Original Article

Accuracy of IOL Power Calculation Formulas for
AcrySof SN60WF versus Tecnis ZCB00 Intraocular

Lenses
Cynthia C Jiang, MD; Noah M Hodson, MD; Daniel A Johnson, MD, MBA; Ahmad Kheirkhah, MD

Department of Ophthalmology, University of Texas Health San Antonio, San Antonio, Texas, USA

ORCID:
Cynthia C Jiang: https://orcid.org/0000-0002-9371-0006
Ahmad Kheirkhah: https://orcid.org/0000-0003-4217-3367

Abstract

Purpose: To compare the accuracy of various intraocular lens power formulas for two
monofocal hydrophobic foldable lenses, the AcrySof SN60WF and the Tecnis ZCB00.
Methods: This retrospective study included 409 eyes from 409 patients who underwent
uncomplicated cataract surgery (299 eyes with SN60WF and 110 eyes with ZCB00).
Biometry was performed for all eyes with an IOLMaster 700. Predicted refraction from
five different IOL power formulas (Barrett Universal II, Haigis, Hoffer-Q, Holladay 2, and
SRK/T) was compared to postoperative refraction at one to three months for the following
axial length strata: short eyes (<22.5 mm), medium eyes (22.5–25.5 mm), and long eyes
(>25.5 mm).
Results: In patients with medium eyes, there were no significant differences in the mean
absolute error (MAE) and the percentage of eyes within ±0.5 D (%±0.5 D) between
both IOLs. In short eyes, although MAE was similar between both lenses, %±0.5 D was
significantly higher for Barrett Universal II in ZCB00 than in SN60WF (P = 0.01) while
Hoffer-Q and Holladay 2 performed equally for both lenses. In long eyes, ZCB00 had a
higher MAE than SN60WF for Barrett Universal II, Haigis, and Hoffer-Q. Additionally, in
long eyes, the percentage of eyes within %±0.5 D was significantly higher for SN60WF
than ZCB00 for all formulas (P < 0.001).
Conclusion: Although there were no significant differences in the formula accuracy
between these two lenses in medium eyes for all formulas and in short eyes for most
formulas, the accuracy decreased significantly in long eyes for ZCB00 compared to
SN60WF. The effect of IOL model on the postoperative outcomes should be further
investigated.

Keywords: Formula Accuracy; Intraocular Lens; SN60WF; ZCB00

J Ophthalmic Vis Res 2022; 17 (3): 344–352

Correspondence to:

Ahmad Kheirkhah, MD. Medical Arts and Research
Center, 8300 Floyd Curl Dr., San Antonio, TX 78229,
USA.
E-mail: Kheirkhah@uthscsa.edu
Received: 29-01-2021 Accepted: 17-01-2022

Access this article online

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

DOI: 10.18502/jovr.v17i3.11571

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: Jiang CC, Hodson NM, Johnson DA,
Kheirkhah A. Accuracy of IOL Power Calculation Formulas for
AcrySof SN60WF versus Tecnis ZCB00 Intraocular Lenses. J
Ophthalmic Vis Res 2022;17:344–352.

344 © 2022 Jiang et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E

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IOL Formula Accuracy for SN60WF vs ZCB00; Jiang et al

INTRODUCTION

Cataract surgery is now considered a form of
refractive surgery. There is an increasing demand
by patients to have optimal uncorrected distance
visual acuity postoperatively. In fact, it has been
shown that such vision is an important determinant
of patient’s satisfaction after cataract surgery.[1]
To achieve this goal, it is critical to have a
postoperative refraction which is as close as
possible to the target refraction. This is largely
dependent on choosing an intraocular lens (IOL)
with the most accurate power.[2, 3] To obtain such
IOL power, precise biometry as well as an accurate
formula for IOL power calculation are required.
However, there still remains the question of which
formula provides the most consistent and accurate
refractive outcome for each individual eye.

Many formulas have been developed to
calculate the IOL power.[4–7]Each of these formulas
takes into consideration certain variables of
the eye, such as corneal power, axial length,
anterior chamber depth, or effective lens position,
in order to predict the power of the lens.[8, 9] The
parameters utilized in these equations vary by each
formula which is why accuracy of these formulas
varies widely.[10–13] Furthermore, it has been shown
that physical and biometric characteristics of
the eye can affect the accuracy of different IOL
power formulas to different degrees.[14, 15] For
example, there have been several studies that
have investigated the effects of abnormal values of
different parameters, such as long and short eyes,
on the accuracy of IOL power calculations.[16−−20]
Although many studies have evaluated the effects
of ocular characteristics on the accuracy of
IOL power, the possible effects of the type of
IOL on this accuracy remains unknown. This is
critical as different IOLs have different physical
characteristics.[21, 22] Multiple previous studies
relied on a single type of IOL,[19, 23–25] or grouped
multiple IOLs into a single dataset.[14, 18, 26, 27] In
addition, it remains unclear whether some formulas
play better for some lenses than for others.

To evaluate the possible effects of the IOL type
on the accuracy of IOL power formulas, in this
study we compared this accuracy for two different
models of IOL. For this, we used two aspheric
monofocal hydrophobic acrylic lenses, the AcrySof
SN60WF (Alcon Laboratories, Inc., Fort Worth, TX,
USA), and the Tecnis ZCB00 (Johnson & Johnson

Vision, Santa Ana, CA, USA), both of which are
commonly used in cataract surgery.

METHODS

This retrospective study included 409 eyes from
409 patients who had cataract surgery with
implantation of either AcrySof SN60WF or Tecnis
ZCB00. The study was performed at UT Health
San Antonio, San Antonio, Texas, USA. The study
protocol was approved by the Institutional Review
Board, and the study was compliant with tenets of
the Health Insurance Portability and Accountability
Act (HIPAA) of 1996.

Inclusion criteria consisted of adult patients who
had undergone uncomplicated cataract surgery.
In patients with bilateral cataract surgery, only
data from the eye with the earliest surgery
were used. We included only eyes with available
data on electronic medical records regarding the
preoperative IOL power calculation for all formulas
studied and postoperative manifest refraction at
one to three months after surgery. We excluded
eyes with corneal or anterior segment disease or
trauma. We also excluded patients with previous
cornea- or lens-based refractive surgery.

For each patient, demographics, ocular
biometric values, the power of the IOL used in
surgery, and the one-to-three-month postoperative
manifest refraction were collected from electronic
medical records. All patients had biometry
performed with an IOLMaster 700 (Carl Zeiss
Meditec AG). The following biometric values
were collected: axial length, lens thickness,
anterior chamber depth, white-to-white diameter,
and keratometry. Furthermore, we gathered
the IOL power measured by five different IOL
power formulas. The formulas and optimized IOL
constants for SN60WF and ZCB00, respectively,
assessed in this study were Barrett Universal II
(lens factor = 1.88 and 2.09), Haigis (A0 = –0.769
and –1.302; A1 = +0.234 and +0.210; A2 = +0.217
and +0.251), Hoffer-Q (pACD = 5.64 and 5.80),
Holladay 2 (ACD constant = 5.601 and 5.786), and
SRK/T (A = 119.00 and 119.30).

To evaluate the accuracy of each formula, we
calculated the mean numerical error (MNE) and
the mean absolute error (MAE). The MNE was
defined as the average of actual postoperative
refraction minus the predicted refraction by the
IOL power formula used for the eye (actual

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IOL Formula Accuracy for SN60WF vs ZCB00; Jiang et al

refraction – predicted refraction).[28] The MAE was
defined as the average of the absolute values of
actual postoperative refraction minus the predicted
refraction for each formula. Moreover, we also
determined the percentage of eyes within 0.25
D (%±0.25 D), 0.5 D (%±0.5 D), 1.0 D (%±1.0 D),
and 2.0 D (%±2.0 D) of the predicted refraction
for each formula. We further stratified the eyes
into subgroups based on the axial length. These
subgroup strata were as follows: short eyes (<22.5
mm), medium eyes (22.5-25.5 mm), and long eyes
(>25.5 mm). Then, the aforementioned accuracy
parameters were evaluated in each subgroup of
axial length. No adjustment was performed for eyes
with long axial length.

Statistical Analysis

Statistical analysis was performed using SPSS (IBM,
version 25). Shapiro–Wilk test was first conducted
to evaluate the normality of data distribution.
Different qualitative and quantitative parameters
were compared between SN60WF and ZCB00
groups using Chi-square and Mann–Whitney tests,
respectively. Friedman test followed by post hoc
Bonferroni test was performed to compare the MNE
and the MAE among different formulas for each
lens. Percentage of eyes within a specific dioptric
range postoperatively was compared between the
two lenses using Chi-square and among different
formulas for each lens using Cochran’s Q test.

RESULTS

This study included 409 eyes from 409 patients
(253 women and 156 men) with a mean age of
70.6 ± 8.6 years (range, 41–91 years). There were
299 eyes with SN60WF and 110 eyes with ZCB00.
There were no significant differences between
the two groups regarding demographics or ocular
biometric values [Table 1]. However, postoperative
refraction was significantly different between the
two lenses (–0.17 ± 0.55 D for SN60WF vs –0.01
± 0.51 D for ZCB00, P = 0.02).

Table 2 demonstrates the MAE and the MNE
for each formula for both SN60WF and ZCB00
lenses. For the MAE, there were no significant
differences between both IOLs for any formula.
Although there were no significant differences in
the MAE among various formulas for SN60WF,
such difference reached statistical significance for

ZCB00, with SRK/T having the highest MAE and
Barrett Universal II and Holladay 2 showing the
lowest MAE (P < 0.01). For the MNE, there were
no significant differences between both IOLs for
all formulas except for Hoffer-Q in which the MNE
was significantly lower for SN60WF compared
to ZCB00 (P = 0.04). For SN60WF, there were
significant differences in MNE among various
formulas with Barrett Universal II and Holladay 2
having the highest and lowest MNE, respectively
(P < 0.01). For ZCB00, the difference in the MNE
among various formulas was statistically significant
and the highest and lowest MNE was seen in SRK/T
and Holladay 2 formulas, respectively (P < 0.01).

Table 3 shows the percentage of eyes within
±0.25 D, ±0.5 D, ±1.0 D, and ±2.0 D of the
predicted refraction for various formulas for both
lenses. There were no statistically significant
differences between the SN60WF and ZCB00
lenses for percentage of eyes within ±0.25 D, ±0.5
D, ±1.0 D, or ±2.0 D of the predicted refraction (all
P-values > 0.05). For both SN60WF and ZCB00,
there were statistically significant differences in the
percentage of eyes within ±0.25 D, ±0.5 D, and
±1.0 D, but not ±2.0 D, among various formulas.
For %±0.5 D, the highest percentage was seen by
Barrett Universal II for SN60WF (P < 0.001) and by
Barrett Universal II and Holladay 2 for ZCB00 (P =
0.02).

Effects of the Axial Length on the Formula
Accuracy

The MAE and percentage of eyes within ±0.5 D
for each formula across different axial lengths for
both IOLs have been shown in Tables 4 and 5,
respectively.

SN60WF lenses

In short and medium eyes, the MAE was similar
among various formulas. In long eyes, however,
the MAE was significantly different among various
formulas (P < 0.001), with Barrett Universal II
having the lowest and Hoffer-Q having the highest
values. Regarding %±0.5 D, there were significant
differences among formulas across all axial
lengths. The highest percentage of eyes ±0.5
D from the predicted refraction was seen with
Hoffer-Q in short eyes and by Barrett Universal
II in medium and long eyes. On the other hand,

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IOL Formula Accuracy for SN60WF vs ZCB00; Jiang et al

Table 1. Patient demographics and ocular biometric values for eyes with SN60WF and ZCB00 lenses.

SN60WF (n = 299) ZCB00 (n = 110) P-value

Age (yr) 70.71 ± 8.60 70.41 ± 8.63 0.57
Sex (F/M) 178/121 75/35 0.14

IOL power used in surgery
(D)

20.31 ± 3.21 20.59 ± 3.32 0.46

Axial length (mm) 23.85 ± 1.11 23.90 ± 1.07 0.74
Lens thickness (mm) 4.61 ± 0.41 4.57 ± 0.41 0.38
Anterior chamber depth
(ACD)

3.12 ± 0.39 3.17 ± 0.34 0.25

White-to-white diameter
(mm)

11.97 ± 0.44 12.00 ± 0.51 0.35

Mean keratometry (D) 43.88 ± 1.58 43.76 ± 1.69 0.48
Postoperative refraction (D) –0.17 ± 0.55 –0.01 ± 0.51 0.02

Table 2. Mean absolute error (MAE) and mean numerical error (MNE) for each formula for both SN60WF and ZCB00 lenses.

Formula Mean Absolute Error (MAE) Mean Numerical Error (MNE)

SN60WF ZCB00 P-value SN60WF ZCB00 P-value

Barrett Universal II 0.41 ± 0.37 0.42 ± 0.37 0.94 0.21 ± 0.52 0.28 ± 0.48 0.21
Haigis 0.42 ± 0.38 0.46 ± 0.38 0.24 0.14 ± 0.55 0.20 ± 0.56 0.30
Hoffer-Q 0.44 ± 0.38 0.48 ± 0.39 0.43 0.15 ± 0.56 0.29 ± 0.55 0.04
Holladay 2 0.42 ± 0.36 0.41 ± 0.36 0.69 0.09 ± 0.54 0.18 ± 0.51 0.23
SRK/T 0.49 ± 0.36 0.49 ± 0.66 0.66 0.15 ± 0.54 0.31 ± 0.76 0.07
∗P-value 0.27 0.002 <0.001 <0.001

∗This P-value is for comparison of different formulas in each lens.

the lowest %±0.5 D value was seen by Barrett
Universal II and Haigis in short eyes, by Hoffer-Q
in medium eyes, and by Hoffer-Q and Holladay 2
in long eyes.

ZCB00 lenses

In short eyes, the MAE was similar among various
formulas. In medium and long eyes, however,
the MAE was significantly different among various
formulas (P < 0.05). The lowest and highest
values of MAE were obtained by Holladay 2 and
SRK/T, respectively, in medium eyes, and by Barrett
Universal II and Hoffer-Q, respectively, in long eyes.
Although there were no significant differences in
the percentage of eyes within ±0.5 D in short
and long eyes, this value was significantly lower in
long eyes compared with short and medium eyes
for all formulas (all P-values < 0.05). In medium

eyes, there were significant differences in %±0.5
D among various formulas, with Holladay 2 having
the highest and Haigis having the lowest values.
For all formulas, the %±0.5 D was significantly
different among short–medium–long eyes (all P <
0.05).

SN60WF versus ZCB00 lenses

In short and medium eyes, the MAE was similar
between SN60WF and ZCB00. However, in long
eyes, the MAE was significantly higher in ZCB00
compared with SN60WF for Barrett Universal II
(P = 0.04), Haigis (P = 0.03), and Hoffer-Q (P =
0.04). In medium eyes, the %±0.5 D for ZCB00
and SN60WF was similar. However, in short eyes,
although there were no statistically significant
differences in %±0.5 D between both lenses for
Haigis, Hoffer-Q, and Holliday 2, ZCB00 had a

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IOL Formula Accuracy for SN60WF vs ZCB00; Jiang et al

Table 3. Percentage of eyes within ±0.25 D, ±0.5 D, ±1.0 D, and ±2.0 D of the predicted refraction for both SN60WF and ZCB00
lenses.

Formula SN60WF ZCB00

±0.25 D ±0.5 D ±1.0 D ±2.0 D ±0.25 D ±0.5 D ±1.0 D ±2.0 D
Barrett
Universal II

40.8% 70.6% 93.0% 99.7% 40.9% 68.2% 91.8% 100.0%

Haigis 41.5% 66.9% 91.6% 99.3% 39.1% 64.6% 89.1% 100.0%

Hoffer-Q 35.8% 65.9% 93.0% 99.7% 33.6% 66.4% 86.4% 99.1%

Holladay 2 40.5% 66.6% 92.6% 99.7% 43.6% 68.2% 92.7% 100.0%

SRK/T 38.5% 67.6% 93.0% 99.7% 37.3% 66.4% 90.9% 98.2%
∗P-value <0.001 <0.001 0.01 0.41 <0.001 0.02 0.001 0.17

*This P-value is for comparison of different formulas in each group.

Table 4. Mean absolute error (MAE) for SN60WF and ZCB00 lenses in short, medium, and long eyes.

Formula Short eyes (AL: <22.5 mm) Medium eyes (AL: 22.5–25.5 mm) Long eyes (AL: >25.5 mm)
SN60WF ZCB00 P-value SN60WF ZCB00 P-value SN60WF ZCB00 P-value

Barrett
Universal II

0.37 ± 0.26 0.34 ± 0.36 0.78 0.43 ± 0.38 0.40 ± 0.35 0.62 0.35 ± 0.34 0.69 ± 0.50 0.04

Haigis 0.36 ± 0.28 0.53 ± 0.41 0.11 0.44 ± 0.40 0.43 ± 0.35 0.93 0.36 ± 0.37 0.78 ± 0.57 0.03
Hoffer-Q 0.30 ± 0.24 0.33 ± 0.34 0.75 0.45 ± 0.38 0.45 ± 0.36 0.87 0.53 ± 0.40 0.95 ± 0.64 0.04
Holladay 2 0.30 ± 0.23 0.37 ± 0.38 0.67 0.43 ± 0.38 0.38 ± 0.33 0.31 0.45 ± 0.34 0.77 ± 0.58 0.08
SRK/T 0.36 ± 0.28 0.55 ± 0.51 0.36 0.44 ± 0.37 0.48 ± 0.68 0.48 0.41 ± 0.31 0.70 ± 0.52 0.21
P-value* 0.48 0.13 0.3 0.005 <0.001 0.04

∗This P-value is for comparison of different formulas in each axial length group.

higher %±0.5 D for Barrett Universal II (P = 0.01)
while SN60WF had a higher %±0.5 D for SRK/T (P
= 0.01). In long eyes, SN60WF had a higher %±0.5
D than ZCB00 for all formulas (P < 0.001 for all
formulas).

DISCUSSION

In this study, we evaluated the accuracy of five
IOL power formulas for two aspheric monofocal
hydrophobic acrylic foldable IOLs, the AcrySof
SN60WF, and Tecnis ZCB00. We found that the
accuracy of the IOL power formulas for these two
lenses varied based on the eye’s axial length.
Although there were no significant differences
in the accuracy between these two lenses in
medium eyes, the accuracy decreased in short
and especially long eyes where postoperative
refractive predictability was different for the
SN60WF and the ZCB00. Furthermore, relative

accuracy of each formula compared to others was
also dependent on the axial length and IOL type.

Although the accuracy of IOL power calculation
formulas and the role of ocular parameters in
such accuracy have been well studied, there are
limited data on the effects of IOL model on the
accuracy. Melles et al[28] compared two lenses
from the same manufacturer, AcrySof SN60WF
to SA60AT (Alcon), and found similar rankings of
seven IOL formulas (Barrett Universal II, Haigis,
Holladay 1, Holladay 2, Hoffer-Q, Olsen, and SRK/T,
and Hoffer-Q) between these two lenses. In our
study, however, we compared the IOL power
formula accuracy between two aspheric monofocal
acrylic hydrophobic lenses from two different
manufacturers as it has been shown that they
have different physical characteristics and visual
performance.[29, 34–36]

For evaluation of the accuracy of IOL power
formulas in this study we used the MAE, the

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IOL Formula Accuracy for SN60WF vs ZCB00; Jiang et al

Table 5. Percentage of eyes within ±0.5 D of the predicted refraction for SN60WF and ZCB00 lenses for short, medium, and
long eyes.

Formula Short eyes (AL: <22.5 mm) Medium eyes (AL: 22.5–25.5 mm) Long eyes (AL: >25.5 mm)
SN60WF ZCB00 P-value SN60WF ZCB00 P-value SN60WF ZCB00 P-value

Barrett
Universal II

70.0% 85.7% 0.001 69.6% 68.8% 0.87 81.8% 42.9% <0.001

Haigis 70.0% 57.1% 0.05 65.6% 66.7% 0.88 77.3% 42.9% <0.001
Hoffer-Q 83.3% 85.7% 0.55 64.4% 67.7% 0.55 59.1% 28.6% <0.001
Holladay 2 76.7% 71.4% 0.33 66.0% 70.8% 0.44 59.1% 28.6% <0.001
SRK/T 73.3% 57.1% 0.01 66.4% 68.8% 0.65 72.7% 42.9% <0.001
P-value* 0.02 0.16 <0.001 0.04 0.004 0.41

∗This P-value is for comparison of different formulas for each lens in each AL group.

MNE, and the percentage of eye within ±0.5 D
of the predicted refraction, as reported before.[37]
Gale et al[30] established the benchmark standards
for refractive outcomes as percentage of eyes
within ±1.0 D of the predicted refraction >85%
and percentage of eyes within ±0.5 D of the
predicted refraction >55%. Our data indicates this
benchmark was met for all formulas for all ranges of
axial length in SN60WF lenses. For ZCB00 lenses,
however, this benchmark was met for all formulas
only for short and medium eyes, but not for any
formula in long eyes, showing the effects of IOL
model on the accuracy of IOL power formulas.

Although the difference in the accuracy of
IOL power formulas between the two lenses
was less evident when all axial lengths were
taken together, the difference was more prominent
when evaluating eyes with different axial lengths
separately. In medium eyes with an axial length
of 22.5–25.5 mm, the MAE and the percentage
of eyes within ±0.5 D were similar between
SN60WF and ZCB00 for any formula. In short
eyes (<22.5 mm), however, although there was
no significant difference between the lenses in
the MAE, the percentage of eyes within ±0.5 D
was different between the two lenses for some
formulas such as Barrett Universal II in which
this formula performed better for ZCB00 than for
the SN60WF. The difference between the two
IOLs was most remarkable in long eyes with
an axial length >25.5 mm. In these eyes, the
MAE was significantly higher for ZCB00 compared
with SN60WF for most of the formulas evaluated
showing a potential error in IOL power calculation
in this IOL model. In addition, the percentage of

eyes within ±0.5 D was significantly higher for
SN60WF compared with ZCB00 for all formulas.
Although the reasons for such performance of IOL
power formulas for ZCB00 lenses in long eyes
remain to be determined, adjustment of IOL power
formulas may be considered for such situations.

It is well known that IOL power formulas have
different accuracies for eyes with different axial
lengths.[14,27] For all axial lengths combined, some
studies have indicated that Barrett Universal II has
a significantly lower MAE and highest percentage
within ±0.25 D, ±0.5 D, or ±1.0 D of the
target refraction than Haigis, Hoffer-Q, Holladay
1, Holladay 2, SRK/T, and T2 for SN60WF,[24]
and a lower MAE and highest percentage within
±0.25 D, ±0.75 D, or ±1.0 D of the target
refraction than Holladay 2, Hoffer-Q, and SRK/T
for ZCB00.[32] However, our findings showed that
formula performance is also dependent on the IOL
type. In fact, such accuracy can affect our choice of
IOL implant for each individual eye.

In medium eyes in our study, for SN60WF there
was no significant difference in the MAE between
formulas, but Barrett Universal II had the highest
percentage (69.6%) of eyes within ±0.5 D of the
predicted refraction. For ZCB00 lenses, in contrast,
Holladay 2 formula was associated with the lowest
MAE and the highest percentage (70.8%) of eyes
within ±0.5 D. Aristodemou et al[31] found similar
accuracy for eyes implanted with either LI61AO
Sofport or Akreos Fit (Bausch & Lomb, Rochester,
NY) with axial length between 22.50 and <25.00
mm when comparing the MAE between Hoffer-Q,
Holladay 1, and SRK/T. Narváez et al[33] similarly did
not find a difference between formulas (Hoffer-Q,

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IOL Formula Accuracy for SN60WF vs ZCB00; Jiang et al

Holladay 1, Holladay 2, and SRK/T) in average (22.0
to <24.5 mm) and medium-long (24.5 to <26.0 mm)
eyes implanted with either CC4204BF Collamer
plate-haptic IOL or AA4203VF silicone plate-haptic
IOL (STAAR Surgical, Monrovia, CA). Notably,
neither of those studies included Barrett Universal
II or compared SN60WF and ZCB00 lenses. Tang
et al[40] found no significant difference in accuracy
for short (<22.0 mm), medium (22.0–25.0 mm),
or long (>25.0 mm) eyes implanted with SN60WF
between Holladay 2, Barrett Universal II, and Hill-
RBF formulas. Kane et al[24] found statistically
significant differences in the MAE among seven
different formulas for their established ranges of
medium (22.0 to <24.5 mm) and medium-long
(24.5 to <26.0 mm) eyes implanted with SN60WF.
For both groups, Barrett Universal II had the
lowest MAE, and SRK/T performed better than both
Haigis and Hoffer-Q formulas for medium eyes
but not medium-long eyes.[24] Barrett Universal II
additionally had a significantly higher percentage
within ±0.25 D, ±0.5 D, ±1.0 D, or ±2.0 D for
medium eyes.[24] As previous studies have used
only one IOL model or considered all IOL models
together, no comparison can be made with our
findings.

For short eyes with axial length of <22.5 mm, we
did not find any significant difference in the MAE
and the percentage within ±0.5 D between the five
formulas for ZCB00 lenses. For SN60WF lenses,
although there was no significant difference in the
MAE for different formulas, the percentage within
±0.5 D was significantly higher in Hoffer-Q (83.3%).
Previously, it has been shown that neither Hoffer-Q,
Holladay 2, nor SRK/T consistently outperformed
one another in eyes implanted with Acrysof
SN60WF or SA60AT (Alcon Laboratories, Inc., Fort
Worth, TX) or LI61AO Sofport or Akreos Fit (Bausch
& Lomb, Rochester, NY) with an axial length <22.0
mm.[28, 31] In comparing the accuracy of Barrett
Universal II, Haigis, Hoffer-Q, Holladay 1, Holladay
2, SRK/T, and T2 formulas, Kane et al[24] did not
find any significant difference in formulas with an
axial length <22.0 mm in eyes implanted with
SN60WF. A 2017 meta-analysis investigating the
accuracy of six IOL power formulas (Haigis, Hoffer-
Q, Holladay 1, Holladay 2, SRK/T and SRK II) in
short eyes (axial length <22.0 mm) demonstrated
that although Holladay 2 offered the smallest MAE
(not statistically significant), Haigis may be superior
to Hoffer-Q (P = 0.003), SRK/T (P = 0.009), and
SRK/T II (P = 0.01) for short eyes.[38] The IOLs

used in this meta-analysis included SA60AT, MA60
(Alcon Laboratories, Inc., Fort Worth, TX), LI61A0
Sofport/Akreos Fit, AMO Sensar AR40e and Tecnis
ZA9003 (Johnson & Johnson Vision, Santa Ana,
CA), ACR6D (Laboratoires Cornéal, Paris, France),
Hoya PY-60AD (Hoya Corporation, Japan), and
SN60WF.[38]

For long eyes with an axial length of >25.5
mm, we noted that Barrett Universal II formula
had the lowest MAE compared with other four
formulas for both ZCB00 and SN60WF lenses.
Barrett formula also had the highest percentage
(81.8%) of eyes within ±0.5 D of the predicted
refraction for SN60WF lenses. Although there were
no significant differences between the percentage
of eyes within ±0.5 D among the five formulas
for ZCB00 lenses in long eye, the values were
significantly less compared with short and medium
eyes. A 2018 systematic review and meta-analysis
investigating the accuracy of six IOL power
formulas (Barrett Universal II, Haigis, Hoffer-Q,
Holladay 1, Holladay 2, and SRK/T) for long eyes
with an axial length of >24.5 mm found that
Barrett Universal II not only had a significantly
lower MAE than Holladay 1, Holladay 2, Hoffer-
Q, and SRK/T (all P < 0.001), but had significantly
higher percentage of eyes within ±0.5 D of the
predicted refraction than all formula.[39] IOLs used
in this study included LI61A0 Sofport/Akreos Fit,
SN60WF, SA60AT, PY-60AD, AR40e, and SN60AT
and MA60AC/BM/MA.[39] Kane et al[24] also found
Barrett Universal II to be the most accurate for eyes
with an axial length ≥26.00 mm for SN60WF. Kane
et al[24] found long eyes implanted with SN60WF
to have formulas with much lower percentage
of eyes within target refraction compared to
medium or medium-long axial lengths; however,
from our study this was only true for ZCB00. In our
study, postoperative refractive predictability was
significantly better for the SN60WF than the ZCB00
in long eyes with a higher percentage within ±0.5
D for all formulas: for example, 81.8% versus 42.9%,
respectively, for Barrett Universal II formula.

Although SN60WF and ZCB00 lenses are
commonly used during cataract surgery, a potential
limitation to our study is that we did not evaluate
other models of IOLs, including those with other
materials such as hydrophilic acrylic or silicone
IOLs. Furthermore, eyes with previous surgeries,
including keratorefractive surgery, were excluded
from our study. The differential effects of these
surgeries on the accuracy of IOL power formulas

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IOL Formula Accuracy for SN60WF vs ZCB00; Jiang et al

for various lenses remain to be determined. Newer
IOL power formulas, such as Kane, Olson, and Hill-
Radial Basis Function (RBF), may also have different
accuracies compared to the formulas evaluated
in our study for different IOL models. Moreover,
although many different methods of adjustments
have been suggested for the long eyes, such as
axial length adjustment,[41] we did not apply any of
these adjustments in this study as it is unknown
whether such adjustments are dependent on the
IOL model.

In summary, our study showed that the accuracy
of IOL power formula can be different for AcrySof
SN60WF or Tecnis ZCB00. As such, difference may
be true for other IOL models, studies on the IOL
formula accuracy should report the results for each
IOL model separately and should avoid combining
different IOL models into one group. Different
adjustments may be required for various IOL
types in different axial lengths. Although significant
differences in lens performance were not seen
in medium eyes, cataract surgery in short or
particularly long eyes should prompt deliberation
in choice of IOL.

Financial Support and Sponsorship

None.

Conflicts of Interest

None declared.

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https://www.accessdata.fda.gov/cdrh_docs/pdf4/P040020S050d.pdf
https://www.accessdata.fda.gov/cdrh_docs/pdf4/P040020S050d.pdf