Original Article

Safety and Precision of Two Different
Flap-morphologies Created During Low Energy

Femtosecond Laser-assisted LASIK

Johannes Steinberg1,2,3, MD; Juliane Mehlan1, MD; Bulat Mudarisov1, MD; Toam Katz1,3, MD; Andreas Frings4,5,
MD; Vasyl Druchkiv1,2, MS; Stephan J Linke1,2,3, MD

1Department of Ophthalmology, University Hospital Hamburg-Eppendorf, Hamburg, Germany
2Hamburg Vision Clinic, Hamburg, Germany

3CareVision GmbH, Hamburg, Germany
4Univ.-Augenklinik Düsseldorf, Düsseldorf, Germany
5Augenarztpraxis PD Dr. Frings, Nürnberg, Germany

ORCID:
Johannes Steinberg: https://orcid.org/0000-0002-3091-9347

Abstract
Purpose: Currently, two major principles exist to create LASIK flaps: firstly, a strictly
horizontal (2D) cut similar to the microkeratome-cut and secondly an angled cut with
a “step-like” edge (3D). The strictly horizontal (2D) cut method can be performed using
apparatus such as the low-energy FEMTO LDV Z8 laser and its predecessors which are
specific to this type. Alternatively, the low-energy FEMTO LDV Z8 laser’s 3D flap design
creates an interlocking flap-interface surface which potentially contributes toward flap
stability. In addition, the FEMTO LDV Z8 offers flap-position adjustments after docking
(before flap-creation). The current study analyzed precision, safety, efficacy, as well as
patient self-reported pain and comfort levels after applying two different types of LASIK
flap morphologies which were created with a low-energy, high-frequency femtosecond
(fs) laser device.
Methods: A prospective, interventional, randomized, contralateral eye, single-center
comparison study was conducted from November 2019 to March 2020 at the Hamburg
vision clinic/ zentrumsehstärke, Hamburg, Germany. Eleven patients and 22 eyes
received low-energy fs LASIK treatment for myopia or myopic astigmatism in both eyes.
Before the treatment, the eyes were randomized (one eye was treated with the 2D, the
other eye with the 3D method).
Results: The mean central flap thickness one month after surgery was 110.7 ± 1.6 μm
(2D) and 111.2 ± 1.7 μm (3D); P = 0.365 (2D vs 3D). Flap thickness measured at 13
different points resulted in no statistically significant differences between any of the
measurement points within/between both groups; demonstrating good planarity of the
flap was achieved using both methods. Despite not being statistically significant, the
surgeons recognized an increase in the presence of an opaque bubble layer in the
3D flap eyes during surgery and some patients reported higher, yet not statistically
significant, pain scores in the 3D flap eyes during the first hours after the treatment.
Overall, safety- and efficacy indices were 1.03 and 1.03, respectively.
Conclusion: In this prospective, randomized, contralateral eye study, the low-energy fs
laser yielded predictable lamellar flap thicknesses and geometry at one-month follow-
up. Based on these results, efficacy and safety of the corresponding laser application,
that is, 2D vs 3D, are equivalent.

Keywords: Cornea; Femtosecond Laser; Flap Morphology; LASIK; Refractive Surgery

J Ophthalmic Vis Res 2023; 18 (1): 3–14

© 2023 Steinberg et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E 3

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Two Different Femto-LASIK Flaps; Steinberg et al

INTRODUCTION

More than 30 years ago, laser in situ
keratomileusis, better known as LASIK, started its
journey to become the most frequently performed
treatment to correct ametropia in otherwise
healthy eyes. Over the past decades, several
modifications were made to further improve its
safety, efficacy, and predictability, as well as the
comfort levels for both patients and surgeons.[1, 2]
One of the improvements was to create a highly
precise LASIK flap with a femtosecond (fs) laser
to reduce variations in terms of flap thickness (FT)
and flap-related complications when compared to
microkeratome-created flaps.[3, 4]

In addition, the fs laser enables different
flap-morphology designs to potentially further
improve the safety of the surgery. Currently,
two methods exist to create LASIK flaps: firstly,
a strictly horizontal two-dimensional (2D) flap-
cutting geometry, comparable to that of the
microkeratome and secondly, a three-dimensional
(3D) flap-cutting geometry which is in essence a
combination of the horizontal cut and an angled
side-cut, leading to a “step-like” edge. The first
option is only possible with the use of the low-
energy FEMTO LDV Z8 laser (Ziemer Ophthalmic
Systems AG, Switzerland) and its predecessors.
Whilst the 3D method creates a perfectly fitting
angled flap, the interface morphology is believed
to contribute toward flap stability and might
also lead to a decreased number of flap striae
and/or epithelial ingrowth.[5–7] However, due to
the entrapped air emerging during the fs-laser
“cutting” process of the horizontal flap-interface,
the occurrence of opaque bubble layers (OBL)
increases and potential tissue bridges might
also occur in the 3D-flaps.[8] Therefore, the
LDV Z8 fs laser creates additional “venting
tunnels” during the 3D flap preparation, which lead

Correspondence to:

Johannes Steinberg, MD. Department of Ophthalmology,
University Hospital Hamburg-Eppendorf, Martinistr. 52,
Hamburg 20251, Germany.
E-mail: steinberg@zentrumsehstaerke.de
Received: 01-09-2021 Accepted: 21-03-2022

Access this article online

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

DOI: 10.18502/jovr.v18i1.12720

the gas formed during the flap-cutting process
into the direction of the flap bed downward and
outward, to allow the gas to dissipate out of the
stroma. Several FT predictability (intended versus
achieved) comparisons were made in the past,
where multiple fs lasers were used and were
responsible for creating the flaps.[9–11]

However, the current study was done to analyze
the predictability, precision, safety, efficacy, as well
as the patients’ pain and comfort levels when
comparing the application of two different flap
morphologies which were both created using the
same low-energy, high-frequency fs laser.

METHODS

This single-center (Hamburg Vision Clinic,
Hamburg, Germany), prospective, interventional,
randomized, contralateral eye study was
conducted from November 2019 to March 2020.
The study was registered in clinicaltrials.gov
(NCT04426175) after Hamburg ethics committee
approval and performed in accordance with the
tenets of the Declaration of Helsinki. All patients
signed an informed consent form after being
advised in detail about the study rationale.

All patients received fs LASIK treatment for
myopia or myopic astigmatism on both eyes from
one of the two trained surgeons (SL/JS). The
inclusion and exclusion criteria were similar to
the criteria defined by the national committee
defining the inclusion and exclusion criteria
recommendations for refractive surgery in
Germany (KRC). Hence, the inclusion criteria
were: myopia up to 8 diopters, astigmatism up to
5 diopters, minimal corneal thickness of 480 μm,
and a minimum of two weeks of no contact lens
wearing. Patients with predicted residual stromal
thickness (RST) under the flap after ablation of
<250 μm, former ocular surgery, ocular diseases
(including, but not limited to, signs of keratoconus),

This is an open access article distributed under the Creative Commons
Attribution License, which permits unrestricted use, distribution, and
reproduction in any medium, provided the original work is properly cited.

How to cite this article: Steinberg J, Mehlan J, Mudarisov
B, Katz T, Frings A, Druchkiv V, Linke SJ . Safety and
Precision of Two Different Flap-morphologies Created During Low
Energy Femtosecond Laser-assisted LASIK. J Ophthalmic Vis Res
2023;18:3–14.

4 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 18, Issue 1, January-March 2023

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


Two Different Femto-LASIK Flaps; Steinberg et al

aged younger than 18 years, and concurrent
participation in another ophthalmological clinical
study were excluded.

Just before the treatment commenced,
every patient was assigned according to our
randomization list, those with a 2D flap created in
one eye and those with a 3D-flap creation in the
other eye. Schematic drawings of the morphology
and geometry of both flap designs are displayed in
Figures 1 (2D) and 2 (3D). In our study, the option of
two venting tunnels (3D flap) was chosen [Figure
2].

In all eyes, the flap was created with the FEMTO
LDV Z8 (Ziemer Ophthalmic Systems AG, Port)
with a target thickness of 110 μm along with
a superior hinge configuration. The subsequent
excimer laser ablation was performed with the
WaveLight® EX500 Excimer Laser (Alcon Fort
Worth, USA).

An optical coherence tomography (OCT) image
for flap visualization can be displayed, at the
surgeon’s discretion, on the screen before and/or
after the flap resection. Before flap creation, flap
visualization may serve as an optional safety
measure confirming the flap’s positioning with
respect to the Bowman’s layer and the stroma,
or, post flap-creation, where the presence of gas
bubbles can be assessed as an additional safety
measure before flap lifting [Figure 3]. In addition,
the intraoperative OCT feature can be useful for the
visualization of the applanation area.

Antibiotic eyedrops were instilled for one
week, while steroids and lubricants were reduced
gradually over the course of one month.

The primary objective of this study was to
compare central FT predictability in 110 µm LASIK
flaps between 2D and 3D flap geometry groups
with spectral domain anterior segments (AS)-
OCT (Maestro 1, Topcon Medical Systems Tokyo,
Japan) performed one month postoperatively. After
measuring the cornea with the OCT using a scan
protocol consisting of 12 B-scans in a radial pattern,
the anterior surface was automatically marked in
the image by the device. Three centrally located
manual thickness measurements from the anterior
surface to the interface were done and the average
value was noted.

Secondary objectives of the study were to
assess the following parameters:

Postoperative flap planarity with AS-OCT
(Maestro 1, Topcon, Japan) at one month follow-up.

After measuring the cornea with the OCT using a
scan protocol consisting of 12 B-scans in a radial
pattern, the anterior surface was automatically
marked in the image by the device. Then, three
manual thickness measurements from the anterior
surface to the interface were done in 12 different
measurement points as displayed in Figure 4.
For every measurement point, three consecutive
measurements were done and the average was
noted.

Subjective intraoperative flap morphology
assessment included: Stromal bed quality, ease
of flap lifting, and presence of OBL. The grading
was given by the surgeon directly after the
completion of the treatment and was based on
their assessment during/after the flap lift.

Self-reported pain perception and visual
experience with 2D and 3D flap geometries
during the early postoperative period. During the
one-day follow-up examination, patients were
asked to respond to three different questions.

Safety and Efficacy index (EI) defined as
the best-corrected visual acuity (BCVA) after
treatment divided by corrected distance visual
acuity (CDVA) before treatment (BCVA post/BCVA
pre), and uncorrected visual acuity (UCVA) after
treatment divided by BCVA before treatment
(uncorrected distance acuity (UDVA) post/BCVA
pre), respectively, were calculated.

Statistical Analysis

Statistical analyses were performed using the
SAS® software version 9.4 and R software
(https://www.r-project.org). A two-sided t-test
was used to test the primary hypothesis. Further
two-sided t-tests were used to test the difference
between the 2D and 3D flap geometries for
continuous parameters, while Fisher’s exact
test was used to test categorical parameters. In
the case of multiple comparisons (for instance,
between the regions or distances) the P-values
were adjusted with Holm’s method.

The sample size was estimated using nQuery®
V4.0.

RESULTS

Eleven patients (22 eyes) were included in our
study. Seven (63.6%) patients were female,
while four (36.4%) were male. The mean age

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Two Different Femto-LASIK Flaps; Steinberg et al

at the time of surgery was 37.27 ± 10.32 years
(range: 21 to 54). Preoperative refraction and
corneal thickness data are displayed in Table 1.
None of the analyzed demographic, refractive or
tomography parameters, displayed statistically
significant differences between the 2D and 3D
group (for all P > 0.05).

Primary Objective

Postoperative central FT for the 2D and 3D cutting
geometries were measured at the one-month
follow-up visit. Target FT was 110 µm. The results
are displayed in Table 2.

Figure 4 displays the differences from the target
FT (110 µm). Based on the equivalence test and the
null-hypothesis test combined, we can conclude
that the observed effect is statistically not different
from zero nor statistically equivalent to zero for 2D
and 3D cutting geometries.

At the one-month follow-up visit, the mean
central FT ± SD measured for 2D geometry flaps
was 110.67 ±1.60 μm, and for the 3D geometry
flaps was 111.21 ±1.65 μm. The mean difference
± SD between the target and achieved FT for
each individual cutting geometry group was 0.67
± 1.60 µm (2D) and 1.21 ± 1.65 µm (3D). Although
the 2D cutting geometry group showed a lower
mean difference in terms of FT predictability, the
difference was not statistically significant (P =
0.440).

Secondary Objectives

The results of the secondary objectives are
displayed in Tables 3–5.

Concerning postoperative flap planarity at
the one-month follow-up visit measured with
AS-OCT; for both 2D and 3D flap cut geometry
groups, a series of three consecutive thickness
measurements were taken at four distinct
measurement points (±1, ±2, and ±3 mm from
the center) along four different meridians (further
called subgroups), namely: superior, inferior, nasal,
and temporal [Figure 5]. The mean values were
taken for each point and then the averages of the
means were compared in terms of subgroups.

Data of the respective means and overall
averages were analyzed [Table 3].

For our analyses, we allocated the measurement
points to four subgroups: superior, inferior, nasal,

and temporal. When comparing these subgroups,
we couldn’t demonstrate any statistical relevant
differences among the four subgroups for either 3D
or 2D flaps, neither when comparing the totals of
the four subgroups of 3D with the totals of the four
subgroups of 2D (all P > 0.05).

We also combined all horizontal and all
vertical measurement points to analyze potential
differences between the 2D and 3D flaps. Again,
no statistically significant differences could be
demonstrated (all P > 0.05). Furthermore, no
statistically significant changes from the central
to the periphery of the cornea (i.e., potentially
increasing or decreasing flap thickness) could be
demonstrated either for 2D or 3D flaps.

Regarding our secondary objective of analyzing
subjective intraoperative flap morphology, we used
a predefined grading and surgeon’s assessment
during and after the procedure where the flaps
were lifted [Table 4]. Eight eyes (72.7%) in the 2D
group which were compared to five eyes (45.5%) in
the 3D group presented with a flat stromal bed (P
= 0.387). Despite not being statistically significant,
both surgeons found corneal stromal striae in two
eyes (18.2%) (P = 0.476) and “rastered” interface
in one eye (9.1%) (P = 1.000) in the 3D geometry
group as compared to none in the 2D flap-cutting
geometry group. Surgeons were able to easily lift
nine flaps (81.8%) from the 2D and six flaps (54.5%)
from the 3D group (P = 0.361). No OBL was found
in nine eyes that received 2D flaps (81.8%) or six
eyes that received 3D flaps (54.5%), respectively (P
= 0.453).

Regarding the secondary objective of this study,
analyzing postoperative subjective pain and visual
perception, a questionnaire was completed during
the first day follow-up visit where patients assessed
their own visual quality and perceived pain levels
during the first hours after the treatment.

Whereas more than half of the eyes treated with
either a 2D or 3D flap morphology experienced
none to moderate pain, reported during the first
hours after surgery, higher pain scores were
reported for some of the eyes treated with a 3D
flap.

In summary, pain perception was slightly better
in the 2D group, however, it was not statistically
significant.

Regarding the visual assessment right after
the treatment and at the beginning of the first
day after surgery, no statistically or clinically

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Two Different Femto-LASIK Flaps; Steinberg et al

significant differences could be demonstrated.
Detailed results are displayed in Table 5.

The patients were also asked to give an
assessment of their visual quality and pain level
at the one-week follow-up visit. None of the
patients reported any noticeable differences when
comparing their 3D and 2D-flap eyes.

Table 6 provides a better representation of
the functional parameters. Preoperative and
postoperative UCVA data for the respective follow-
up examinations are presented, and converted
from Snellen notation to the logarithm of the
minimum angle of resolution (logMAR).

The mean UCVA (n = 22) improved significantly
(P < 0.0001) between the preoperative visit 0.97
± 0.36 logMAR and the one-month follow-up visit
0.00 ± 0.02 logMAR.

Safety and Efficacy

For all eyes combined, the overall mean UCVA (n
= 22) measured at one month after treatment was
0.00 ± 0.02 logMAR. The safety index (SI) was 1.03,
and the EI was 1.03 with no statistically significant
differences between the 2D and 3D flap groups (all
P > 0.05).

DISCUSSION

Published literature comparing microkeratome
and fs laser created flaps is not a novelty
anymore.[3, 4, 13] Correspondingly, various
publications exist comparing the predictability
of FT measurements among fs lasers.[9, 11, 14]
To the best of our knowledge, this is the first
study that compared the predictability of two
flap-cutting geometries (2D vs 3D) created by
the same low-energy high-spot density fs laser.
In this prospective, randomized, contralateral,
single-center study, we were able to demonstrate
central FT predictability and discuss the objective
and subjective intra- and postoperative flap
morphology, as well as patients’ visual and pain
experience between the two groups. Furthermore,
it was verified that both geometry groups displayed
comparable overall linear and planar FTs from the
center to the periphery of the cornea.

Concerning FT predictability in other studies,
a retrospective series published in 2013 by
Cummings et al where 120 µm intended thickness
flaps were created by the FS200 fs laser (Alcon,

Wavelight, Fort Worth, USA) in 162 eyes and
measured by the AS-OCT (3D OCT-2000, Topcon
Medical Systems Tokyo, Japan) postoperatively,
showed a mean FT of 121.94 ± 10.52 µm.[9]

In another prospective study, 87 consecutive
eyes received either 110 or 120 µm intended flaps
created by the 200 kHz VisuMax fs laser (Carl Zeiss
Meditec, Jena, Germany). Results showed a mean
achieved FT of 112.3 ± 3.84 μm (range, 109.6 to
115.1) and 122.2 ± 3.93 μm (range, 115.8 to 129.0
μm) at one-month follow-up visit for the respective
intended flaps created.[15]

In a study where 110 µm intended flaps were
measured with FD-OCT one week postoperatively,
results showed a mean central FT of 105.4 ± 3.4
µm for FS200 and 110.8 ± 3.9 µm for VisuMax-
created flaps which was found to be statistically
significant; P < 0.01.[16] In the current study,
although the mean central FT measured for 2D
geometry flaps (110.67 ± 1.60 μm) was closer to the
110 µm target FT as compared to the 3D geometry
flaps (111.21 ± 1.65 μm) at one-month follow-up,
no statistically significant difference was found
between the two groups; P = 0.440. Therefore,
our results suggest that excellent predictability was
achieved regardless of the flap geometry utilized,
that is, 2D versus 3D.

One of the secondary objectives of our study
was to analyze postoperative FT in both groups
along 13 different data points across the horizontal
and vertical meridians, starting from the center
of the cornea to ±1.0, ±2.0, and ±3.0 mm. Our
results seem to be in line with the literature
discussed below: Jagow et al demonstrated in
their prospective comparative study, where FTs
were created either by a 60 kHz fs laser (Intralase,
Advanced Medical Optics) or a mechanical
microkeratome (Zyoptix XP, Bausch & Lomb)
and assessed with an AS-OCT for 20 points
measured from the corneal vertex across each
flap, for an intended 100 µm FT. The mean FT
achieved ranged between 108 and 124 µm, with
up to 16 µm of SD.[17] Zheng et al compared flap
morphology with the FD-OCT (uniformity, accuracy,
predictability) of 110 µm intended flaps created by
the FS200 (Alcon, Wavelight, Fort Worth, USA) (n
= 200 eyes) and the VisuMax fs laser (Carl Zeiss
Meditec, Jena, Germany) (n = 200 eyes), one week
postoperatively. Nine thickness measurements
were obtained across the length of the flaps at
the meridians of 0º, 45º, 90º, and 135º with the
cursor manually placed at ±4, ±3, ±2, and ±1 mm

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Two Different Femto-LASIK Flaps; Steinberg et al

Table 1. Descriptive summary (preoperative refraction and pachymetry) of the 2D and 3D groups.

2D (n = 11) 3D (n = 11)

Parameter (unit) Median (Q1/Q2) Mean ± SD Min/Max Median (Q1/Q2) Mean ± SD Min/Max
Sphere (D) –2.00 (–3.25;

–1.75)
–2.45 ± 1.36 –5.50/–1.0 –2.25 (–4.25;

–1.50)
–2.61 ± 1.69 –6.25/–0.25

Cylinder (D) –0.75 (–1.50;
–0.50)

–0.93 ± 0.77 –2.75/0.00 –0.50 –1.00;
–0.50)

–0.79 ± 0.69 –2.50/0.00

SE (D) –2.38 (–4.00;
–1.88)

–2.92 ± 1.43 –6.00/–1.50 –2.62 (–4.63;
–1.75)

–3.01 ± 1.62 –6.25/–1.00

CCT (µm) 566 (531; 591) 564 ± 37 514/642 565 (533; 588) 564 ± 34 516/632

SE, spherical equivalent; CCT, central corneal thickness
P-values from a two-sided t-test = all >0.05

Table 2. Postoperative central flap thickness measured with AS-OCT at one-month follow-up visit.

2D 3D P-value∗

Characteristics
(unit)

Median
(Q1/Q3)

Mean ± SD Min/Max Median
(Q1/Q3)

Mean ±SD Min/Max

Flap thickness
achieved (µm)

110.3
(109.3/111.7)

110.67 ± 1.60 108.3/114.3 110.7
(110.3/111.3)

111.21 ± 1.65 109.3/114.3 0.440

Achieved
thickness minus
Target (µm)*

0.33
(–0.67/1.67)

0.67 ± 1.60 –1.7/4.3 0.67
(0.33/1.33)

1.21 ±1.65 –0.7/4.3 0.440

∗P-value from a two-sided t-test

Table 3. Mean flap thickness for 2D vs 3D flaps measured with AS-OCT from central along the superior, inferior, nasal, and
temporal meridians at respective points: ±1, ±2, and ±3 mm at one-month follow-up visit.

2D (n = 11) Central (µm)
Mean ± SD

±1 mm (µm)
Mean ± SD

±2 mm (µm)
Mean ± SD

±3 mm (µm)
Mean ± SD

Superior 110.67 ± 1.60 111.33 ± 1.56 111.85 ± 2.34 111.58 ± 2.80
Inferior 110.67 ± 1.60 111.61 ± 2.27 112.18 ± 1.82 111.76 ± 2.18
Nasal 110.67 ± 1.60 111.21 ± 2.30 110.91 ± 2.10 111.18 ± 2.72
Temporal 110.67 ± 1.60 111.12 ± 2.58 111.30 ± 1.64 110.70 ± 2.35
Overall
average

110.67 ± 1.60 111.32 ± 1.92 111.56 ± 1.69 111.30 ± 2.17

3D (n = 11) Central (µm)
Mean ± SD

±1 mm (µm)
Mean ± SD

±2 mm (µm)
Mean ± SD

±3 mm (µm)
Mean ± SD

Superior 111.21 ± 1.65 111.70 ± 1.74 111.85 ± 1.77) 111.58 ± 2.53
Inferior 111.21 ± 1.65 112.85 ± 1.98 111.73 ± 2.11 111.91 ± 2.23
Nasal 111.21 ± 1.65 111.33 ± 2.08 111.06 ± 2.63 112.52 ± 2.83
Temporal 111.21 ± 1.65 112.76 ± 3.30 111.33 ± 2.86 111.55 ± 2.37
Overall
average

111.21 ± 1.65 112.16 ± 1.85 111.49 ± 2.03 111.93 ± 2.24

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Two Different Femto-LASIK Flaps; Steinberg et al

Table 4. Summary of intraoperative assessments: stromal bed quality, ease of flap lift, and presence of opaque bubble layer
(OBL).

Characteristics Category 2D 3D P-value*

Stromal bed quality, n (%) Smooth 8 (72.7) 5 (45.5) 0.387

Tissue bridges 3 (27.3) 3 (27.3) 0.659

Lines 0 2 (18.2) 0.476

Rastered 0 1 (9.1) 1.000

Ease of flap lift, n (%) Easily 9 (81.8) 6 (54.5) 0.361

Sticky 2 (18.2) 5 (45.5)

Presence of OBL, n (%) No OBL 9 (81.8) 6 (54.5) 0.453

<30% of flap surface 1 (9.1) 2 (18.2)
30–40% of flap surface 1 (9.1) 3 (27.3)

*P-value from a Fisher’s exact test
For stromal bed quality: because one eye could display more than one variable, P-values were given for each variable
comparing 2D and 3D. In all other analyzes, the overall P-value for the Fisher’s exact test was given.

Table 5. Summary of postoperative self-reported pain perception and visual experience stratified between 2D and 3D flap
geometry groups on day-one follow-up visit.

Category 2D(n = 11) 3D(n = 11) Overall(n = 22) P-value*

“Rate your pain in the right eye/left eye
during the hours after the treatment.” No
pain

4 (36.4) 3 (27.3) 7 (31.8) 0.821

Mild pain 2 (18.2) 1 (9.1) 3 (13.6)

Moderate pain 3 (27.3) 2 (18.2) 5 (22.7)

Severe pain 2 (18.2) 4 (36.4) 6 (27.3)

Intense pain 0 1 (9.1) 1 (4.5)

Rate your first visual experience
immediately after treatment: right
eye/left eye. As good as with glasses
before treatment

2 (18.2) 2 (18.2) 4 (18.2) 1.000

Almost as good as with glasses before
treatment

2 (18.2) 3 (27.3) 5 (22.7)

A little blurred 4 (36.4) 3 (27.3) 7 (31.8)

Blurry like seeing through foggy glasses 3 (27.3) 3 (27.3) 6 (27.3)

“Rate your visual acuity a few minutes
after awakening this morning for the
right and the left eye.” As good as with
glasses before treatment

5 (45.5) 5 (45.5) 10 (45.5) 1.000

Almost as good as with glasses before
treatment

2 (18.2) 3 (27.3) 5 (22.7)

A little blurred 4 (36.4) 3 (27.3) 7 (31.8)

∗P-value from a Fisher’s exact test

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Two Different Femto-LASIK Flaps; Steinberg et al

 

Figure 1. Flap morphology in planar (2D) flaps. Side view on the 2D LASIK flap. The flap is generated after applanation in a strictly
horizontal plane leading to a minimum-angled flap edge after the applanation (A & B). Planar rim cut at approximately 30º (C).
Source: Femto LDV Z8; Surgical procedure manual Cornea; Ziemer Ophthalmology.

 

 

Figure 2. Flap morphology in planar (3D) flaps. Side (upper row) and top (lower row) views on the 3D LASIK flap. The flap is
generated after applanation combining a strictly horizontal plane with a 90º side cut (A & B). Additional venting tunnels (optionally
2–5 tunnels, see lower row) have to be created to release the otherwise enclosed air.
Source: Femto LDV Z8; Surgical procedure manual Cornea; Ziemer Ophthalmology.

from the center of the flap. In total, 36 thickness
measurements were analyzed for each flap. The
mean FT achieved with the FS200 was 105.7 ±
2.6 µm, which was significantly less (P < 0.01)
than for the VisuMax (111.2 ± 2.3 µm).[17] Although
both lasers used the 3D cutting geometry, the
VisuMax results were found to be closer when
corresponding to our 3D group. In our study,
seeing that no statistically significant differences
were found between the central and overall FT (13
points) results for both cutting geometry groups,
we can conclude that both 2D and 3D flap-cutting
geometries demonstrated high precision in terms
of FTs.

Regarding our subjective intraoperative flap
morphology findings, despite no statistically
significant differences between both groups, both

surgeons (SL, JS) noted from a clinical perspective
a tendency toward a more homogeneous interface
with a less adhesive flap and less OBL in the
2D flap geometry. Regarding postoperative self-
reported pain perception and visual experience
stratified between 2D and 3D flap geometry
groups, the patients were unaware of which eye
received 2D or 3D flap morphology (i.e., blinded
study design). For seven eyes (31.8%) “no pain” was
reported. Four of them belonged to the 2D group.
However, despite not being statistically significant
in our 22 eyes-analyses, higher pain scores were
reported for some of the eyes treated with the
“3D-flap”. Regarding the subjective visual quality
assessment, no differences could be identified.
Minutes after waking up the first morning post
operation, for 10 eyes (equally distributed between

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Two Different Femto-LASIK Flaps; Steinberg et al

 

Figure 3. Intraoperative OCT before flap lifting. The yellow line defines the cut position.

 

Figure 4. The mean differences of flap thickness from 110 µm. Squares: Mean differences from 110 µm. Dashed lines equivalence
bounds (–4.58; 4.58). Thick line around differences is TOST (Two One-Sided Tests) confidence interval. 2D 90% CI (–0.207; 1.54);
3D 90% CI (0.311; 2.113). Thin line NHST (Null Hypothesis Significance Test) 95% confidence interval. 2D 95% CI (–0.407; 1.741);
3D 95% CI (0.105; 2.32).

2D and 3D eyes), patients rated their visual acuity
to be “as good as with glasses before treatment”.
No statistically significant differences between
intraoperative flap quality and patient’s perception
could be demonstrated during the first hours after
the treatment. However, differences between
both flap geometry groups regarding a tendency
toward more adhesive and more OBL-prone flaps,
potentially leading to the perceived (patient)
discomfort in 3D flaps as compared to 2D flap
geometry group, were clinically noticed.

Furthermore, it is important to keep in mind
that the analyses of the intra-op flap-/interface
morphology and the patients’ postoperative
assessments were secondary objectives of the
study. Since the power analysis was based on the
primary objective, that is, comparing the central

FT predictability in both flap geometries and by
taking the contralateral character of the study
into account, we had to limit the number of eyes
included in the study.

In case clinically relevant differences regarding
subjective pain perception and morphology are
to be assessed, bigger sample sizes would be
necessary for future investigations. However, due
to the low number of eyes included, the Fisher’s
exact test was used in these analyses. Our P-
values > 0.05 indicate no correlation between
the different categories and the 2D and 3D flap
morphologies.

Technically, each flap-cutting geometry has its
own special advantages. As mentioned, the 2D
flap-cutting geometry only exists in the low-energy

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Two Different Femto-LASIK Flaps; Steinberg et al

 

Figure 5. Schematic illustration to display the four measurement points in each meridian.

high-spot density FEMTO LDV Z8 laser and its
predecessors.

Due to the nature of the 2D flap configuration,
one would expect it to be relatively easy when
lifting such a flap. With the FEMTO LDV Z8, not only
are round flaps (as with the 2D) are a possibility
but oval-shaped flaps can also be created with
the 3D flap-cutting geometry tool. According to the
patient requirements, 3D flap geometries can be
resized or repositioned on the patient’s eye, and
side cut angles can be programmed from 30º to
150º around the globe.

The biggest advantage of the low-energy
FEMTO LDV Z8 is the additional software option
that exists called Optima which allows the surgeon
to start with a 2D flap approach and switch
intraoperatively to a 3D flap-mode after docking.
As 2D flaps are generated without an angled
site-cut, these flaps have to be created in the
center of the applanated corneal surface. Adjusting
the flap position after applanation would lead to
a potentially irregular flap shape and/or a much
too small or long hinge-configuration. Therefore,
no such option for the surgeon exists other than
in 3D flap-creation. With the 3D, angled side-cut
geometry, even after applanation of the cornea,
the surgeon can change settings including the flap
position as well as the hinge position based on a
live image. As mentioned before, the angled side
cut in 3D geometry flaps creates a perfectly fitting
angled flap and interface morphology believed to

contribute toward flap stability which might lead to
a decreased number of flap striae and/or epithelial
ingrowth.[5–7]

Considering the aforementioned advantages
and disadvantages of 2D versus 3D flap
geometries as well as the flexibility to
intraoperatively switch after docking in case
the surgeon wants to shift the centration before
flap-cutting commences, the low-energy FEMTO
LDV Z8 seems to be the preferred choice in
performing LASIK surgeries.

One of the limitations of our study was the lack
of comparison of the induced corneal higher order
aberrations (HOA) due to flap striaes which would
be another important parameter when comparing
the two flap-cutting techniques. As a result, it is
recommended that we research this aspect for
follow-up studies. Another limitation occurred with
our small sample size as we had to limit the number
of eyes included in our study to properly achieve
our primary objective.

In summary, this study compared two different
flap morphologies created during LASIK, whilst
using the same low-energy, high-frequency OCT-
equipped fs laser. Both the 2D and 3D flap-cutting
geometries demonstrated comparable precision
and predictability in terms of FTs combined with a
high safety and efficacy performance.

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Two Different Femto-LASIK Flaps; Steinberg et al

Table 6. Summary of pre- and postoperative uncorrected visual acuity( logMAR).

Characteristics Category 2D(n = 11) 3D(n = 11) Overall(n = 22) P-value**

Preop UCVA n (missing) 11 (0) 11 (0) 22 (0)

Mean (SD) 0.91 (0.32) 1.03 (0.39) 0.97 (0.36) 0.4224

95% CI 0.69; 1.12 0.77; 1.30 0.81; 1.13

Median 1.00 1.00 1.00

Q1; Q3 0.70; 1.10 0.88; 1.10 0.80; 1.10

Min; Max 0.2; 1.3 0.4; 2.0 0.2; 2.0

One day post-op
UCVA

n (missing) 11 (0) 11 (0) 22 (0)

Mean (SD) 0.11 (0.08) 0.10 (0.04) 0.11 (0.06) 0.5668

95% CI 0.06; 0.17 0.07; 0.13 0.08; 0.14

Median 0.10 0.10 0.10

Q1; Q3 0.10; 0.18 0.10; 0.10 0.10; 0.10

Min; Max 0.0; 0.3 0.0; 0.2 0.0; 0.3

One week post-op
UCVA

n (missing) 11 (0) 11 (0) 22 (0)

Mean (SD) 0.06 (0.08) 0.06 (0.11) 0.06 (0.09) 1.0000

95% CI 0.01; 0.11 0.00; 0.14 0.02; 0.10

Median 0.00 0.00 0.00

Q1; Q3 0.00; 0.10 0.00; 0.18 0.00; 0.10

Min; Max 0.0; 0.2 0.0; 0.3 0.0; 0.3

One month post-op
UCVA

n (missing) 11 (0) 11 (0) 22 (0)

Mean (SD) 0.01 (0.03) 0.00 (0.00) 0.00 (0.02) 0.3293

95% CI 0.00; 0.03 0.00; 0.00 0.00; 0.01

Median 0.00 0.00 0.00

Q1; Q3 0.00; 0.00 0.00; 0.00 0.00; 0.00

Min; Max 0.0; 0.1 0.0; 0.0 0.0; 0.1

P-value* <0.0001

Financial Support and Sponsorship

None.

Conflicts of Interest

None.

REFERENCES

1. Kim TI, Alió Del Barrio JL, Wilkins M, Cochener B, Ang M.
Refractive surgery. Lancet 2019;393:2085–2098.

2. Moshirfar M, Bennett P, Ronquillo Y. Laser in situ
keratomileusis. Treasure Island, FL: StatPearls; 2021.

3. Pajic B, Vastardis I, Pajic-Eggspuehler B, Gatzioufas
Z, Hafezi F. Femtosecond laser versus mechanical

microkeratome-assisted flap creation for LASIK:
A prospective, randomized, paired-eye study. Clin
Ophthalmol 2014;8:1883–1889.

4. Pietilä J, Huhtala A, Mäkinen P, Salmenhaara K, Uusitalo
H. Laser-assisted in situ keratomileusis flap creation
with the three-dimensional, transportable Ziemer FEMTO
LDV model Z6 I femtosecond laser. Acta Ophthalmol
2014;92:650–655.

5. dos Santos AM, Torricelli AA, Marino GK, Garcia R, Netto
MV, Bechara SJ, et al. Femtosecond laser-assisted LASIK
flap complications. J Refract Surg 2016;32:52–59.

6. Güell JL, Elies D, Gris O, Manero F, Morral M.
Femtosecond laser-assisted enhancements after laser in
situ keratomileusis. J Cataract Refract Surg 2011;37:1928–
1931.

7. Letko E, Price MO, Price FW Jr. Influence of original flap
creation method on incidence of epithelial ingrowth after

JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 18, Issue 1, January-March 2023 13



Two Different Femto-LASIK Flaps; Steinberg et al

LASIK retreatment. J Refract Surg 2009;25:1039–1041.
8. Mastropasqua L, Calienno R, Lanzini M, Salgari N,

De Vecchi S, Mastropasqua R, et al. Opaque bubble
layer incidence in Femtosecond laser-assisted LASIK:
Comparison among different flap design parameters. Int
Ophthalmol 2017;37:635–641.

9. Cummings AB, Cummings BK, Kelly GE. Predictability of
corneal flap thickness in laser in situ keratomileusis using
a 200 kHz femtosecond laser. J Cataract Refract Surg
2013;39:378–385.

10. Prakash G, Agarwal A, Yadav A, Jacob S, Kumar DA,
Agarwal A, et al. A prospective randomized comparison of
four femtosecond LASIK flap thicknesses. J Refract Surg
2010;26:392–402.

11. Zheng Y, Zhou Y, Zhang J, Liu Q, Zhai C, Wang Y.
Comparison of laser in situ keratomileusis flaps created by
2 femtosecond lasers. Cornea 2015;34:328–333.

12. Eldaly ZH, Abdelsalam MA, Hussein MS, Nassr MA.
Comparison of laser in situ keratomileusis flap morphology
and predictability by wavelight FS200 Femtosecond laser
and Moria microkeratome: An anterior segment optical
coherence tomography study. Korean J Ophthalmol
2019;33:113–121.

13. Reinstein DZ, Sutton HF, Srivannaboon S, Silverman
RH, Archer TJ, Coleman DJ. Evaluating microkeratome
efficacy by 3D corneal lamellar flap thickness accuracy
and reproducibility using Artemis VHF digital ultrasound
arc-scanning. J Refract Surg 2006;22:431–440.

14. Ahn H, Kim JK, Kim CK, Han GH, Seo KY, Kim EK, et al.
Comparison of laser in situ keratomileusis flaps created
by 3 femtosecond lasers and a microkeratome. J Cataract
Refract Surg 2011;37:349–357.

15. Ju WK, Lee JH, Chung TY, Chung ES. Reproducibility
of LASIK flap thickness using the zeiss femtosecond
laser measured postoperatively by optical coherence
tomography. J Refract Surg 2011;27:106–110.

16. Zheng Y, Zhou Y, Zhang J, Liu Q, Zhai C, Wang Y.
Comparison of laser in situ keratomileusis flaps created by
2 femtosecond lasers. Cornea 2015;34:328–333.

17. von Jagow B, Kohnen T. Corneal architecture of
femtosecond laser and microkeratome flaps imaged
by anterior segment optical coherence tomography. J
Cataract Refract Surg 2009;35:35–41.

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