± 0.91
IOFB 28.0% (n = 7) 52.0% (n = 13) 20.0% (n = 5) 0.78 ± 0.92
Penetrating 33.3% (n = 6) 50.0% (n = 9) 16.7% (n = 3) 1.55 ± 1.00
Perforating 0% 100% (n = 3) 0% 2.70 ± 0.35
Rupture 10.5% (n = 2) 63.2% (n = 12) 26.3% (n = 5) 1.68 ± 1.08
Overall 30.9% (n = 32) 43.6% (n = 50) 25.5% (n = 28)

Mean final visual acuity 0.81 ± 0.90 1.70 ± 0.97 0.63 ± 0.84

IOFB, intraocular foreign body; LogMAR, logarithm minimum angle of resolution

ocular wound, and as such they would be expected
to have a better prognosis.

Furthermore, we identified a guarded
improvement in visual acuity following PPV for
ocular trauma with improvement or stability of
visual acuity noted in 66% of patients and an
improvement from 1.73 (±0.86) LogMAR to 1.17
(±1.03; p < 0.01) LogMAR. The improvement was
noted in all BETTS groups with the only exception
of perforating group. While this does demonstrate
a statistically significant improvement in visual
acuity, it also highlights the guarded prognosis of
final visual acuity for PPV following ocular trauma.

Notably, other groups have demonstrated similar
improvements following PPV, albeit with different
cohorts to ours. Mansouri et al described an
improvement from 2.36 (±0.72) LogMAR to 1.50
(±1.14) LogMAR following PPV in a smaller cohort (n
= 90) in Iran.[6] Furthermore, Guven et al described
a statistically significant improvement in 337 out of
their cohort of 633 patients who underwent PPV
following ocular trauma.[10] However, it should also
be noted that a large proportion (48.2%) of patients
in this cohort had terror-related open globe injury,
making it difficult to compare their findings with
those of this study. Interestingly, Xia et al also
describe an improvement in visual acuity from
2.20 (±0.63) LogMAR to 1.87 (±0.60) LogMAR in a
longitudinal American cohort of 96 eyes, similar to
ours.[16]

Overall, oil tamponade was the most commonly
chosen agent and that group had worst final
visual acuity 1.70 (±0.97) LogMAR; however, the
reason for this was most likely the type and
severity of ocular injury, with the need for a longer
acting tamponade. Therefore, in our study, type

of tamponade cannot be used as a prognostic
factor on its own. Similarly, Jiang et al concluded
that use of silicone oil did not affect the visual
acuity prognosis but the severity of presentation,
in that case traumatic endophthalmitis, was the
main factor determining the appropriate choice
of treatment.[18] Vaziri et al concluded that the
type of tamponade used should be individualized
according to the characteristics of the patient and
medical presentation.[19]

Additionally, only 8 and 9 patients out of 110
patients followed-up developed phthisis and a
persisting retinal detachment, respectively, at the
final visit. Furthermore, there was a wide variation
of one to five surgeries required for patients with
ocular trauma in our cohort, with a mean of 1.8 (±1.0)
operations similar to other cohorts.[16] Furthermore,
we identified that presenting VA (p < 0.01) and
type of ocular injury (p = 0.05) as prognostic
indicators for final VA again suggesting that those
with less severe injuries on presentation have a
better prognosis. Indeed, initial VA was shown as
an important prognostic factors in multiple previous
studies.[5, 10, 20, 21]

There are, however, limitations to our study.
We were unable to investigate the presence of
endophthalmitis, presence of afferent pupillary
defect and zone of injury (as previously explored
by the OTS), and the impact of this on surgical
outcome. Secondly, our study does not involve
information on the timing of the PPV. Currently,
there are no clear guidelines concerning the
optimal timing of surgery. According to Ryan
et al and Brinton et al, patients that underwent
vitrectomy within first 14 days after presentation
seemed to have better visual outcomes than those

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Vitreoretinal Surgery for Ocular Trauma; Bober et al

who had to wait longer.[22, 23] However, others
argue the timing of vitrectomy is not related to
visual outcomes.[6, 24] For that reason it is difficult
to estimate the effect that timing of the PPV may
have. Additionally, in the contusion group we were
unable to investigate the specific indication for
intervention, and in the IOFB group while all IOFBs
involved the posterior segment, we were unable to
investigate the location within the posterior pole.
What is more, the retrospective nature of the study
can introduce bias due to variability in reporting
clinical findings. Furthermore, as a single-center
study, it is difficult to use our findings to inform
practices in other countries.

In summary, we present a study of prognostic
factors and outcomes of vitreoretinal surgery in
ocular trauma. We demonstrate a varied number of
surgeries required following ocular trauma, visual
acuity improvement following PPV but with a very
guarded prognosis and, as expected, that patients
without a full-thickness laceration have the best
prognosis.

Financial Support and Sponsorship

Nil.

Conflicts of Interest

There are no conflicts of interest.

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