Original Article

A Simple Inner-Stopper Guarded Trephine for Creation
of Uniform Keratectomy Wounds in Rodents

Peter B. Le1,2,#, BS; Fang Chen1,2,#, PhD; David Myung1,2,3, MD, PhD

1Department of Ophthalmology, Stanford University School of Medicine, CA, USA
2VA Palo Alto Health Care System, Palo Alto, CA, USA

3Department of Chemical Engineering, Stanford University, CA, USA

ORCID:
Peter Le: https://orcid.org/0000-0002-1932-9995

Fang Chen: https://orcid.org/0000-0002-6675-5508
David Myung: https://orcid.org/0000-0002-7980-3070

Abstract
Purpose: Creating controllable, reproducible keratectomy wounds in rodent corneas can
be a challenge due to their small size, thickness, and the lack of usual tools available for
human eyes such as a vacuum trephine. The purpose of this work is to provide a consistent,
reproducible corneal stromal defect in rats using a simple, economical, and customized inner-
stopper guarded trephine.
Methods: The inner-stopper guarded trephine is used to induce a circular wound in rat
corneas. After trephination, the corneal flap can be removed by manual dissection using
a blunt spatula. We used optical coherence topography (OCT) to measure the defect wound
depth induced in ex vivo rat eyes.
Results: Despite a minor learning curve, this simple device enables depth control, reduces
variability of manual keratectomy wound depth in rats, and decreases the risk for corneal
perforation during keratectomy. Corneal defect creation was highly reproducible across
different researchers and was independent of their surgical training.
Conclusion: This inner-stopper guarded trephine can be utilized and applied to pre-clinical
testing of a wide range of corneal wound healing therapies, including but not limited to
biotherapeutics, corneal prosthetics, and regenerative technologies.

Keywords: Anterior Lamellar Keratoplasty (ALK); Corneal Defect Model; Inner-stopper Guarded
Trephine; Keratectomy; Rat Corneal Wound Model; Trephine Design

J Ophthalmic Vis Res 2021; 16 (4): 544–551

INTRODUCTION

The cornea is the transparent, outermost part of
the eye that is responsible for protecting intraocular

Correspondence to:

David Myung, MD, PhD. 1651 Page Mill Rd. Palo Alto, CA
94304, USA.
E-mail: djmyung@stanford.edu
#These authors contributed equally.
Received: 29-05-2020 Accepted: 01-07-2021

Access this article online

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

DOI: 10.18502/jovr.v16i4.9743

eye structures and focusing light onto the retina.[1]
It is susceptible to exposure-related injuries such
as burns involving chemical, thermal, and radiation
sources, as well as physical trauma.[2] Diseases
and injuries to the cornea result in impaired
vision due to scarring, clouding, thinning, among

This is an open access journal, and articles are distributed under the terms of
the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 License, which
allows others to remix, tweak, and build upon the work non-commercially, as
long as appropriate credit is given and the new creations are licensed under the
identical terms.

How to cite this article: Le PB,# Chen F,# Myung D. A Simple Inner-Stopper
Guarded Trephine for Creation of Uniform Keratectomy Wounds in Rodents.
J Ophthalmic Vis Res 2021;16:544–551.

544 © 2021 LE ET AL. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E

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New Trephine for Rodent Studies; Le et al

others, and in advanced cases, blindness.[3]
Many ongoing therapeutic efforts in corneal
research include the use of pre-clinical animal
models on rodents such as rats.[4, 5] This disease
model can be used to investigate potential
corneal wound healing treatments, such as
cell transplantation, amniotic membranes, fibrin
gel, as well as polymers and biopolymers.[6]
Larger animal models with similar ocular
anatomy to humans have been widely used
to study wound healing in the cornea. We
recently developed a 3D printable modified
trephine that can create consistent anterior
lamellar keratectomy wounds in rabbits.[7] This
trephine was used to create defects to study
the ocular wound-healing effects of novel
in situ forming hydrogels in rabbits.[8–10] The
development of a similar trephine for rats is
equally important because one of the many
advantages of using rodents is the availability
of visual function tests available for rodents,
but not larger animals.[11, 12] Also, the cost for
rat studies are much lower than that of larger
animals. Therefore, rats serve as an important
model for the study of wound healing in the
cornea. The size of their cornea is large enough
to allow for the study of wounds and subsequent
tissue collection and analyses.[13] However, rats
have smaller eyes and their average central
corneal thickness (CCT) is 159 μm,[14] so studying
cornea wound healing in rats involves producing
defects with precision and reproducibility. Thus,
there is a need to develop a reliable system
to create consistent and controlled corneal
defects in rats in a way that minimizes the
risk of corneal perforation. Here, we report
an inner-stopper guarded trephine to create
consistent anterior lamellar keratectomy in
rats.

There are many variables to consider when
deciding on a wound model for studying the
cornea. Some studies require only debridement of
the epithelium, thereby preserving the basement
membrane, while others require wounds that
penetrate the basement membrane and extend
into the stroma.[15–17] The proposed method
will focus on the latter because it allows the
researcher to consistently remove corneal
stromal tissue for studies involving wounds that
penetrate the stroma. Currently, there are several
techniques available to produce anterior wounds
to the corneal stroma. Manual keratectomy

(MK) involves applying and rotating a sharp
trephine or circular biopsy punch to the surface
of the cornea, gradually increasing pressure to
produce a wound and subsequently excising the
corneal flap. Another method, photorefractive
keratectomy (PRK), uses an excimer laser to
ablate corneal tissue. Compared to MK, laser
excimer ablation is more precise and reduces the
variability in the depth of the injury.[18] However,
laser ablation requires extensive training by the
surgeon and has high equipment costs.[19–21]
Alternatively, microkeratomes are another tool
that can be potentially utilized to create a
corneal stromal defect.[22] However, there are
no microkeratomes that currently exist for rats.
Therefore, a method for creating corneal wounds
using manual, mechanical tools would be an
important advance for preclinical research on
small animals.

Of the reported studies involving the need
to model corneal injuries in rats, there is
no systematic model to produce consistent
manual corneal defects. Achieving similar
corneal cut depths across eyes is difficult to
achieve manually. To reliably assay the effects
of therapeutics on corneal wound healing,
confounding variables such as the degree of
corneal deformation during trephination must be
taken into consideration.

Perforation of the cornea results in leakage of
anterior chamber fluid, in which case the globe
and consequently the animal may have to be
euthanized unless the eye is still usable for study
after globe repair with sutures.[23] Accordingly, a
corneal defect that is too superficial and does not
cut deeply enough will likely be repaired by the
animal’s innate wound healing mechanisms rather
than the treatment itself.[24] Therefore, the purpose
of this method is to design a disease model for
a consistently deep but non-perforating stromal
defect in rat corneas.

We developed a handheld trephine with an
inner stopper that allows for reproducible corneal
stromal defects in rat eyes. After the trephination,
we performed keratectomies on ex vivo rat corneas
with a blunt spatula and imaged them using optical
coherence topography (OCT). We quantified the
depth of the excised rat cornea using OCT stromal
thickness measurements and demonstrated that
the device and protocol can be used to produce
defects of consistent depth in rats between
different users.

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New Trephine for Rodent Studies; Le et al

METHODS

No live rats were operated on for the data collection
that supports the use of this method. However,
if the techniques described in this paper are to
be used in vivo, then researchers should abide
with the ARVO statement for the Use of Animals in
Ophthalmic and Vision Research.

Rat eyeballs were purchased from Vision Tech
(Sunnyvale, Texas, USA) and Pel-Freeze Biologicals
(Rogers, AR, USA). 2 mm biopsy punches (RBP-20)
were purchased from Robbins Instruments, Inc.
(Sunnyvale, CA, USA). Ring forceps (11106-09),
micro spatula (10089-11), and fine-point surgical
forceps (11445-12) were purchased from Fine
Science Tools (Foster City, CA, USA). Teflon
polytetrafluoroethylene (PTFE) sheets, 0.127
mm (8569K16) and 2.38 mm (8545K14), were
purchased from McMaster-Carr (Elmhurst, IL, USA)

Creating the Inner-stopper Guarded Trephine

Use a 2 mm biopsy punch to punch a piece of 2.38
mm thick Teflon sheet. This piece of Teflon sheet
is used as the inner stopper. Use the same 2 mm
biopsy punch in the previous step to punch a piece
of Teflon sheet that is 127 µm thick. This thinner
piece of Teflon sheet is used as the trephination
depth calibrator. Note that this second piece of
Teflon can be adjusted to a thickness equal to the
desired depth of the corneal defect. Transfer and
insert the two Teflon sheets into a new 2 mm biopsy
with the inner stopper sheet further away from the
blade and the calibrator sheet closer to the blade.
Refrain from denting the new 2 mm biopsy punch
to keep the blade sharp. Using a blunt needle, push
the Teflon sheets from the posterior end of the
trephine until two sheets are contacting closely and
the calibrator sheet is flush with the edge of the
blade. Apply a few drops of cyanoacrylate to the
posterior end of the trephine to keep the stopper
sheet in place. Remove the calibrator sheet from
the anterior of trephine.

Performing the Keratectomy

Using the inner-stopper guarded trephine, begin
by preparing the ex vivo rat eyeball or animal for
aseptic surgery. Place the inner-stopper guarded
trephine on the center of the rat cornea. Press
the trephine blade toward the cornea. A dent will

form on the cornea without cutting into the corneal
stromal tissue. Rotate the trephine in one direction
(either clockwise or counter-clockwise) for at least
90°, and then rotate again in the other direction for
90°. Repeating the rotation multiple times will allow
the blade cut into corneal stroma. Discontinue
rotation when the trephine blade does not go into
the stroma any deeper. Gently pull out the trephine
from the eye.

Removing the Stromal Tissue

To remove the layer of anterior stroma after
trephination, lift the flap of the incised cornea at
one end using fine-point surgical forceps under
a bright-field microscope. Use an angled blunt
spatula to dissect the stromal tissue along a
lamellar plane on the posterior edge of the
trephination. Continue the dissection process with
careful, fine sweeping motions along the plane until
the flap is completely detached from the cornea.
Remove and discard the excised cornea.

Data Analysis

After the keratectomies were performed, anterior
segment OCT was used to image the eyes. The
OCT images of the cornea were then analyzed
by Image J to measure the depth of the cut. The
depth of the cut was analyzed by measuring the
thickness of the wounded cornea and the adjacent
intact cornea. The percentage of excised cornea
was calculated based on these two measurements
by the following:

(thickness of intact cornea – thickness of
wounded cornea) / thickness of intact cornea × 100.

Statistical Analysis

Means, standard deviations, and p-values were
calculated in Microsoft Excel 2016. Significance
was determined using a two-tailed Student’s t-
test, and p-values < 0.05 were considered to
be significant. Pearson’s coefficient was calculated
using the PEARSON function in Microsoft Excel
2016.

RESULTS

Figure 1 illustrates the sagittal cross-section of
the inner-stopper guarded trephine. The 2.38 mm

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New Trephine for Rodent Studies; Le et al

measurement refers to the inner stopper. The
0.13 mm measurement represents the trephination
depth calibrator that is removed during the
assembly of the trephine.

OCT images in Figure 2 show the range of defect
depths possible by this method, from shallow
(approximately 20%) to deep (approximately 80%).
Panel A shows an intermediate defect, whereas
panel B shows a deeper defect and near-
perforation of the cornea. Panel C shows a more
superficial defect and panel D shows a photo of the
ex vivo rat eyeball after introducing the defect.

The degree of defect, represented by the
percentage of excised cornea, were graphed
alongside the diameter and weight of the rat
eyeballs. Figure 3 shows the linear relationship
between these measurements and the defects
produced by the inner-stopper guarded trephine.
The weight (Pearson’s r = 0.0665) and diameter
(Pearson’s r = 0.1206) of the rat eyes had a weak
positive correlation with the percentage of excised
cornea.

Figure 4 shows the consistency of the corneal
defect depth between two different users. User two
had about one month of keratectomy experience,
compared to user one who had six months
of keratectomy experience. On average, user
one used the inner-stopper trephine to cut
approximately 56.5% of the cornea with a standard
deviation of 12.4%. Out of twenty-six eyes, two
were perforated and discarded (7.7% perforation).
The relative standard deviation for the percentage
of corneal stromal tissue excised was 21.9%. The
minimum percentage was found to be 33.8% and
the maximum was 81.7%.

User two cut approximately 57.4% of the
cornea with a standard deviation of 15.2%. The
relative standard deviation for the percentage
of cornea cut was 26.4%. The minimum defect
was 20.9% and the maximum was 80.5%. Out
of the 24 eyes, user two perforated 5 eyes.
There was no significant difference between the
values for weight (p = 0.7218), diameter (p =
0.6842), and percentage of cornea excised (p =
0.8569) between the two users, indicating that the
procedure is consistent between the two users.
The perpendicularity of the stromal defects were
also objectively measured. On average, user one
created defects that had an angle of 135.7°, with
a standard deviation of 32.7. User two created
defects that had an angle of 136.7°, with a

standard deviation of 22.9. While this is less than
ideal for the use of corneal transplantation and
donor-recipient matching, this method nonetheless
creates substantial stromal defects that can be
filled with in situ forming hydrogels similar to what
can be done in rabbits.[8–10]

Figure 5 shows an OCT image of the application
of an in situ forming hydrogel to a corneal defect
introduced by the described method.

DISCUSSION

In many cases, keratectomies performed in rat
models are irregular and vary significantly between
different cornea samples. The protocol in this
study describes a simple modification of a trephine
that produces a relatively consistent corneal
keratectomy wounds in rats.

When using the trephine, it is critical to ensure
that the circular blade of the trephine is positioned
over the center of the eye. If not centered, the
size of the defect will be less accurate due to the
changing corneal thickness that is dependent on
the location where the trephine is placed on the
cornea.[11] Because rat corneas are considerably
thinner than those of other larger animal models,
there is a much decreased margin for error and
greater risk of perforation. Another vital aspect of
performing the keratectomy is to take advantage
of the shear stress of the trephine blade by
using extensive rotation and avoiding excess
perpendicular pressure to the cornea, which can
also result in perforation.

In the beginning stages of using this method,
there may be difficulty in producing incisions in the
cornea. One major complication is that the blade
may glide along the surface of the cornea when
one is trying to make an incision. To avoid this, the
surgeon could attempt to gently pat the surface
of the cornea with a tissue or sterile cotton swab.
When performing the keratectomy, the eye should
be immobilized. Any movement of the eyeball will
reduce the amount of force imposed on the circular
defect and potentially cause the trephine to glide
along the surface of the cornea and scrape the
surrounding layer of epithelial cells. For animal
surgery, globe movement can be restricted by
using ring forceps.

This simple trephine modification allows for
the creation of uniform corneal defects between
animals to study corneal wound healing in a very

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New Trephine for Rodent Studies; Le et al

Figure 1. Schematic representation and illustration of the inner stopper guarded trephine.

cost-effective way. Once the defects are created,
researchers can attempt to treat the wound using
various methods and analyze wound healing
clinically and histopathologically without worrying
about wound uniformity between surgeries and
between surgeons. In rat eyes, the trephine seems
to create oblique defects rather than perpendicular
defects. We propose that this is due to the
biomechanics, small size, and high curvature of
the rat cornea. After the trephine is inserted to
cut the stroma and removed, the elasticity of
the now substantially thinned cornea may have
caused some of the tissue to move back toward
the center of the defect. Additionally, the high
curvature of the rat cornea makes it more difficult
for the trephine to cut a perpendicular angle
in the stroma. Despite this difficulty to create
perpendicular defects, this method is still useful
to study therapies that can conform to the shape
of the defect, such as hydrogels. We found in our
prior published work that wound perpendicularity
could be achieved reliably in rabbits, which
have substantially thicker corneas with different
biomechanical properties and lower curvature
compared to those of rats.[7] Compared to other
methods such as mechanical keratectomy, excimer
laser ablation, and microkeratomes, using an inner-
stopper guarded trephine is more economical and
simpler to use. For studies involving larger animal
models, the protocol to create the inner-stopper
trephine can be modified and replicated by using

a larger biopsy punch to create a circular incision
with a larger diameter.

In summary, we reported a simply designed
inner-stopper guarded trephine-based protocol
for producing consistent stromal defects in rat
corneas, which is critical to study the effects of
various therapeutics on corneal wound healing in
a rat model. The inner stopper is essential for
controlling the trephination depth.

Financial Support and Sponsorship

The authors would like to acknowledge the support
from the National Institutes of Health (National
Eye Institute K08EY028176 and a Departmental
P30-EY026877 core grant), the Stanford SPARK
Translational Research Grant and Maternal &
Child Health Research Institute (MCHRI) (D.M.), the
core grant and Career Development Award from
Research to Prevent Blindness (RPB), the Matilda
Ziegler Foundation, the VA Rehabilitation Research
and Development Small Projects in Rehabilitation
Effectiveness (Spire) program (I21 RX003179), and
the Byers Eye Institute at Stanford.

Acknowledgements

The authors thank David Buickians for providing
the illustration of the inner-stopper guarded
trephine.

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New Trephine for Rodent Studies; Le et al

Figure 2. Optical coherence tomography (OCT) of the rat corneas after ALK. (A) Intermediate defect of the cornea. (B) Deep defect
of the cornea. (C) Superficial defect of the cornea. (D) Rat eyeball after ALK with the inner-stopper guarded trephine.

Figure 3. Correlations between the diameter (A) and weight (B) of the eyes and the percentage of cornea excised by the inner-
stopper guarded trephine. The linear dependence was considered weak when the Pearson’s r value is below 0.2.

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New Trephine for Rodent Studies; Le et al

Figure 4. Comparison of corneal defects created by the inner-stopper guarded trephine by two users with different keratectomy
experiences. User one had six months of experience in performing keratectomies and User two had one month of experience.
There was no significant difference in the percentage of cornea excised between the two users.

Figure 5. OCT image of a rat corneal defect filled in with a novel in situ forming therapeutic hydrogel.

Conflicts of Interest

None.

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