Original Article

In Vivo Intraocular Lens Thickness Measurement and
Power Estimation Using Optical Coherence

Tomography

Ehsan Barzanouni1,2, MD; Diba Idani3, Medical Student; Farideh Sharifipour1,2, MD

1Ophthalmic Research Center, Research Institute for Ophthalmology and Vision Science, Shahid Beheshti University of Medical
Sciences, Tehran, Iran

2Department of Ophthalmology, School of Medicine, Shahid Beheshti University of Medical Sciences, Tehran, Iran
3School of Medicine, Shahid Beheshti University of Medical Sciences, Tehran.

ORCID:
Ehsan Barzanouni: https://orcid.org/0000-0001-8672-4496
Farideh Sharifipour: https://orcid.org/0000-0002-1511-9608

Abstract

Purpose: To estimate the power of an implanted intraocular lens (IOL) by
measuring IOL thickness using anterior segment optical coherence tomography
(AS-OCT) and to assess the repeatability of measurements.
Methods: Ninety-seven eyes were studied one month after uneventful
phacoemulsification within the bag Acrysof SA60AT IOL implantation (range +11
to +35). All eyes had postoperative refraction of ±0.5 D of target refraction.
AS-OCT was used to measure the central thickness of the IOL. Correlation
between labelled IOL power and central IOL thickness as well as the measure of
repeatability, for example, intraclass correlation coefficient (ICC), were evaluated.
IOL thicknesses were also calculated using a formula and compared with AS-OCT
derived measurements.
Results: IOL thickness correlated significantly with labelled IOL power (R2 =
0.985, P < 0.001). The regression equation (IOL Power = [0.04 × IOL thickness
in micron] – 7.56) indicates 25 microns of central IOL thickness change per
1D power change. Over the studied range, IOL power could be estimated with
a precision of 0.85 ± 0.02 D (95% confidence interval: 0.83–0.94D). ICC for
repeated measurements was 0.999. There was a significant correlation between
calculated and measured (AS-OCT) IOL thickness (R2 = 0.984, P < 0.001).
Conclusion: Central IOL thickness measurements with the AS-OCT are highly
repeatable and closely correlated with the labelled IOL power, which can predict
the IOL power with ±0.85 D from the actual power. This method can be helpful
in cases of postoperative IOL surprise.

Keywords: Anterior Segment Optical Coherence Tomography; AS-OCT; Intraocular Lens;
IOL; IOL Thickness

J Ophthalmic Vis Res 2022; 17 (3): 353–359

© 2022 Barzanouni et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E 353

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In-vivo IOL Power Estimation by OCT ; Barzanouni et al

INTRODUCTION

Cataract removal with intraocular lens (IOL)
implantation is one of the most frequently
performed ophthalmic surgeries. Microsurgical
techniques, improved IOL material and designs,
sophisticated biometry methods, and advanced
IOL power calculation formulas have altered the
role of cataract surgery even as a refractive surgery,
where in addition to removing opaque crystalline
lens also corrects any preexisting ametropia.
The accuracy of the ocular measurements
and IOL calculation, as well as selection of
the appropriate biometric formula, are the main
factors in achieving the desired postoperative
refractive results.[1] However, despite all these
measures, refractive surprise might happen as
a result of transcription errors, wrong patient
biometry, wrong IOL selection, changes in planned
procedure, incorrect IOL brought into the theatre,
left/right eye selection errors, communication
errors, and positive/negative IOL power errors.[2]
In rare cases, incorrect IOL labelling might be the
cause.[3–5] However, in 25–38% of the cases, the
cause of refractive surprises remains unknown.[2]
Although there is a need to calculate the power of
an implanted IOL, currently there is no established
method, and knowledge of implanted IOL power
is only restricted to the medical records of the
patients.

The introduction and evolution of imaging
techniques especially optical coherence
tomography (OCT) has made it possible to
image the ocular structures with micron-level
precision. OCT measurements have been shown
to highly correlate with real values, making it an
ideal method for evaluating anterior segment
structures.[6, 7] Scheimpflug imaging has been
used for central IOL thickness measurement
and in vivo calculation of IOL power.[8] This study

Correspondence to:

Farideh Sharifipour, MD, Department of Ophthalmology,
Labbafinejad Medical Center, 9th Boostan St., Pasdaran
Ave., Tehran 1666663111, Iran.
E-mail: sharifipourf@yahoo.com
Received: 11-06-2021 Accepted: 15-12-2021

Access this article online

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

DOI: 10.18502/jovr.v17i3.11572

was conducted to assess the correlation of IOL
thickness measured by anterior segment OCT (AS-
OCT) with the actual power of implanted IOL to
calculate the power of an unknown IOL.

METHODS

This prospective study was performed at a private
clinic. The study protocol adhered to the tenets
of the Declaration of Helsinki. Informed consent
was obtained from all patients and the test was
performed free of charge.

The study included consecutive patients
who underwent uneventful phacoemulsification
within the bag Acrysof SA60AT IOL (Alcon)
implantation. At postoperative month one, patients
with uncorrected visual acuity of 20/25 or better
who manifested refraction within ±0.5 D spherical
equivalent of target refraction were enrolled in
the study. Patients with corneal opacity precluding
high-quality images, history of trauma or anterior
segment diseases causing pupil abnormality, IOL
decentration, iridodonesis, pseudophacodonesis,
and IOL tilt were excluded.

Acrysof SA60AT IOL is a monofocal foldable,
single-piece posterior chamber acrylic lens with an
asymmetric biconvex 6 mm optic, overall length
of 13 mm, and a refractive index of 1.55. Available
powers range from 6.0 to 30.0 D in 0.5 D
increments and from 30 to 40 in 1D increments.

Optical Coherence Tomography
Measurements

OCT scans were performed using anterior
segment module, (Topcon 3D OCT-1000 Topcon
Corporation, Tokyo, Japan) after pupillary dilation.
The scan line was centered on the IOL along the
horizontal line and three images were captured.
The presence of a reflex saturation beam indicated
the perpendicularity of the IOL to the scanning
beam [Figure 1]. Lens thickness was measured

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How to cite this article: Barzanouni E, Idani D, Sharifipour F. In Vivo
Intraocular Lens Thickness Measurement and Power Estimation Using
Optical Coherence Tomography. J Ophthalmic Vis Res 2022;17:353–359.

354 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 3, July-September 2022

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


In-vivo IOL Power Estimation by OCT ; Barzanouni et al

Figure 1. Representative image of IOL thickness measurement method using anterior segment OCT.

 

Figure 2. Plot of IOL thickness (microns) against labelled IOL power (D).

using a built-in caliper from the anterior to the
posterior surface of IOL at the point of greatest
convexity. On each scan, measurements were
done by two observers (FS, DI) masked to the
IOL power. The average of the three closest
measurements was used for the analyses. Scans
with a lens tilt, motion artefact, and adhesion of
posterior capsule to the IOL were discarded.

Statistical Analysis

Statistical analysis was performed using the SPSS
software version 18.0 (SPSS Inc., Chicago, USA).
The intra- and interobserver repeatability of IOL
thickness measurements were assessed using
intraclass correlation coefficient (ICC). Correlation
between IOL thickness and labelled IOL power

was evaluated by Pearson’s correlation and linear
regression analysis; 95% confidence intervals
(CI) were calculated for every IOL prediction
based on thickness measurements. In addition, we
calculated central IOL thickness using the formula
proposed by Naeser et al[9] for each IOL power
and compared them with OCT-derived thickness
measurements.

𝑇 = 𝐸 + 2 × (|(𝑛2−1.336)×
1000
1/2×𝑃 |

−√((𝑛2 − 1.336)×
1000
1/2 × 𝑃 )

2
− 1
4𝐷2 )

(1)

The formula calculates the central thickness of
an IOL from variables normally supplied by
manufacturers where T is the central thickness of

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In-vivo IOL Power Estimation by OCT ; Barzanouni et al

 

Figure 3. Plot of labelled IOL power against IOL power calculated by the measured regression equation showing significant
correlation.

 

Figure 4. Plot of difference of labeled and calculated IOL powers against actual IOL power. The majority of labelled IOL powers
lie within Mean ± SD of difference of labeled and calculated IOL powers.

IOL optic (mm); E is edge thickness of the IOL optic
(mm); n2 is the refractive index of the IOL; P is IOL
power (Diopter); and D is IOL optic diameter (mm).

For the type of IOL, we used E = 0.21 mm,
n2 = 1.55, and D = 6 mm. P-values < 0.05 were
considered statistically significant.

RESULTS

A total of 88 participants (115 eyes) fulfilled the
inclusion criteria, among them 14 patients (18 eyes)
were excluded due to low-quality scans, artifacts,
decentration, and adhesion of posterior capsule to
the IOL. Data from 97 eyes (74 patients) were used
for the analyses. The patients included 30 men and

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In-vivo IOL Power Estimation by OCT ; Barzanouni et al

 

Figure 5. Plot of IOL thickness against confidence Interval (CI) width showing that 95% CI is the narrowest for IOL thicknesses
between 600 and 900 microns and becomes wider outside this range.

44 women with a mean age of 61.57 ± 8.08 years
(range, 45–86 years). Known IOL power ranged
from +11 to +35 D.

ICC (95% CI) for intra- and inter-observer
repeatability was 0.999 (0.995–0.998) and
0.997 (0.996–0.998), respectively. IOL thickness
correlated significantly with the labelled IOL power
(R2 = 0.985, P < 0.001) [Figure 2]. The regression
equation is as follows: IOL Power (D) = (0.04 × IOL
thickness in micron) – 7.56. For instance, an IOL
with a central thickness of 700 microns predicts
an IOL power of 20.43D. Figure 3 shows a plot of
labelled IOL power against IOL power calculated
by the measured regression equation for our
patients indicating a significant correlation (R2 =
0.970, P < 0.001). The majority of labelled IOL
powers were within mean ± SD of difference of
IOL power and calculated IOL power [Figure 4].

For each prediction, 95% CI
width was generated (CI width
=√0.695+

(𝐼𝑂𝐿 𝑡ℎ𝑖𝑐𝑘𝑛𝑒𝑠𝑠(µ)−792.31)2
627755

), yielding an
average of 0.84 ± 0.02 (range, 0.83–0.91). For
IOL thicknesses between 600 and 900 microns,
95% confidence interval did not exceed 0.86
D, however, farther from the mean, the CI was
wider indicating that the accuracy of prediction is
highest within this range and decreases with IOL
thicknesses outside this range [Figure 5].

Central IOL thickness was also calculated
theoretically using the Naeser et al formula.[9]

The calculated IOL thicknesses and the AS-
OCT-measured central IOL thicknesses were
significantly correlated (R2 = 0.984, P < 0.001).

DISCUSSION

In this study, we demonstrated that measuring
the central thickness of SA60AT IOL by AS-OCT
was highly repeatable and closely correlated with
labelled IOL power, which could predict the IOL
power within ±0.85D of actual power. We also
determined the correlation of AS-OCT-measured
IOL thickness with the theoretically calculated IOL
thickness and observed a significant correlation
between the two thicknesses. Therefore,
measuring IOL thickness using AS-OCT can
provide an almost precise estimation of unknown
IOL power using the Naeser et al formula as well.[9]
Although our results are most likely applicable to
the specific IOL type and power range used in this
study, many IOLs share the same characteristics in
terms of size, optic diameter, and refractive index,
so it is possible that the formula would apply to
many IOL trademarks.

The use of accurate biometry techniques
and appropriate IOL calculation formulas has
greatly improved the refractive outcomes of
cataract surgery. However, in cases with refractive
surprise after cataract surgery, possible sources
of error include decentered IOL, undiagnosed
keratoconus, inaccurate biometry, upside down
IOL implantation, incorrect IOL brought into the

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In-vivo IOL Power Estimation by OCT ; Barzanouni et al

theatre, mixed-up documentation of patients, and
mislabeled IOLs.[3–5] In the past, some surgeons
used to evaluate lens resolution and measure the
IOL power before inserting the lens into the eye to
make sure that the manufacturing IOL is truly the
correct power.[10]

In a study by Turner et al using Scheimpflug
imaging, the central thickness of MA60AC IOL
(Alcon) was correlated with known IOL power and
a similar formula was obtained. As compared to
our study, they had a limited range of IOL power
(11 to 26.5D).[8] The IOL thickness measurements
using Scheimpflug imaging was different from our
AS-OCT-derived measurements, for example, a
600 micron thickness in their study represented
IOL power of 20.451 D, while in our study
700 microns represent 20.43 D IOL power. The
difference in measurements obtained by different
imaging techniques and even among different
OCT machines has been well-documented which
indicates that the measurements cannot be used
interchangeably.[11–13]

We observed that for IOL thicknesses between
600 and 900 microns, 95% confidence interval
did not exceed 0.86 D, however, farther from
the mean, CI was wider indicating that the
accuracy of prediction is highest within this range
and decreases with IOL thicknesses outside this
range [Figure 5]. Additionally, IOL surprise most
commonly happens in the extreme IOL powers with
less accuracy in the prediction of the IOL power.

Our study had the advantage of including
a wide range of IOL powers and comparing
our measurements to the theoretic formula for
calculating IOL thickness. However, using a single
type of IOL precludes extrapolation of our results
to other IOL brands with different designs or
refractive index and powers outside the range
used in this study. Since OCT imaging uses
backscattered infrared light, for accurate IOL
thickness measurements by OCT, media anterior to
the IOL should be clear. Therefore, dense corneal
opacities can interfere with image acquisition
and accurate measurements, as are titling or
decentration of the IOL, which preclude the
presence and adjustment of reflex saturation beam
as the indicator of perpendicularity of the IOL
to the scanning beam. These limitations of IOL
thickness measurement by OCT were considered
as the exclusion criteria in our study. Attachment
of posterior capsule to the IOL may result in falsely
greater thickness. However, posterior capsule

opacification (PCO) per se is not a limitation to
IOL thickness measurements provided that the
posterior capsule could be visualized separately
behind the IOL.

In summary, our study was successful
in determining that central IOL thickness
measurements by AS-OCT shows a strong
correlation with IOL power with high accuracy and
repeatability and can be used with the regression
equation obtained for this IOL type in cases of
IOL surprise. Further studies with other types of
IOLs are warranted to evaluate the applicability of
our results. Future studies are needed to evaluate
applicability of OCT to measure IOL tilt and the
resulting induced cylinder. It is also recommended
that the manufacturers provide IOL thickness on
the IOL boxes along with other IOL characteristics,
which could be compared with OCT-derived
thicknesses in case of IOL surprise.

Financial Support and Sponsorship

Nil.

Conflicts of Interest

There are no conflicts of interest.References

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