Original Article

Orthokeratology in Moderate Myopia: A Study of
Predictability and Safety

Kirti Singh, MD, DNB, FRCS; Mainak Bhattacharyya, MS, DNB; Abhishek Goel, MS, DNB, FICO
Ritu Arora, MD, DNB; Nikhil Gotmare, MS; Himshikha Aggarwal, MBBS

Guru Nanak Eye Centre, Maharaja Ranjit Singh Marg, New Delhi, India

ORCID:
Kirti Singh: http://orcid.org/0000-0002-9181-5963

Mainak Bhattacharyya: http://orcid.org/0000-0002-0571-5764

Abstract

Purpose: Literature is relatively silent on safety profile and predictability of orthoker-
atology lenses in terms of myopia correction and prevention of further progression,
especially in semi-tropical countries; this study was designed to fill this gap.
Methods: This prospective, intervention case series enrolled 30 eyes of 30 patients
with myopia up to –5.5 diopters (D). Patients were randomized into two groups of 15
each; the study group was prescribed overnight orthokeratology (OK) lenses, while the
control group used daily wear conventional soft contact lenses. Follow-up examinations
were performed after 1 h and 6 h, and then at 1, 7, 15, 30 days, and 4 months post lens
wear. Uncorrected visual acuity (UCVA), contrast sensitivity, keratometry, central corneal
thickness (CCT), and tear film break up time (TBUT) were evaluated at each follow-up
examination.
Results: All patients attained a visual acuity of 0.00 Logarithm of the Minimum Angle
of Resolution (logMAR) after one week of lens use, which was maintained throughout
the study period. While patients allotted to the study group had a gain of 8.1 Snellen
lines (UCVA), those in the control group gained 8.9 lines (BCVA) at the end of follow-up
period. In the OK group, cornea showed a flattening of 0.8 D (mean keratometry) after
single overnight usage of OK lens and overall flattening of 1.2 D compared to baseline, at
the end of four months. The change in contrast sensitivity, corneal endothelial specular
count, axial length and tear film status was not significant in either group.
Conclusion: Orthokeratology is an effective and safe modality to correct moderate
myopia in motivated young adults. No side effects were encountered after a short-term
follow-up in participants who resided in semi-tropical environments.

Keywords: Contact Lens; Overnight Wear; Orthokeratology; Moderate Myopia; Semi-tropical
Environments

J Ophthalmic Vis Res 2020; 15 (2): 210–217

Correspondence to:

Mainak Bhattacharyya, MS, DNB. 19/312, Shivam Khand,
Vasundhara, Ghaziabad 201012, India.
E-mail: drmainakb@gmail.com
Received: 28-03-2018 Accepted: 16-04-2019

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DOI: 10.18502/jovr.v15i2.6739

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How to cite this article: Singh K, Bhattacharyya M, Goel A, Arora R,
Gotmare N, Aggarwal H. Orthokeratology in Moderate Myopia: A Study of
Predictability and Safety. J Ophthalmic Vis Res 2020;15:210–217.

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Orthokeratology in Moderate Myopia; Singh et al

INTRODUCTION

Orthokeratology (OK) is defined as “reduction,
modification, or elimination of a refractive error by
programmed application of contact lenses.”[1] Its
genesis arose following a serendipitous observa-
tion by Wesley and Jessen in the 1950s who found
spectacle blur experienced by patients after wear-
ing hard contact lenses. This perceived blurring
was subsequently traced to lens-induced corneal
reshaping, which was then utilized for therapeutic
purposes.[2] The method was eventually discontin-
ued due to problems of poor lens fitting, unpre-
dictable results, and safety concerns.[3–6] This lost
science of OK was revived in the late 1980s with
the development of reverse-geometry contact lens
designs by Wlodyga and Stoyan.[7] Their design
permitted more predictable results to be achieved
over shorter periods. Further refinement using very
high oxygen-permeable materials ushered in an
era of overnight lens wear. This overnight OK lens
reduced daytime visual aid requirements and came
to be known as “accelerated orthokeratology”
because of the rapid onset of refractive and corneal
topographic changes.[8]

The OK lenses work by altering the corneal
shape from prolate to oblate, resulting in a reduc-
tion in the central corneal curvature. This alteration
of shape is a result of the flat lens design, causing
a redistribution of corneal epithelium and anterior
stromal tissue over the central treatment zone
which is 5 to 6 mm in diameter.[9] The central
treatment zone is dictated by pupil size, and
treatment zone less than mesopic pupil dimensions
can adversely affect vision in conditions of low-
illumination and low-contrast. The reversibility of
the procedure within two to four weeks of discon-
tinuation of OK lens wear is a consequence of
regression of corneal parameters.[10]

Common issues of concern with OK lens use
include the unpredictability of visual gain due to
issues of inadequate lens centration, poor con-
trast with persistent use, and increase in higher-
order aberrations (HOA) and safety because of the
inherent risk of microbial keratitis.[11] In semi-tropical
environments, microbial growth is expected to be
more florid, especially in the closed-eye conditions
simulated by OK lens wear. These risks underscore
the importance of safety profiling of OK lenses in
semi-tropical environments. Previous studies have
also reported a high rate of keratitis associated

with lens use in semi-tropical regions.[12, 13] Strin-
gent lens care regimens have made OK a safe
overnight treatment modality, but evidence on
safety and predictability of OK lens use in semi-
tropical environments is relatively scarce; this study
was designed to bridge this gap.

METHODS

This study was a prospective, interventional trial of
OK lens wear in 30 eyes of 30 patients with myopia
up to –5.5 diopters (D). This research followed the
tenets of the Declaration of Helsinki. Informed con-
sent was obtained from all participants after expla-
nation of the nature and possible consequences of
the study. This research was approved by our local
Institutional Ethical Committee. Inclusion criteria
were: age 18–30 years; myopia up to –5.5 D,
and with-the-rule astigmatism of up to –1.5 D or
against-the-rule astigmatism up to –0.75 D with
keratometry values between 40 and 45 D. Patients
with pathological myopia, corneal pathologies such
as dry eyes, healed keratitis, ocular surgery, kerato-
conus and systemic comorbidities such as diabetes
mellitus and thyrotoxicosis were excluded from the
study. Patients were randomized (using the closed
envelope method) into two groups of 15 each:
the study group (OK group) was prescribed OK
lenses in one eye only and the control group was
prescribed daily wear conventional soft contact
lenses in both eyes.

The evaluated parameters were cycloplegic
refraction, uncorrected visual acuity (UCVA), best-
corrected visual acuity (BCVA) using a Snellen
chart, corneal topography and keratometry by Orb-
scan IIz (Bausch & Lomb Technolas Topographer,
USA), central corneal thickness (CCT) (Sonomed
300P PacScan; Sonomed Escalon, USA), tear film
break up time (TBUT), contrast sensitivity (using
FACT charts), corneal endothelial cell count (Nidek
CEM 530, Nidek Co Ltd, Japan), and axial length.

The study group was subjected to a trial of
reverse geometry lenses, made of Boston XO
material with diffusion constant (DK) value 140
(OrthoK Lucid Korea lenses). These light blue
colored lenses of 10.6 mm diameter were available
in a power range of –0.50 D to –5.0 D with base
curves ranging from 8.44 mm (40.00 D) to 7.42 mm
(46.00 D). The flat K reading was used to calculate
the base curve of the first trial lens.

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Orthokeratology in Moderate Myopia; Singh et al

Sequential flattening or steepening was per-
formed in steps of 0.4–0.5 BC until an optimal
fluorescein bull’s eye pattern was attained [Figure
1]. A movement of 1 mm was the goal for dynamic fit,
but a greater emphasis was placed on the static fit.
Patients were assessed after 1 h of wear to confirm
adaptability and detect early improvements (if any)
in visual acuity. The lens was then inserted in one
eye, and the patient was admitted overnight to
ensure initial comfort and adherence.

UCVA, contrast sensitivity, keratometry values,
CCT, and TBUT were evaluated in the morning
after the first night of OK wear. The patients were
then discharged and asked to resume normal daily
activities while using OK lenses during their 8–
9 h of night-time sleep. The duration of OK lens
usage was determined based on the amount of
myopia to be corrected. For mild myopia (–2.0 to
–3.5 D), the OK lens was worn every night for three
weeks followed by alternate nights. For moderate
myopia (> –3.5D), the lens was worn every night.
Subjects were followed-up at days 7, 15, 30, and
then monthly for four months.

Subjective assessments of the comfort and toler-
ability of lens wear were evaluated for each patient
at the beginning and end of the study. The criteria
used included quality of vision, comfort/difficulty of
lens wear, ghosting of images, halos, flares, or
difficulties in performing tasks in dim light.

The CL group subjects were prescribed conven-
tional daily wear soft contact lenses (Silk Lens) with
a Dk value of 50 and a thickness of 0.1 mm. These
patients were not admitted for the first night, but
instead were followed-up at 1 h and 6 h of lens
wear on days 1, 7, 15, 30, and then monthly until four
months. The lens usage was as per requirements,
which ranged from 6–9 h per day. Both eyes
were prescribed soft lenses, but only one eye was
included for the purpose of the study.

Statistical Analysis

Continuous variables were expressed as means
± standard deviations, and categorical variables
were expressed as frequencies and percentages.
An independent t-test was used to compare the
continuous variables between the OK and control
groups, whereas a paired t-test was used to com-
pare the change of measurement results for paired
samples. A Chi-squared test or Fisher Exact test
was used to examine differences in categorical

variables. Statistically significant differences were
defined as P < 0.05. Statistical analyses were
carried out using the Statistical Package for Social
Sciences (SPSS) Version 17.0 software.

RESULTS

The OK and control groups were age matched, with
the average age being 22.3 ± 2.8 years in the OK
group and 22.1 ± 6.8 years in the control group (P
= 0.9). The sample consisted of 16 females and 14
males. The mean spherical refractive error in the
OK group was –3.4 ± 1.3 D (–2.0 to –5.5 D), with a
cylindrical error of –0.4 ± 0.5 D at 69 ± 32° (–0.25
to –1.5 D at 15–95°). The mean spherical refractive
error in the control group was –3.4 ± 1.03 D (–1.8
to –5.3 D) with mean cylindrical error of –0.2 ±
0.3D at 95 ± 6° (–0.25 to –1.75D at 20–100°). No
statistically significant intergroup differences were
found in the distribution of refractive errors using
the Mann–Whitney test (P = 0.351).

Visual acuity

Mean visual acuities in the OK and control groups at
presentation were 1.07 ± 0.15 and 1.040 ± 0.11 Log
MAR, respectively (P = 0.635). At all subsequent
follow-ups, visual acuity measures were taken after
the removal of the OK lens in the study group
and with the soft lens in situ in the control group.
Post lens wear visual acuity at 1 h was 0.31 ± 0.3
LogMAR in the OK group versus 0.00 LogMAR
in the control group. At day 7, the visual acuities
were 0.05 ± 0.1 LogMAR versus 0.00 LogMAR in
the OK and control groups, respectively. After that,
both groups had a visual acuity of 0.00 LogMAR at
all subsequent follow-ups. A statistically significant
intergroup difference in visual acuity was seen only
at 1 h and 6 h of lens wear (P < 0.001) [Figure 2].

In the OK group, the gains in Snellen lines of
visual acuity were 4.98 at 1 h, 8.1 lines and the
end of follow-up. In the control group, the gains
were 8.9 lines at all follow-ups beginning at 1 h.
This underscores the fact that OK lens wearers took
time to attain good unaided visual acuity, whereas
control wearers (the control group) had an instant
gain of aided good vision.

Visual acuity of 0.0 LogMAR units (6/6 Snellen)
was achieved after one day of overnight wear in
patients with mild myopia and by day 7 of overnight
wear in patients with moderate myopia. The target

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Orthokeratology in Moderate Myopia; Singh et al

Figure 1. Sequential fitting from steep fit to ideal fit during trial fitting of an orthokeratology patient.

Figure 2. Gain in number of Snellen lines after lens wear. CL, contact lens; OK, Orthokeratology

of visual acuity of 0.0 LogMAR (Snellen 6/6) was
attained in all patients and was maintained for the
entire four-month follow-up period. A drop of 1.2
lines in the evening time was documented in the
OK group during the first week of the OK lens
use.

Corneal alterations and effect on contrast
sensitivity and tear film

Corneal alterations were assessed by evaluat-
ing changes in corneal topography, pachymetry,
and endothelial cell counts. Additional deleterious
effects (if any) on contrast sensitivity and tear

film dynamics were recorded [Table 1]. Corneal
topography exhibited maximal changes in ker-
atometry readings occurring within the first night
of OK lens wear. These effects were particu-
larly evident within the first hour of lens wear,
reaching a significant level (P = 0.034). This
change plateaued by 6 h of wear with no
further significant change. Over the longitudi-
nal follow-up period, the maximal change in
mean Sim K (measured at central 3- and 5-
mm central zones) occurred within the initial
four weeks of OK lens wear [Figures 3 and
4]. As depicted in Table 1, this change was
highly significant at the final follow-up at four
months.

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Orthokeratology in Moderate Myopia; Singh et al

Figure 3. Change in mean keratometry in both groups in 3-mm zone. CL, contact lens; K, keratometry; Ortho K, Orthokeratology.

Figure 4. Change in mean keratometry in both groups in 5-mm zone. CL, contact lens; K, keratometry; Ortho K, Orthokeratology.

Table 1. Change in corneal pachymetry, 3-mm and 5-mm zone keratometry, specular count tear film break-up time, axial length
and contrast sensitivity in the study (Ortho K) and control groups post lens wear

Ortho K group Control group Intergroup
comparison

Pre lens wear Post lens use
(four months)

Pre lens wear Post lens use
(four months)

Corneal Pachymetry 527 ± 28.4µm 525.8 ± 27.4 µm 532 ± 27.4 µm 530.80 ± 29.07
µm

NS

Keratometry (3-mm zone) 44.37 ± 1.3 D 42.83 ± 1.1 D 1.54
(P = 0.000)

44.12 ± 0.9D 44.14 ± 0.9 D P = 0.002
Significant

Keratometry (5-mm zone) 44.58 ± 1.2 D 43.38 ± 0.7 D 1.2
(P = 0.000)

43.72 ± 1.0 D 43.68 ± 0.9 D NS

Specular count 2901.40 ± 305.5
cells/mm3

2894 ± 294.6
cells/mm3

2772.87 ± 290.3
cells/mm3

2733.20 ± 249.6
cells/mm3

NS

Tear film break-up time (TBUT) (in
seconds)

11.9 ± 0.96 s 12.6 s 11.8 ± 1.1 s 12.1 ± 0.7 s NS

Axial length 24.13 ± 0.7 mm 24.01 ± 0.4 mm 23.47 ± 0.7 mm 23.13 ± 0.6 mm NS
Contrast sensitivity (by FACT chart) 1.42 ± 0.12 1.423 ± 0.11 1.373 ± 0.09 1.37 ± 0.94 NS

D, diopter; NS, not significant

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Orthokeratology in Moderate Myopia; Singh et al

Corneal flattening by 1.5 D in mean K (3 mm zone)
and 1.2 D (5 mm zone) was observed in OK group
patients by the end of the study period. The 5-
mm zone keratometry documented the flattening
earlier, beginning at 7 days compared to the 14
days for the 3-mm zone keratometry map.

During the entire follow-up period, perceived
lens tolerance and comfort were high, with no
dropouts seen. There were no statistically sig-
nificant changes in TBUT between the baseline
and four-month follow-up measurements in either
group – 11.9 ± 0.96 s and 11.8 ±1.1 s, respectively, in
the OK group (P = 0.112) and 12.3 ± 0.6 s and 12.1 ±
0.7 s, respectively, in the control group (P = 0.132).
Intergroup comparison revealed no statistically sig-
nificant difference between the two groups in TBUT
values measured before intervention (P = 0.90) or
after four months (P = 0.123). This implied that no
significant tear film disruptions were observed at
any of the follow-ups in either the study group or
the control group.

Contrast sensitivity (CS) was measured using
FACT charts at 3 meters. There were no statistically
significant differences in contrast sensitivity, as
indicated by pre- to post lens prescription CS
values, for either the OK (pre: 1.4 ± 0.1, post: 1.4 ±
0.1) (P = 0.189) or CL (pre: 1.37 ± 0.1, post: 1.37 ± 0.9)
(p = 1.0) groups. The change in contrast sensitivity
in the OK group (0.4 grid) was not significant as
compared to no change in the CL group patients
during the entire follow-up period of four months.

Subjective improvements in vision quality in the
eyes treated with the OK lenses were adequate
for the performance of daily activities with no
additional vision aids. Subjective score assess-
ments improved in all patients at all follow-ups,
with only a handful of patients complaining of
ghosting of images, glare, or difficulties in dim light
on day 1. These complaints resolved by the end
of four months. No significant lens decentration,
corneal abrasion, dry eye, or sight-threatening
complications such as microbial keratitis was noted
in any of the subjects over the entire follow-up.

DISCUSSION

Orthokeratology utilizes contact lenses to “reduce,
modify, or eliminate refractive errors.”[14] A resur-
gence of interest in this technology occurred after
the advent of reverse-geometry lens designs and
use of an extremely high Dk material which makes

these lenses easy to center and safer for the
cornea. Reverse-geometry OK lenses incorporate
a secondary curve, steeper than the lens base
curve, to aid centration and are fitted with a base
curve flatter than the central corneal curvature.
This applies pressure to the central treatment
zone, altering the corneal shape from prolate to
oblate after overnight wear.[15] OK is reportedly
effective in slowing myopia progression over a 12-
year follow-up period with a clinically acceptable
safety profile.[14]

In our study, 60% of refractive correction was
achieved after the first overnight OK wear, and
almost 100% visual correction was achieved after
one week of continuous overnight OK lens wear.
This dramatic initial visual improvement is consis-
tent with previous studies.[15, 16] The initial correc-
tion achieved in the morning after overnight OK-
wear starts wearing off within hours due to the
regression of the corneal shape, leading to visual
blurring in the afternoon period.[13] This fact was
confirmed by our results, with patients complaining
of afternoon blur with a drop of 1.2 Snellen lines
in the evening during the first week. This effect
is usually transient and resolves over a week.[17]
Stabilization of visual gain varies, with most studies
reporting a gestation of four weeks and others—
like ours—a period of 7–10 days.[15, 16, 18–20]

A concern with OK lenses is loss of contrast;
however, in this series contrast sensitivity (and
visual acuity) did not deteriorate either in the OK
group or the control group after lens wear.[22] A
study by Tang et al measuring contrast sensitivity
under both photopic and mesopic conditions cor-
roborated this finding.[23]

Corneal flattening by a mean of 1.2 D was
observed by four months, with maximum flattening
after initial overnight use. This correlated more
with the 5-mm zone topography value, which also
picked up the peripheral changes earlier. These
discrepancies in the 3- and 5-mm zones can be
explained by the principle of OK where the lens
hydraulically redistributes epithelial cells from the
center toward the periphery and induces central
corneal thinning and mid-peripheral thickening.[13]
Thus, 5-mm zone keratometry is a more sensitive
indicator of OK-induced change and detects these
changes earlier than the 3-mm zone map.

The most common problem associated with OK
lens use is inadequate lens centration with superior
displacement due to Bell’s phenomenon during

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Orthokeratology in Moderate Myopia; Singh et al

sleep, causing with-the-rule astigmatism.[11] Sun et
al have recently reported increased corneal irreg-
ularity and ocular HOA (spherical aberrations and
comas) with OK lenses, despite improvements in
refractive error.[24] No significant lens decentration
was seen in our patients.

In our series, no case of induced toxicity was
noted, and no patient presented with any evidence
of corneal damage or infiltration. This could be a
result of the explicit lens care instructions that were
given, and the vigilance of our motivated patients
in carrying out lens hygiene measures. A review
of literature on infectious keratitis associated with
OK lens use reports that Pseudomonas aeruginosa
and Acanthamoeba are the most commonly identi-
fied infectious agents with the majority of infections
resulting in corneal scar formation, necessitating
surgical intervention in 10% of eyes.[25] Previous
studies have emphasized the importance of proper
lens care and maintenance of lens hygiene to
ensure the safety of long-term OK lens wear.[26, 27]

This study was designed as a pilot study evaluat-
ing efficacy and safety of OK, and longer follow-ups
are necessary to establish the long-term effects
of OK lenses. As the risk of keratitis is not high,
substantial, long-term follow-up cohorts are nec-
essary to evaluate the risk of keratitis associated
with these contact lenses. No lens is considered
completely safe for overnight wear. In addition,
given that refractive surgeries such as LASIK/SMILE
are very popular, some may question the relevance
of OK lenses.[28] However, OK lenses are non-
invasive, reversible, and relatively safe to use (even
in thin corneas) and hence stay relevant, especially
in a developing country like ours.

In conclusion, OK is an effective and safe method
for correcting moderate myopia in motivated young
adults. Use of OK lenses was not associated with
deleterious corneal complications, even in wearers
residing in semi-tropical environments.

Acknowledgments

The authors would like to thank Dr. Mamtamayi
Priyadarshani (Prkamya Visions) for her technical
support and guidance.

Financial Support and Sponsorship

Nil.

Conflicts of Interest

There are no conflicts of interest.

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