Original Article

Amniotic Membrane Transplantation for Persistent
Epithelial Defects and Ulceration due to Pseudomonas

Keratitis in a Rabbit Model

Mohammad Mehdi Soltan Dallal1,2, PhD; Farhad Nikkhahi3, PhD; Seyed Mostafa Imeni4, PhD
Saber Molaei5, MD; Seyed Kazem Hosseini6, MS; Zohreh Kalafi2, MS; Sara Sharifi Yazdi7, MD

Hedroosha Molla Agha Mirzaei8, MS

1Division of Microbiology, Department of Pathobiology, School of Public Health, Tehran University of Medical Sciences (TUMS),
Tehran, Iran

2Food Microbiology Research Center, Tehran University of Medical Sciences, Tehran, Iran
3Medical Microbiology Research Center, Qazvin University of Medical Science, Qazvin, Iran

4Biodiversitat, Ecología, Technologia Ambiental i Alimentaria )BETA Tech Center(, (TECNIO Network), U Science Tech,
University of Vic-Central University of Catalonia, Carrer de la Laura 13, 08500 Vic, Spain

5AJA University of Medical Sciences, Tehran, Iran
6Quality Control Manager of Iranian Tissue Bank Research & Preparation Center, Director of Stem Cells Preparation Unit,

Tehran University of Medical Sciences, Tehran, Iran
7School of Medicine, Tehran University of Medical Sciences (TUMS), Tehran, Iran

8Food Microbiology Research Center, Tehran University of Medical Sciences, Tehran, Iran

ORCID:
Mohammad Mehdi Soltan Dallal: https://orcid.org/0000-0002-3421-3974

Abstract

Purpose: The use of amniotic membrane has been suggested in the treatment of
infectious keratitis for its intrinsic anti-infective properties probably mediated by its anti-
inflammatory effects. The aim of this study was to investigate the effect of amniotic
membrane transplantation (AMT) along with ciprofloxacin to cure the primary stages of
Pseudomonas keratitis.
Methods: In total, 28 rabbits were selected and divided in four groups as follows: group
1 as control, group 2 with amniotic membrane, group 3 with ciprofloxacin, and group
4 with amniotic membrane combined with ciprofloxacin. About 0.05 cc suspension of
Pseudomonas aeruginosa, 27853 ATCC was injected into corneal stroma.
Results: The results showed groups of AMT, AMT + ciprofloxacin, and ciprofloxacin had
0% perforation while the control group had 85.6%. Average infiltration of 5.5 mm was
observed in ciprofloxacin group, 5 mm in AMT + ciprofloxacin group, 24 mm in AMT
group, and finally 23.75 mm for control. Amniotic membrane showed to be effective
in prevention of cornea perforation as well as remission of Pseudomonas keratitis.
There was no significant difference between ciprofloxacin groups in comparison with
ciprofloxacin + AMT group. However, regarding the anti-inflammatory effect, the process
of improvement of inflammation in ciprofloxacin + AMT group was faster.
Conclusion: Transplantation of amniotic membrane in the primary stages of
Pseudomonas keratitis treatment remarkably prevents the disease and it can be used
to control its process.

Keywords: Ciprofloxacin; Human Amniotic Membrane; Keratitis; Pseudomonas aeruginosa; Rabbit

J Ophthalmic Vis Res 2021; 16 (4): 552–557

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AMT for Rabbit Model of Keratitis; Soltan Dallal et al

INTRODUCTION

Human amniotic membrane (AM) forms the inner
wall of the membranous sac that surrounds
and protects the embryo during gestation.
It consists of a single layer of ectodermally
derived columnar epithelial cells attached to
a basement membrane with an underlying
layer of mesenchyme.[1] Amniotic membrane
transplantation (AMT) is widely used in various
ocular surface diseases such as neurotrophic
keratitis and persistent epithelial defects,[2, 3]
band keratopathy,[4] bullous keratopathy,[5, 6] after
excimer laser photorefractive keratectomy,[7, 8]
after the excision of a conjunctival mass,[9, 10]
pterygium,[11, 12] ocular surface reconstruction in
symblepharon,[13, 14] acute chemical injury,[15, 16]
and a chronic limbal deficiency.[17, 18] When used
as a graft (epithelial side up), AM is expected
to become incorporated in the recipient tissue.
If it is used as a patch (epithelial side down),
it works as a biological bandage affording a
cover for a limited duration or a combination of
these. The use of AM has been also suggested
in the treatment of infectious keratitis because
of its intrinsic anti-infective properties probably
mediated by its anti-inflammatory effects and
because AM may act as a long-term drug delivery
system.[19–21] The antimicrobial effects of AM
have been demonstrated against several species
such as Escherichia coli, Group A Streptococci,
Pseudomonas aeruginosa, and Staphylococcus
aureus.[22, 23] AM graft for epithelial reformation
has been employed in order to eradicate the P.
aeruginosa infection of keratitis and have exhibited
desirable outcomes.[24]

The aim of the current study was to investigate
the effect of AMT along with ciprofloxacin to cure
the primary stages of Pseudomonas keratitis.

Correspondence to:

Mohammad Mehdi Soltan Dallal, PhD. Food
Microbiology Research Center (FMRC)/Division of
Food Microbiology, Department of Pathobiology,
School of Public Health, Tehran University of Medical
Sciences (TUMS), Tehran 6446-14155, Iran.
E-mail: soltanda@sina.tums.ac.ir/
msoltandallal@gmail.com
Received: 13-11-2020 Accepted: 21-05-2021

Access this article online

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

DOI: 10.18502/jovr.v16i4.9744

METHODS

All experiments were carried out in accordance
with the UK Animals (Scientific Procedures) Act,
1986 and associated guidelines, EU Directive
2010/63/EU for animal experiments. In addition,
this study is certified by accreditation research
ethics national committee with issue code of
IR.TUMS.REC.1394.2091.

In total, 28 male rabbits with an average weight
of 1.5–2 kg were selected. The AM was prepared
according to Song and Kim method.[25] Human
placenta was obtained after an elective caesarean
section in a woman who was seronegative for
human immunodeficiency virus, hepatitis B, C, and
syphilis. Under a lamellar flow hood, the placenta
was first washed free of blood clots with sterile
saline. The inner AM was separated from the rest
of the chorine by blunt dissection and flattened
onto a nitrocellulose membrane.[26] The membrane
with the filter was then washed three times with
phosphate buffered saline (PBS) containing 50
μg/ml penicillin, 50 μg/ml streptomycin, and 2.5
μg/ml amphotericin B and put in M199 culture for 24
hr with antibiotic solution including streptomycin,
cloxacillin, ceftriaxone, and amphotericin B, and
finally packed in pieces of 1.5×1.5 in three of
sterilized nylon and stored in –80ºC in freezer.
Twenty-eight rabbits were divided into four groups
as follows: group 1 as control group [Figure 1A],
group 2 as AM [Figure 1-B], group 3 as ciprofloxacin
[Figure 1C], and group 4 as AM combined with
ciprofloxacin [Figure 1D].

The rabbits were anesthetized with
intramuscular injection of ketamine hydrochloride
(30 mg/kg) and xylazine hydrochloride (5 mg/kg)
and then a drop of tetracaine HCL 0.5% was
applied to the rabbits’ right eye. About 0.05 cc
suspension of P. aeruginosa 27853 ATCC was
injected into corneal stroma with a sterile 30 G
needle connected to a micro-syringe, using an
operating microscope. The experimental keratitis
was allowed to proceed untreated for 20 hr. There

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How to cite this article: Soltan Dallal MM, Nikkhahi F, Imeni SM, Molaei
S, Hosseini SK, Kalafi Z, Yazdi SS, Mirzaei HMA. Amniotic Membrane
Transplantation for Persistent Epithelial Defects and Ulceration due
to Pseudomonas Keratitis in a Rabbit Model. J Ophthalmic Vis Res
2021;16:552–557.

JOURNAL OF OPHTHALMIC AND VISION RESEARCH VOLUME 16, ISSUE 4, OCTOBER-DECEMBER 2021 553

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


AMT for Rabbit Model of Keratitis; Soltan Dallal et al

was no interference in the control group. In groups
3 and 4, the AM in pieces of 1.5×1.5 cm transplanted
to the entire corneal surface by eight interrupted
10.0 nylon sutures. On the first day, ciprofloxacin
drop was injected to groups 2 and 4 every 30 min.

On the second day to seventh day every 2 hr,
the results were registered in aspect of perforation
in cornea and the amount of infiltration by the use
of image J 1 software.

RESULTS

Results were registered as clinical reports on the
first, third, and seventh day [Table 1]. During the
first 20 hr, after injecting P. aeruginosa, a white
opacity appeared in all rabbits. Rabbits had corneal
ulcers and on the second day, the conjunctiva was
markedly hyperemic in four groups. At the end of
the first week, Hypopyon formation was noticed in
five eyes in the AMT group. Corneal perforation
was noticed in four cases in the control group but
in no case in other groups.

The results showed that the cornea had
infiltration in which central part, an area with
the size of 6 mm had descemeto cell and progress
toward causing perforation in cornea control group
(A: Control group). On the other hand, AMT group
conjunctiva inflammation showed to be less than
control group and in cornea examination the
amount of infiltration showed to be 24 mm (B:
AMT group). For ciprofloxacin group, ciprofloxacin
sediment was clearly visible (C: ciprofloxacin) and
finally in the group with ciprofloxacin + AMT as well
as the ciprofloxacin group the decrease of opacity
cornea was quite visible (D: AMT + ciprofloxacin).

The clinical results of four groups in examination
of Pseudomonas keratitis are also shown in Table
2. These results showed that AMT + ciprofloxacin
group had 0% perforation and the control group
had 85.7%. Average infiltrations were 5 mm in AMT
+ ciprofloxacin groups and 23.75 mm in control.

The result showed that the AMT, ciprofloxacin,
and AMT + ciprofloxacin were effective on
perforation and infiltration on all groups compared
to the control group.

In addition, there was no significant difference
between ciprofloxacin group and ciprofloxacin
combination with AM. In the same way, there
was no significant difference between membrane
amniotic group and ciprofloxacin compared with
combined group of ciprofloxacin with membrane
amniotic.

DISCUSSION

Few studies have investigated the effect of AMT in
the surgical treatment of severe infectious keratitis
with corneal ulceration or perforation.[19, 23, 27]
The main advantages of AMT in the treatment
of bacterial keratitis that we observed are the
epithelial bandage properties, which allowed early
use of topical steroids; the anti-inflammatory and
anti-scarring effects of the AM, the promotion
of epithelialization, and the possible benefits
of a direct antimicrobial role of the AM.[28]
These studies found AMT to be effective in
treating neurotrophic ulcer, inflammatory corneal
ulcer, bullous keratopathy, inflammatory or non-
inflammatory scleral ulcer and as an adjuvant
treatment of pterygium excision. The basement
membrane of an AM promotes epithelial growth
and differentiation, reinforces the adhesion of
basal epithelial cells and prevents epithelial
apoptosis. The stroma matrix suppresses TGF-
b signaling, proliferation, and myofibroblastic
differentiation of normal human corneal and limbal
fibroblasts and thus, inhibiting the unwanted
production of extracellular matrix and scarring.[6]
These properties have made the AM an ideal
reconstructive substrate for repairing persistent
epithelial defects and corneal ulcers,[2] conjunctival
defect,[9, 10] chemical or thermal injury,[15, 29] and
limbal cell deficiency.[16, 17] The application of
AM in the treatment of corneal perforation and
scleromalacia has been also reported.[30, 31]
The human AM possesses anti-inflammatory,
antifibrotic, and antiangiogenic properties, and
these attributes make it ideal for ocular surface
reconstruction procedures.[32, 33] In addition,
the AM also has antimicrobial properties due
partly to its anti-inflammatory effects, and
also due to secretion of elfin and secretory
leucocyte proteinase inhibitor, both of which have
antimicrobial actions and act as components of
the innate immune system.[34, 35] It also contains
cystatin E, an analogue of cysteine proteinase
inhibitors, which has complementary antiviral
properties.[36] Furthermore, AM transplantation
(AMT) is reserved for cases of postinfectious
ulcers after an appropriate period of anti-infective
treatment when clinical signs are improving.[37]
This is because the anti-infective properties of
AM are nonspecific and not considered to be
potent enough to be effective in acute infective
keratitis. This is the reason behind the concept

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AMT for Rabbit Model of Keratitis; Soltan Dallal et al

 

Figure 1. Cornea infiltration of the four groups of experiment. (A: Control group; B: AMT group; C: ciprofloxacin; D: AMT +
ciprofloxacin).

Table 1. Clinical results of four groups on the first, third, and seventh day and in the first 20 hr*

Groups/days First day Third day Seventh day

Control Average infiltration 2.25 mm with
corneal opacity and without

epithelial defect

Average infiltration 7.01 mm with
corneal opacity, epithelial defect,

and descemeto cell

Average infiltration 23.75 mm
with corneal opacity and

epithelial defect

AMT Average infiltration 2.62 mm and
without epithelial defect

Average infiltration 6.25 mm and
without epithelial defect

Average infiltration 24 mm and
without epithelial defect, melting,

and scar

ciprofloxacin Average infiltration 2.35 mm and
without epithelial defect

Average infiltration 4.51 mm and
epithelial defect

Average infiltration 5.5 mm,
epithelial defect, and scar with

diameter 2.5×2.5 mm
ciprofloxacin + AMT Average infiltration 2.6 mm and

without epithelial defect
Average infiltration 4 mm and

without epithelial defect
Average infiltration 5 mm and

without epithelial defect and scar

*Findings in the first 20 hours only the first day for all groups
**AMT, amniotic membrane transplantation

of fortifying AM with antimicrobial drugs to make
it a viable therapeutic modality in the setting
of active infections of the cornea. Antibiotic-
impregnated medical devices such as catheters,
bone and cardiac implants have been in use
for over a decade.[22, 38] Various studies have

shown the potential of such an approach, for
example, in vascular surgery and arthroplasty,
where they appear effective in reducing the risk
of bloodstream infections or in limiting deep
wound infections.[39, 40] AM is effective in remission
of Pseudomonas keratitis and prevention of

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AMT for Rabbit Model of Keratitis; Soltan Dallal et al

Table 2. Clinical outcomes of perforation and infiltration in all four groups of Pseudomonas keratitis

Results AMT* AMT + ciprofloxacin ciprofloxacin Control

Perforation (0%) 0 (0%) 0 (0%) 0 (85.7%) 6

Infiltration 24 mm 5 mm 5.5 mm 23.75 mm

Significant difference compared to
control group (P-value)

P < 0.5 P < 0.5 P < 0.5 –

*AMT, amniotic membrane transplantation

cornea perforation and controlling as well as anti-
Pseudomonas effects. There was no difference
between ciprofloxacin group in comparison
with ciprofloxacin + AMT group. However,
regarding anti-inflammatory effects, the process
of improvement of inflammation in ciprofloxacin +
AMT group was faster. During this research, we
came to conclusion that transplantation of AM
in the primary stages of Pseudomonas keratitis
treatment remarkably prevents the disease and it
can be used to control its process.

Acknowledgements

This work was supported by a Vice-Chancellor
for Research grant (no. 10793) and approved
by the Committee for Research Ethics
(no.IR.TUMS.RES.1394.2091) of Tehran University
of Medical Sciences (Tehran, Iran).

Financial Support and Sponsorship

Nil.

Conflicts of Interest

There are no conflicts of interest.

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