Original Article

Changes in Corneal Asphericity after MyoRing
Implantation in Moderate and Severe Keratoconus

Masoud Khorrami-Nejad1, MS; Ozra Aghili1, MS; Hesam Hashemian2, MD; Mohamad Aghazadeh-Amiri1, OD
Farshid Karimi1, MS

1Department of Optometry, School of Rehabilitation, Shahid Beheshti University of Medical Sciences, Tehran, Iran
2Eye Research center, Farabi Eye Hospital, Tehran University of Medical Sciences, Tehran, Iran

ORCID:
Masoud Khorrami-Nejad: https://orcid.org/0000-0002-8270-9704

Hasan Hashemian: https://orcid.org/0000-0003-0836-8937

Abstract

Purpose: To evaluate the effect of MyoRing implantation on corneal asphericity in moderate and severe
keratoconus (KCN).
Methods: This cross-sectional observational study comprised 32 eyes of 28 patients with KCN, who had
femtosecond-assisted MyoRing corneal implantation. The primary outcome measures were preoperative
and six-month postoperative corneal asphericity in 6-, 7-, 8-, 9-, and 10-mm optical zones in the superior,
inferior, nasal, temporal, and central areas. The secondary outcome measures included uncorrected
distance visual acuity (UDVA), corrected distance visual acuity (CDVA), manifest refraction, thinnest location
value, and keratometry readings.
Results: A significant improvement in the UDVA and CDVA was observed six months after the surgery (P <
0.001) with a significant reduction in the spherical (4.67 diopters (D)) and cylindrical (2.19 D) refractive errors.
A significant reduction in the corneal asphericity in all the optical zones and in the superior, inferior, nasal,
temporal, and central areas was noted (P < 0.001). The mean thickness at the thinnest location of the cornea
decreased from 437.15 ± 30.69 to 422.81 ± 36.91 μm. A significant corneal flattening was seen. The K1, K2,
and Km changes were 5.32 D, 7 D, and 6.17 D, respectively (P < 0.001).
Conclusion: MyoRing implantation is effective for improving corneal asphericity in patients with KCN. It
allows successful corneal remodeling and provides a significant improvement in UDVA, CDVA, and refractive
errors.

Keywords: Cornea; Corneal Topography; Keratoconus

J Ophthalmic Vis Res 2019; 14 (4): 428–435

Correspondence to:

Hesam Hashemian, MD. Eye Research Center, Farabi
Eye Hospital, Tehran University of Medical Sciences,
Tehran 16169, Iran.
E-mail: hashemian_md706@yahoo.com

Received: 01-09-2018 Accepted: 06-02-2019

Access this article online

Website:
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DOI:
10.18502/jovr.v14i4.5443

Introduction

Keratoconus (KCN) is the most prevalent primary
corneal ectasia which commonly causes bilateral

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How to cite this article: Khorrami-Nejad M, Aghili O, Hashemian H,
Aghazadeh-Amiri M, Karimi F. Corneal Asphericity after MyoRing Implanta-
tion. J Ophthalmic Vis Res 2019;14:428–435.

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Corneal Asphericity and MyoRing Implantation; Khorrami-Nejad et al

asymmetrical thinning of the paracentral cornea.[1]
Thinning of the cornea usually occurs in the central
and the inferior temporal region,[2] although thin-
ning in the upper area has also been reported.[3, 4]
Thinning of the cornea leads to myopia and irregu-
lar astigmatism, which affects visual quality.

In most studies, the reported prevalence of KCN
in the general population was between 50 and
230 per 100,000.[5–7] Recent studies have shown
that KCN starts from the posterior corneal surface
and the posterior curvature is affected to a greater
extent than the anterior curvature in the early
stage of KCN.[8, 9] Therefore, devices based on
direct evaluation of the two surfaces of the cornea
(Scheimpflug principle) have been specifically
addressed in recent studies.[10, 11] Corneal topogra-
phy, the most accurate method for detecting and
confirming KCN, is also based on Placido disc and
Scheimpflug imaging, which are sensitive methods
for assessing the shape of the cornea.[12, 13]

Since the cornea accounts for the largest amount
of the dioptric power of the eye, a small change
in the shape of the cornea is sufficient to produce
a significant dioptric change.[14] Aspheric cornea
affects the lower and the higher order aberra-
tions, particularly compensates for the spherical
aberrations, and ultimately improves the retinal
image quality. Therefore, corneal asphericity has a
potentially significant effect on visual quality.[15, 16]

MyoRing is a 360° continuous full-ring implanted
into a corneal pocket using a PocketMaker micro-
keratome or a femtosecond laser. The MyoRing has
a diameter of 5–8 mm, a thickness of 200–400 μm,
and a body width of 0.5 mm. MyoRing implantation
has proven to be safe and effective for the treat-
ment of myopia, ectasia, and KCN.[17–19] The use of
an intrastromal corneal ring in the periphery of the
cornea causes frontal displacement of the cornea.
It also causes central corneal flattening (the arc-
shortening effect).[20]

Very few studies have evaluated the corneal
asphericity before and after MyoRing implantation.
Due to the effect of corneal asphericity on the
quality of vision, we aimed to study the changes
in these parameters in our study. The prediction of
the effect of MyoRing on corneal asphericity may
determine whether the patient is a good candidate
for MyoRing implantation. The selection of suitable
candidates for this surgery may increase the quality
of vision and, ultimately, the quality of life.

METHODS

This cross-sectional observational study included
32 eyes of 28 patients with a mean age of 26.75
± 6.46 years (ranging 18 to 42 years).

The statistical population of this study consisted
of stage 2 and stage 3 KCN patients referred to the
Farabi Eye Hospital between 2014 and 2016 who
underwent femtosecond-assisted MyoRing implan-
tation. Thirty-two eyes of 28 patients were included
in the study and all of these 28 patients were
evaluated. This study was performed in accordance
with the tenets of the Declaration of Helsinki,
and the Ethics Committee of the Shahid Beheshti
University of Medical Sciences approved the study.
The records were de-identified and anonymous.

The exclusion criteria for this study consisted of
any defect in documentation, presence of corneal
scar, previous corneal surgery of any type, use
of contact lenses three weeks before surgery,
presence of other ocular or systemic diseases (reti-
nal abnormalities, diabetic retinopathy, cataract,
glaucoma, etc.), the inability of acquiring reliable
imaging, and failure to complete postoperative
examinations six months after the procedure. The
records of the patients included in the study were
examined by the observation method.

In all cases, the pocket for MyoRing implanta-
tion was created using the 150 kHz femtosecond
technology (IntraLase, Advanced Medical Optics
Inc., Santa Ana, CA, USA). After the creation of the
pocket, a space was gently formed by passing a
spatula through the temporal incision between the
closed flap and the bed.

Data extracted from the patients’ records
included the axes and amount of total, anterior,
and posterior corneal astigmatism measured
by the Pentacam (Oculus Optikger te GmbH,
Wetzlar, Germany), as well as the spherical and
cylindrical refractive errors. Corneal asphericity in
different zones of the cornea was measured using
a refractive map of the Pentacam. All patients
fulfilling the inclusion criteria during the study
period were included in the study. All surgeries
were performed by a single surgeon.

In the present study, MyoRings with diameters
of 5 mm and 6 mm and thicknesses of 240
μm and 280 μm were used according to the
size of the pupil in mesopic conditions and the
severity of KCN. Uncorrected distance visual acuity
(UDVA), corrected distance visual acuity (CDVA),

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Corneal Asphericity and MyoRing Implantation; Khorrami-Nejad et al

manifest refraction, corneal asphericity at 6, 7,
8, 9, and 10 mm optical zones in the superior,
inferior, nasal, temporal, and central areas, mini-
mum corneal thickness, and keratometry readings
were the outcome measures of the study. They
were measured preoperatively and six months after
MyoRing implantation.

KCN patients were divided into four cate-
gories according to the Amsler Krumeich KCN
classification.[21] The stage was determined if one
characteristic each from the following was present:

Grade 1: induced myopia and/or astigmatism
less than 5 D, keratometric reading ≤ 48.00 D,
Vogt’s striae, and/or eccentric steepening; grade
2: induced myopia and/or astigmatism of 5–8
D, keratometric reading less than 53 D, lack of
scar, and/or minimum corneal thickness greater
than 400 μm; grade 3: induced myopia and/or
astigmatism of 8–10 D, mean keratometric reading
greater than 53 D, no scar, and/or minimum corneal
thickness of 200–400 μm; and grade 4: refraction
not measurable, the keratometric reading greater
than 55 D, central scar, and/or the corneal thick-
ness less than 200 μm.

In the next step, patients with grade 2 and
grade 3 KCN who underwent the MyoRing implan-
tation and fulfilled the inclusion criteria for the
study were selected as the statistical population.
Data were gathered using Pentacam HR (Oculus
Optikger te GmbH, Wetzlar, Germany), Topcon
auto-kerato refractometer KR 8800 (Topcon Corpo-
ration, Tokyo, Japan), Heine Beta 200 retinoscope
(Heine Optotechnik GmbH & Co., Herrsching, Ger-
many), and an ETDRS chart (at a distance of 4
m). Visual acuity was recorded using the LogMAR
system.

Statistical analysis was performed using the
SPSS software for Windows (Version 22, IBM Inc.,
Armonk, New York, USA). Data were analyzed
using statistical indices, including the mean and
standard deviation. All data were checked for
normality using the Shapiro–Wilk test, followed by
a comparison of the data before surgery with those
after six months of surgery using the paired t-
test. To compare the normal variables in multiple
groups, one-way or two-way analysis of variance
was used. P < 0.05 was considered statistically
significant.

RESULTS

In the present study, 32 eyes of 28 patients [13
(40.6%) males and 19 (59.4%) females] with stage
2 and stage 3 of KCN were examined. The mean
age was 26.75 years, with a range of 18 to 42 years.
Six-month postoperative follow-up was carried out
for all patients. Eighteen right eyes (25.56%) and
fourteen left eyes (75.43%) were included in the
study. According to the Amsler Krumeich KCN
classification, 24 eyes (75%) had grade 2 KCN
and 8 eyes (25%) had grade 3 KCN. The mean
spherical and cylindrical refractive errors and the
mean LogMAR CDVA and UDVA before and after
the MyoRing implantation are presented in Table 1.
The mean spherical and cylindrical refractive errors
significantly decreased (P < 0.001) and the mean
UDVA and CDVA improved significantly after the
surgery (P < 0.001).

Means and standard deviations of minimum,
average, and maximum keratometry before the
surgery were 48.86 ± 3.14, 51.19 ± 3.6, and 53.63
± 54.3 D, respectively. The mean and standard
deviation of minimum, average, and maximum ker-
atometry six months after the MyoRing implantation
were 43.34 ± 3.36, 45.01 ± 36.36, and 46.59 ± 3.67
D, respectively, whereas those for the thickness
at the thinnest point of the cornea were 437.15 ±
30.69 μm before the surgery and 422.181 ± 36.91
μm after the MyoRing implantation [Table 2]. The
thinnest point of the cornea after the surgery was
14.34 ± 16.53 μm thinner than the preoperative
value (P < 0.001).

The means and the standard deviations of the
asphericity based on the position of the cornea
(nasal, temporal, upper, and lower) in the 6-, 7-
, 8-, 9-, and 10-mm optical zones are presented
in Table 3. The mean and standard deviation of
the asphericity in the entire cornea were also
determined for these optical zones [Table 3]. The
mean corneal asphericity before the surgery was
the highest in the 6-mm zone and the lowest
in the 10-mm zone. However, after the MyoRing
implantation, the greatest and the least changes in
the corneal asphericity values were observed in the
6-mm and 10-mm zones, respectively.

The change in the mean corneal asphericity was
significant in all optical zones after the MyoRing
implantation (P < 0.001). The changes in the mean
temporal, nasal, upper, and lower asphericity in all

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Corneal Asphericity and MyoRing Implantation; Khorrami-Nejad et al

Table 1. Descriptive statistics for refractive errors, the corrected distance visual acuity, and the uncorrected distance visual
acuity

Variables Unit Mean Maximum Minimum Standard deviation P-value

Sphere Pre-operation Diopter –4.95 0 –11.00 3.03 < 0.001

Post-operation –2.08 +4.00 –4.00 1.60

Cylinder Pre-operation Diopter –4.28 –1.00 –8.00 1.85 < 0.001

Post-operation –2.08 0 –6.00 1.32

CDVA Pre-operation LogMAR 0.32 0.1 0.5 0.17 < 0.001

Post-operation 0.22 0 0.5 0.15

UDVA Pre-operation LogMAR 1.12 0.4 2.2 0.45 < 0.001

Post-operation 0.44 0.1 1.6 0.31

CDV, corrected distance visual acuity; logMAR, logarithm of the minimum angle of resolution; UDVA, uncorrected distance visual
acuity

Table 2. Descriptive statistics of the keratometry and the thinnest point of the cornea

Variables Unit Mean Minimum Maximum Standard deviation P-value

Thinnest point Pre-operation μm 437.15 380 486 30.69 < 0.001

Post-operation 422.81 343 491 36.91

K-Min Pre-operation Diopter 48.86 43.3 54.1 3.14 < 0.001

Post-operation 43.54 36.8 50.3 3.36

K-Max Pre-operation Diopter 53.69 45.3 60.3 3.54 < 0.001

Post-operation 46.59 38.2 54.8 3.67

K-Mean Pre-operation Diopter 51.19 44.3 56.7 3.06 < 0.001

Post-operation 45.01 38 51.4 3.36

K-Max, maximum keratometry values; K-Mean, mean keratometry values; K-Min, minimum keratometry values

optical zones of the cornea after the surgery were
also found to be significant (P < 0.001).

DISCUSSION

The radius of curvature of a cornea with KCN
changes after the MyoRing implantation, mak-
ing it flatter. Due to this change in shape, the
cornea with KCN may become similar to a normal
physiological cornea after the surgery. However,
creating a flattening effect in the center of the
cornea without following a specific asphericity
pattern leads to a positive asphericity (rather than
improvement in the negative diopter value) of the

cornea and the cornea may become completely
oblate after surgery. To achieve excellent results
using intrastromal rings, it is necessary to control
the flattening pattern induced by them.

In the present study, significant decreases in
myopia and the cylindrical refractive errors were
observed, with a greater reduction in myopia than
in astigmatism at six months postoperatively. The
mean reductions in the spherical and cylindrical
refractive errors were 4.67 and 2.19 D, respectively.
These findings are consistent with those of previ-
ous studies. In the study by Daxer et al, the mean
variations in the spherical and cylindrical refractive
errors were 5.23 and 2.23 D, respectively, which

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Corneal Asphericity and MyoRing Implantation; Khorrami-Nejad et al

Table 3. Descriptive statistics of the asphericity variables based on the corneal zones

Asphericity Zone Preoperation Postoperation

Mean Standard deviation Mean Standard deviation

Nasal 6 mm –2.14 1.3 0.6 1.23

7 mm –1.72 0.88 0.26 0.92

8 mm –1.51 0.63 –0.07 0.73

9 mm –1.38 0.49 –0.38 0.62

10 mm –1.21 0.44 –0.55 0.55

Temporal 6 mm –0.97 0.72 1.11 1.29

7 mm –0.93 0.57 0.7 0.99

8 mm –0.92 0.42 0.33 0.78

9 mm –0.90 0.32 0.01 0.61

10 mm –0.87 0.34 –0.25 0.46

Superior 6 mm –1.86 1.2 0.28 1.58

7 mm –1.69 0.83 0.39 1.2

8 mm –1.47 0.61 0.29 0.89

9 mm –1.26 0.48 0.05 0.69

10 mm –1.09 0.4 –0.21 0.51

Inferior 6 mm –0.10 0.94 1.51 1.9

7 mm –0.43 0.73 0.92 1.48

8 mm –0.66 0.64 0.44 1.18

9 mm –0.85 0.56 0.06 0.96

10 mm –0.97 0.49 –0.27 0.78

Entire cornea 6 mm –1.27 0.64 0.88 1.19

7 mm –1.20 0.51 0.57 0.94

8 mm –1.14 0.4 0.25 0.73

9 mm –1.07 0.34 –0.06 0.57

10 mm –0.97 0.45 –0.29 0.46

are comparable with our results.[22] In another study
by Jabbarvand et al, the average postoperative
changes in the spherical and cylindrical refractive
errors were 5.74 and 3.23 D, respectively.[23] The
follow-up evaluations were performed 1, 6, and 12
months after the surgery, with similar results at
each evaluation.

The amount of myopia and astigmatism cor-
rection achieved in our study was greater than
that in the studies using intracorneal ring segment
(ICRS) implantation for the treatment of KCN.[24, 25]
Therefore, MyoRing may have more potential for
the correction of myopia and astigmatism than
ICRS in patients with KCN. This is probably due to
the arc-shortening effect of complete rings.

In the present study, the reduction in the spher-
ical and cylindrical refractive errors after MyoR-
ing implantation was consistent with a significant
improvement in visual acuity, as expected. The
mean increase in the UDVA after the surgery was
0.68 ± 0.44 LogMAR, a finding similar to those
from the studies by Jabarvand et al[23] and Alio
et al.[19] Improvement in the UDVA by 0.62 and 0.75
LogMAR, respectively, has been reported in both
the studies.

In the present study, the mean improvement
in the CDVA was 0.1 LogMAR, which is similar
to the findings in the study by Alio et al.[19] In
other studies by Mahmood et al[26] and Jabarvand
et al,[23] the mean improvement in the CDVA was

432 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 14, Issue 4, October-December 2019



Corneal Asphericity and MyoRing Implantation; Khorrami-Nejad et al

0.17 LogMAR and 0.26 LogMAR, respectively. In
a study conducted by Saeed et al, no significant
change was observed in the thickness of the
thinnest point of the cornea after the MyoRing
implantation.[27] However, in the present study, a
statistically significant decrease of 14.34 μm in the
thickness of the thinnest point of the cornea was
observed.

In the present study, a significant central flat-
tening of the corneal topography was observed
six months after the surgery, which was consistent
with the refractive changes. Based on the results
obtained in this study, the mean keratometry was
reduced by 6.17 D, which is similar to the result of
an average keratometric reduction by 5.76 diopters
in the study by Daxer et al.[22] In the studies by
Alio et al[19] and Mahmood et al,[26] this decrease
was approximately 8 D, which is slightly higher than
that found in our study. In the study by Alio et al,
the pupil size was not considered in the mesopic
conditions, and only the MyoRings with a diameter
of 5 mm and a thickness of 280 μm were implanted
in all patients. In the present study, based on
the size of the pupil of the patients under the
mesopic conditions and on preoperative keratom-
etry, MyoRings with diameters of 5 and 6 mm and
thicknesses of 240 and 280 μm were implanted.
The smaller diameter and higher thickness of the
MyoRing increase the effect of corneal flattening by
the ring (the arc-shortening effect).[23] The reason
for the difference in the keratometric reduction
between the two studies may be the difference
in the size and thickness of the MyoRing. In the
study by Mahmood et al, the size of the pupil in
patients under mesopic conditions was ignored as
the sample size was small (six eyes). Two patients
had a cross-linking history. Moreover, the study did
not take into account the specific inclusion and
exclusion criteria.

Jabbarvand et al reported a 9.78 D reduction
in the mean keratometry reading,[23] which is sig-
nificantly different from that in the present study
and in other studies. The authors used an Orbscan
to evaluate the anterior corneal surface, while in
the present study, we used the Pentacam HR for
corneal imaging. According to some studies, the
reproducibility of Pentacam is higher than that of
Orbscan.[28] In the study by Jabbarvand et al, 70%
of the patients were male, and the minimum age
of the subjects was 19 years with no maximum age
limit. In the present study, approximately 60% of the

patients were female and the age range was 18–42
years.

We observed a significant change in the corneal
asphericity after the MyoRing implantation. After
the surgery, the corneal prolate shape was reduced
and the cornea became oblate. The result was
predictable because a considerable flattening was
achieved in the center of the cornea with the
MyoRing implantation. An interesting finding was
that the mean decrease in the asphericity at the 6–
10-mm zones followed the similar slope.

In this study, the nasal position of the cornea had
the highest asphericity changes, and the inferior of
the cornea had the lowest amount of asphericity
compare to other regions (In the 6-mm optical
zone).

It is our belief that the present study was the
first study that evaluated the changes in corneal
asphericity in the 6–10-mm optical zones according
to the nasal, temporal, upper, and lower corneal
regions after MyoRing implantation. Alio et al stud-
ied the changes in the mean corneal asphericity
in the 8-mm zone.[19] They reported a decrease
of 1.72 in the mean asphericity six months after
the surgery, which is almost consistent with the
present study (1.39 ± 0.56). A slight difference
between the two studies may be due to a greater
corneal flattening in the study by Alio et al due
to the use of MyoRings with a smaller diameter
and a greater thickness. In their study, asphericity
changes were evaluated one and two months
postoperatively. This follow-up period is shorter
than the follow-up of six months in the present
study.

In another study by Hosny et al, the corneal
asphericity was evaluated only in a MyoRing with
a diameter of 6 mm.[29] The mean change in
the corneal asphericity was 0.43 ± 2.6 after the
MyoRing implantation. The less favorable outcome
of this study compared to the present study could
be due to the difference in the duration of follow-
up after the surgery. In the study by Hosny et al,
the results were evaluated one month after the
surgery.

Torquetti et al evaluated the changes in the
corneal asphericity after implantation with ICRSs in
KCN.[16] They reported a mean decrease of 0.53
in the corneal asphericity. The mean asphericity
before the surgery in their study was –0.85.
They suggested that the change in the thicker
and the paired segments was more than in the

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Corneal Asphericity and MyoRing Implantation; Khorrami-Nejad et al

single segments. The MyoRing has a stronger
arc-shortening effect than the ICRSs due to its
360° design. The reason for the low amount of
variation in the asphericity in the study by Torquetti
et al may be the use of ICRSs instead of the
MyoRing.

In conclusion, we found that MyoRing implan-
tation significantly reduced the cylindrical and
spherical refractive errors due to central corneal
flattening. This technique appears to be effective
for decreasing myopia and corneal steepness,
and effectively affects the corneal shape. A more
detailed examination of the corneal parameters
such as asphericity in patients with KCN can result
in better understanding of the changes associated
with KCN. Positive spherical aberration worsens
contrast sensitivity and may compromise the visual
outcomes after MyoRing implantation.

Financial Support and Sponsorship

Nil.

Conflicts of Interest

There are no conflicts of interest.

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