Original Article

Ray Tracing versus Thin-Lens Formulas for IOL Power
Calculation Using Swept-Source Optical Coherence

Tomography Biometry

Reza Ghaffari1,2, MD; Parisa Abdi1, MD; Alireza Moghaddasi1, MD; Somayeh Heidarzadeh1, MS; Hossein
Ghahvhechian3, MD; Maryam Kasiri1, MS

1Eye Research Center, Department of Cornea, Farabi Eye Hospital, Tehran University of Medical Sciences, Tehran, Iran
2Stein Eye Institute and Department of Ophthalmology, David Geffen School of Medicine at the University of California, Los

Angeles (UCLA), Los Angeles, California, USA
3Eye Research Center, The Five Senses Health Institute, Rassoul Akram Hospital, Iran University of Medical Sciences, Tehran,

Iran

Abstract

Purpose: To evaluate the ray tracing method’s accuracy employing Okulix
ray tracing software and thin-lens formulas to calculate intraocular lens (IOL)
power using a swept-source optical coherence tomography (SS-OCT) biometer
(OA2000).
Methods: A total of 188 eyes from 180 patients were included in this study. An
OA-2000 optical biometer was used to collect biometric data. The predicted
postoperative refraction based on thin-lens formulas including SRK/T, Hoffer
Q, Holladay 1, and Haigis formulas and the ray tracing method utilizing the
OKULIX software was determined for each patient. To compare the accuracy
of approaches, the prediction error and the absolute prediction error were
determined.
Results: The mean axial length (AL) was 23.66 mm (range: 19–35). In subgroup
analysis based on AL, in all ranges of ALs the ray tracing method had the lowest
mean absolute error (0.56), the lowest standard deviation (SD; 0.55), and the
greatest proportion of patients within 1 diopter of predicted refraction (87.43%)
and the lowest absolute prediction error compared to the other formulas (except
to SRK/T) in the AL range between 22 and 24 mm (all P < 0.05). In addition, the
OKULIX and Haigis formulas had the least variance (variability) in the prediction
error in different ranges of AL.
Conclusion: The ray tracing method had the lowest mean absolute error, the
lowest standard deviation, and the greatest proportion of patients within 1
diopter of predicted refraction. So, the OKULIX software in combination with SS-
OCT biometry (OA2000) performed on par with the third-generation and Haigis
formulas, notwithstanding the potential for increased accuracy in the normal
range and more consistent results in different ranges of AL.

Keywords: Biometry; Intraocular; Lenses; Optical Phenomena; Phacoemulsification

J Ophthalmic Vis Res 2022; 17 (2): 176–185

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OCT Biometry; Ghaffari et al

INTRODUCTION

Accurate intraocular lenses (IOL) power calculation
and precision refractive outcomes following
cataract surgery are now seen as a critical
component in determining the success of
refractive surgery. In recent years, there have been
advancements in this field with the introduction
of newer devices for ocular biometry and IOL
power calculation formulas. However, choosing
the best method for IOL power calculation is still a
challenging issue.[1, 2]

Since 1999, with the introduction of IOL Master,
optical biometry has established itself as the
standard for axial length (AL) measurement.
Since 2009, newer devices such as the AL-Scan
(Nidek Co, Aichi, Japan), Lenstar (Haag-Streit,
Switzerland), Aladdin (Topcon EU, Tokyo, Japan),
and IOL Master 700 (Carl Zeiss Meditec AG,
Jena, Germany) have been launched and made
accessible. Each of these biometers are made
up of four closely related technologies: optical
low-coherence interferometry (OLCI), optical low-
coherence reflectometry (OLCR), partial coherence
interferometry (PCI), and swept-source optical
coherence tomography (SS-OCT).[3–6]

The OA-2000 (Tomey, Nagoya, Japan) has
lately superseded the OA-1000 model. The OA-
2000, which was just released, employs SS-OCT
with a laser wavelength of 1060 nm. The AL,
anterior chamber depth (ACD), crystalline lens
thickness (LT), central corneal thickness (CCT),
corneal diameter (CD), pupil size, and keratometry
(K) could all be examined with this equipment.[7,8]
A firm agreement has also been reported between
the OA-2000 and the reference IOL Master 500
biometer for almost all biometry measurements.[9]

Concerning the IOL power calculation formulas
most commonly used in clinical practice, the
thin-lens formulas, including the third-generation

*Correspondence to:

Hossein Ghahvehchian, MD. Rassoul Akram Hospital,
Sattarkhan Niayesh St., Tehran 1455364, Iran.
Email: hosein_gh1370@yahoo.com
Received: 10-08-2019 Accepted: 25-12-2021

Access this article online

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

DOI: 10.18502/jovr.v17i2.10788

theoretical and fourth-generation formulas like
Haigis, are currently widely used by cataract
surgeons. The Gullstrand eye model is the main
structure of these formulas. In this mode, it is
assumed that the cornea is a thin optical lens
with a refractive index of 1.3375 (or 1.3315 in
the Haigis formula) and a constant ratio of the
anterior/posterior curvature, along with Gaussian
optics assumptions which only apply to paraxial
rays, are the basis of all of these formulas.[2]

As an alternative approach, ray-tracing
technology has been applied for IOL power
calculation with promising results in both
nonoperated eyes, especially in high myopic
and hyperopic patients, and post-refractive
surgery eyes.[10,11] The ray-tracing method offers
the potential to increase IOL power calculation
accuracy by considering the geometric and
optical properties of different interfaces like the
cornea and the IOL, taking into account the effect
of aberrations like spherical aberrations, and
performing analyses of single rays limited only
by the pupillary zone.[12,13] As a result, in order
to design lenses and optical systems, the ray
tracing method has now become the standard
technique.[14]

In this investigation, the OKULIX ray-tracing
program was used to assess the accuracy of
IOL power calculation, which combines corneal
topography data for IOL power calculation, in
comparison with the second- and third-generation
formulas and the fourth-generation Haigis formula
using an SS-OCT biometer (OA- 2000).

METHODS

This prospective study was conducted between
May 2015 and May 2016. The Institutional Review
Board of our Hospital approved the study protocol,
and the study was conducted by the tenets of the
Declaration of Helsinki. Written informed consent
was obtained from all participants.

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: Ghaffari R, Abdi P, Moghaddasi A, Heidarzadeh
S, Ghahvhechian H, Kasiri M. Ray Tracing versus Thin-Lens Formulas for
IOL Power Calculation Using Swept-Source Optical Coherence Tomography
Biometry. J Ophthalmic Vis Res 2022;17:176–185.

JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 2, April-June 2022 177

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OCT Biometry; Ghaffari et al

Study Population

This study included 188 eyes of 180 patients
who had visually significant cataracts. Patients
with a history of previous intraocular or refractive
surgery, corneal grafts, corneal scars, keratoconus,
edema, pseudoexfoliation syndrome, glaucoma,
and posterior segment disease (e.g., macular hole,
neovascular age-dependent maculopathy, macular
edema, or geographic atrophy) were excluded
from the study. Patients with intraoperative
complications like decentered capsulorhexis, tear
in the anterior or posterior capsule, vitreous loss,
or those with a postoperative best-corrected visual
acuity (BCVA) < 20/40 were excluded as well.

Preoperative Measurements

Complete ophthalmic examinations, including
visual acuity testing, tonometry, and fundus
examination, were performed before surgery.

Biometric data including AL, ACD, CCT, and
LT were collected using the OA 2000 optical
biometer (Nagoya, Japan, software V.1.0R) in the
immersion mode. A swept-source laser with a
wavelength of 1060 was used to measure the
optical distance between ocular surfaces. The
device can analyze corneal curvature in nine rings,
each with 256 points in a 5.5 mm zone using
placido-based topography of the anterior corneal
surface. To experience the best correlation with
the IOL Master, keratometry values in the 2.5
mm optical zone were utilized for the IOL power
calculation for the thin-lens formulae. The IOL
power for each patient was chosen in accordance
with the intended refraction of 0.00 D.

The IOL power and the predicted postoperative
refraction based on thin-lens formulas, third-
generation formulas (SRK/T, Hoffer Q, and Holladay
1), and the fourth-generation Haigis formula were
determined by the device software for each
patient. The optimized IOL constants for each
IOL and formula provided by the User Group for
Laser Interference Biometry (Available at http:
//www.augenklinik.uniwuerzburg.de/ulib/c1.htm,
accessed April 12, 2017) were used for calculations.

Ray-tracing Method

OKULIX ray-tracing program (Tedics Peric & Jöher
GbR, Dortmund, Germany) was used to assess

the IOL power and also to forecast postoperative
refraction while relying upon the implanted IOL
type used for the ray-tracing method.

OKULIX is a software that calculates the IOL
power using corneal topography and has been
used extensively in prior cases.[2] The program is
capable of modeling the monochromatic optical
capacities of the pseudophakic human eye.

Unlike Gaussian optics-based formulas, which
are only applicable for paraxial rays, OKULIX
performs an analysis of single rays limited only
by the pupillary zone, taking into account the
effect of spherical aberration. Ray tracing covers
the region between the fovea and the cornea.
The software also considers the effect of oblique
incidence of light rays (Stiles-Crawford effect). Light
rays undergo refractions on different interfaces
(vitreous, lens, aqueous humor, cornea), and the
refractive index changes at each interface. The
Okulix database contains labeled IOL data, such
as anterior and posterior vertex radii, central
thickness, refractive index, and asphericity of both
surfaces for aspheric IOLs.

The pupil size in the ray-tracing software was
set at 2.5 mm at iris plane. All calculations of
the OKULIX were set for the optimal focus, that
was described by the International Organization
for Standardization (ISO 11979-2) as the ray that
contacts the pupil plane at a determined distance
(𝑑 = 0.5 × √2 × 𝑝𝑢𝑝𝑖𝑙 𝑑𝑖𝑎𝑚𝑒𝑡𝑒𝑟) for each
meridian. The position of the postoperative IOL
was determined using an algorithm based on ACD
and crystalline LT.[13]

Surgical Technique

All patients underwent phacoemulsification
performing a 2.8 mm temporal approach with
astigmatically neutral or near-neutral posterior
limbal incisions.[16] Aiming at a 5-mm capsulorhexis
size, the standard phacoemulsification technique
was used to remove the cataract. The following
spherical monofocal IOLs, C-flex 570C (Rayner
Intraocular Lenses Ltd, East Sussex, UK), Rayner
Superflex 620H, and Acry-Sof SA60AT (Alcon
Alcon Laboratories Inc, Ft Worth, Texas), and an
aspheric IOL, Rayner Superflex Aspheric 920H
(Rayner) were selected, assigned, and implanted
in the capsular bag of the respective patients. IOL
power selection was based on the AL. The SRK-T
was used in AL > 26, Holladay 1 for AL between 22

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OCT Biometry; Ghaffari et al

and 26, and the Hoffer-Q in AL < 22. All operations
were performed by the same experienced surgeon
(RG).

Outcome Measures

The prediction error (PE) and absolute PE were
used to assess accuracy (AE). The difference
between the spherical equivalent (SE) of the
refraction predicted by the formula for the
implanted IOL and the actual postoperative
refraction was designated as the PE. Subjective
refraction using a 6-m acuity chart was employed
to detect manifest refraction one month
postoperatively.

Statistical Analysis

The mean, median, and standard deviation
(SD) of PE and absolute PE were calculated to
show the distribution of the data. The formulas
were compared using linear mixed models and
pairwise comparisons with Bonferroni correction
after accounting for inter-eye correlation. The
heterogeneity of the variances was analyzed
by the Leven’s Test. Subgroup analysis based
on the AL and IOL type was also done by
pairwise comparisons with Bonferroni correction.
The percentage of eyes within the predicted
refractions of 0.25, 0.5, and 1 D for each formula
was calculated, and the significance of their
differences was analyzed by the generalized
estimating equation (GEE) analysis.

RESULTS

The study included 188 eyes of 180 patients (100
women; mean age, 62.4 ± 10.4 years). The mean
AL was 23.66 ± 2 mm (range: 19–35). Table 1 shows
the distribution of the AL in our patients.

The implanted IOL models included the Rayner
C-flex 570C (59 eyes), Rayner Superflex 620H (22
eyes), Rayner Superflex Aspheric 920H (70 eyes),
and Acry-Sof SA60AT (37 eyes).

The mean power of the implanted IOLs was
18.87 ± 6.12 D (range: –9 to 39) and the mean
postoperative manifest refraction was 0.1 ± 0.78
D (range: –4.62 to +2.75). In four patients, the
postoperative absolute refractive SE error was
more than 2 D.

The mean and SD of the PE and AE of all seven
formulas, and the percentage of the patients within
the predicted refractions of 0.25, 0.5, and 1 D for
each formula have been shown in Table 2.

Comparison of the PE between different
formulas showed the significant superiority of
the Okulix formula in terms of the lowest mean
AE (MAE), the lowest SD, and the narrowest
range of PE. The heterogeneity of variances was
significantly based on Leven’s test (P < 0.001).

As shown in Table 3 and Figure 1, pairwise
comparisons of the formulas with Bonferroni
correction revealed statistically significant lower
values in the MAE of the Okulix as compared
to other formulas (all P < 0.05). There were
no significant differences between the SRK/T,
Hoffer Q, Holladay 1, Haigis standard, and Haigis
optimized formulas.

Comparison of the PE of the formulas in
subgroup analysis based on the AL using pairwise
comparisons with the Bonferroni correction
showed that the Okulix had the lowest MAE as
compared to other formulas (Except SRK/T) in
the AL range of 22–24 mm (Table 4). There were
no statistically significant differences between
formulas in the subgroup analysis based on the AL
[Figure 2].

Regarding the percentage of eyes within the
predicted refractions of 0.25, 0.5, and 1 D, although
the Okulix had the highest proportion of the eyes
in each group [Table 2 and Figure 3], based on the
GEE analysis for the percentage of eyes within the
0.25 and 0.5 D, the difference was not significant.
However, there was a significant difference in
the percentages of eyes within 1 D of predicted
refraction between the Okulix and all the other
formulas (P < 0.05).

The distribution of the PE and AE error for
each formula based on the AL has been shown in
Figures 4 and 5, respectively. As shown in these
figures, the Okulix and Haigis formulas had the
least variability (minimum variance) of change in the
PE in different ranges of AL. In subgroup analysis
based on the implanted IOL type using the linear
mixed model and ad-hoc Bonferroni’s test, third-
generation formulas did not seem to favor one IOL
model over others. There was significant precision
calculated for C-flex 570C among other IOLs for the
Okulix (P < 0.05), however, no statistical difference
was found between the Okulix and other formulas
in subgroup analysis for other IOLs. The detailed

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OCT Biometry; Ghaffari et al

Table 1. The axial length measurements of patients and the frequency of axial length ranges

Mean Median SD Range Frequency (%)

<22 mm 22-24 mm 24-26 mm 26-30 mm >30 mm Total
23.66 mm 23.29 mm ±2.07 19 to 35 mm 22(11.7) 112(59.6) 37(19.7) 13(6.9) 4(2.1) 188(100)

SD, standard deviation

Table 2. Prediction and absolute prediction error and percentage of patients within the predicted refraction for each formula

Formula PE AE % Within Predicted
Refraction

Mean SD Median Range Mean SD Median Range ±0.25D ±0.50 D ±1.00 D
SRK/T 0.18 1.07 0.18 -4.14 to 4.09 0.75 0.79 0.50 0.01 to 4.14 25.00 50.53 78.19

Hoffer Q 0.13 1.06 0.11 -5.11 to 3.97 0.74 0.77 0.48 0.02 to 5.11 20.21 53.19 76.60

Holladay 1 0.16 1.02 0.12 -4.72 to 4.03 0.71 0.75 0.48 0.01 to 4.72 24.47 53.72 80.32

Haigis 0.24 1.06 0.20 -5.53 to 4.31 0.71 0.82 0.49 0.00 to 5.53 25.00 52.66 80.85

Okulix 0.09 0.79 0.01 -1.89 to 1.49 0.56 0.55 0.47 0.01 to 1.89 29.94 55.69 87.43

PE, prediction error; AE, absolute prediction error; SD, standard deviation

results based on the IOL type have been shown as
supplemental data [Table 1].

DISCUSSION

Our study results showed that the ray tracing
method using the Okulix software together with
the OA- 2000 swept-source optical biometer
performed comparable other third-generation and
Haigis formulas.

The mean AL of our study population was 23.66
mm, which is within the range of the mean AL
reported in the normal population. Incidentally, our
study included a vast range of ALs (19–35 mm) and
patients with short (11.7 % with AL < 22 mm) and
long eyes (9% with AL > 26 mm).

In this study, based on a pairwise comparison of
the formulas, the Okulix had the lowest absolute
error when the analysis included all ALs. However,
in subgroup analysis based on AL, the difference
in absolute error was statistically significant in the
AL 22–24 mm (except to SRK/T). There were no
significant differences between the other third-
generation and Haigis formulas when the AL was
not considered.

The good results of the ray-tracing method may
be due to the fact that the ray tracing uses the
exact Snell’s law as compared to the conventional
thin-lens formulas which rely on Gaussian optics

assumptions which apply only to the paraxial rays
in the optical system. Therefore, it can model the
human eye optics more precisely.[11,17] The ray-
tracing also incorporates corneal topography data,
which means it may be more accurate in calculating
corneal power since more wide surface data is
entered into the ray-tracing program.[17]

Incorporation of the crystalline lens position
and thickness as biometric parameters in
addition to factors like the AL for prediction
of the postoperative pseudophakic ACD could
be another reason for improved results of the
ray-tracing method in our study. Hoffman et
al reported improved results (9% reduction in
the MAE) by taking into account the effect of
the crystalline lens position and thickness in
the algorithm used to predict the postoperative
IOL position as compared to the algorithm only
using the AL [Appendix1].[13] Some other modern
formulas like the Holladay 2 and Olsen also
employ the crystalline LT as an important biometric
measurement in their calculations for predicting
the effective lens position (ELP). This finding is
consistent with previous reports about PE of the
third-generation formulas.[18,19]

Regarding the relationship between the PE and
AL changes, the OKULIX and Haigis formulas had
the least variance in different ranges of the AL.
As shown in Figure 2, in normal and short ALs,

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Table 3. Pairwise Comparison of absolute prediction error between Okulix and other formulas

Formula(J) Mean
Difference(I-J)

SE P value 95% Confidence Interval for
Difference

SRK/T -0.180 0.037 < 0.001 -0.293 to -0.066
Okulix(I) Hoffer Q -0.168 0.036 < 0.001 -0.279 to -0.057

Holladay 1 -0.140 0.035 0.002 -0.247 to -0.033

Haigis -0.144 0.038 0.003 -0.260 to -0.029

SE, standard error

Figure 1. The absolute prediction error of each formula. Comparison of the prediction error of the formulas in subgroup analysis
based on the AL using pairwise comparisons with the Bonferroni correction showed that the OKULIX had the lowest MAE
compared to other formulas (all P < 0.05).

and especially in the AL 22–24 mm, there was
the least discrepancy between the formulas. As
the AL increased, remarkable differences could be
observed in each formula’s absolute error, so that
both the mean absolute error of each formula and
also the discrepancy between different formulas
increased in ALs > 26 mm. However, the OKULIX
had the lowest changes in the absolute error based
on the AL. These findings are in agreement with the
results of the study by Hoffman.[20] In this study, the
Holladay 1 formula in ALs < 24 mm and the Haigis
formula in ALs > 24 mm had the lowest error after
the OKULIX.

The methods used for prediction of the IOL
position in each formula could be a factor
explaining differences observed in multiple
ALs. Third-generation formulas use different IOL
constants, ALs, and keratometry readings for ELP

prediction. Using keratometry readings to calculate
the corneal height as a basis for this formula is
implicated as a source of error in ELP estimation in
different combinations of the AL and keratometry,
resulting in non-physiologic irregularities in the
prediction of the IOL power as described in the
SRK/T formula.[21,22] On the other hand, the use
of parameters like the AC depth in the Haigis
formula [which uses three different constants
a0, a1, a2 related to the IOL, AC depth, and AL,
respectively] and the AC depth and LT in the
OKULIX formula instead of indirect assumptions
based on keratometry readings is associated
with a higher degree of overall accuracy in the
prediction of the IOL position in different ranges of
the AL.

Similar to the results reported by Hoffman et
al comparing the accuracy of the OKULIX and

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OCT Biometry; Ghaffari et al

 

Figure 2. The absolute prediction error of the formulas based on the axial length. There were no statistically significant differences
between the other formulas in subgroup analysis based on the axial length.

Figure 3. Percentage of eyes within the predicted refraction in each formula. Regarding the percentage of eyes within the
predicted refractions of 0.25, 0.5, and 1 D, although the OKULIX had the highest proportion of the eyes in each group, the
difference was not significant based on the generalized estimating equation analysis for the percentage of eyes within the 0.25
and 0.5 D. However, there was a significant difference in the percentages of eyes within 1 D of predicted refraction between the
OKULIX and all the other formulas (P < 0.05).

the third-generation formulas, we observed results
that were on par among (and even more accurate
results in the AL 22–24 mm) these formulas.
However, unlike their results, we did not find any
significant superiority of the OKULIX formula in the
high myopic and hyperopic eyes, which may be

related to the small sample size of these patients
in this study population.

According to Figure 3, the number of cases with
refractive surprise was also lower in the OKULIX
than other formulas. The predicted error was 1 D
and lower in 87.5% of the patients based on the

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Figure 4. Distribution of absolute prediction errors based on axial length for each formula. The OKULIX and Haigis formulas had
the lowest magnitude of change in the absolute prediction error in different ranges of axial length. Most cases of refractive surprise
were myopic eyes with ALs > 26 mm.

 

 

Figure 5. Distribution of absolute prediction errors based on axial length for each formula. The OKULIX and Haigis formulas had
the lowest magnitude of change in the prediction error in different ranges of axial length.

OKULIX, while 80.7% of the patients based on the
Haigis and 78.2% based on the SRK/T formula were
within the PE of 1 D. According to Figure 4, most
cases of refractive surprise were myopic eyes with
ALs > 26 mm.

Hoffman et al compared the accuracy of the
ray tracing between aspheric aberration-correcting
and spherical IOLs and reported the particular
benefits of the ray tracing method for IOL power
calculation for aspheric IOLs.[20] In this study, we

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OCT Biometry; Ghaffari et al

did not find any significant differences between
aspheric and spherical IOL types, which may be
related to the smaller sample size of our study.

The relatively small sample size is the first
limitation of this study. We did not use optimization
for other third-generation and Haigis formulas for
comparisons which may be necessary for the final
achievable accuracy with these formulas since the
current software for the OKULIX on the OA-2000
device does not allow for optimization. However,
because the optimized IOL constants are not
usually available to the surgeon, the results of this
study are still valid in helping ophthalmologists to
choose the appropriate IOL power formula in the
clinical setting. In addition, we did not compare our
results with some other modern formulas like the
Holladay 2, Olsen, and Barret’s formulas. Another
limitation is the limited follow-up of our patients.
IOL position changes due to fibrosis of capsule that
could happen in the first three months after surgery
may cause refractive changes. However, there are
also papers[20,23−−26] using refraction at one month
as the outcome. It should also be mentioned that
using different IOL types could lead to variation in
refractive outcomes. However, due to limitations in
the power of lenses available, different types of IOL
were used in the study.

In summary, the results of this study
demonstrated that the ray tracing method using the
OKULIX software and the biometric data provided
by the new swept-source biometer yielded
comparable results with the third-generation and
Haigis formulas. Where all patients were included,
the OKULIX formula had the lowest mean absolute
error and a more constant pattern of performance
in different ranges of the AL when compared to
other formulas. Based on our results, the ray-
tracing method may be an accurate and robust
method for calculation of the IOL power in virgin
corneas.

Financial Support and Sponsorship

None.

Conflicts of Interest

The authors declare that there are no conflicts of
interest.

Appendix 1

The assumed postoperative IOL position is
calculated two formulas:[13]

1)

A𝑎= C𝑚× (
𝑎
𝑎𝑚)

0.7+ A𝑚– C𝑚– 0.5 × (d – d𝑚)

A𝑎= anterior chamber depth with the IOL in
the eye of interest
Cm = distance between the posteriorcornea and

center of a 21.00-D IOL in a mean-sized eye (4.6
mm)

a, am = axial length of the eye of interest and a
mean-sized eye (23.6 mm)

Am = anterior chamber depth with the IOL model
of interest in a mean-sized eye

d, dm = thickness of the IOL of interest and 21.00-
D IOL of the same model.

2)

A𝐿 = A𝐿 + 0.574 × t𝐿 – 0.632 – (0.5 × d)

A𝐿 = anterior chamber depth with the IOL in
the eye of interest
Ap = preoperative anterior chamber depth
t𝐿 = thickness of the crystalline lens
d = thickness of the IOL

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