Original Article

Implantation of a Small Aperture Intraocular Lens in
Eyes with Irregular Corneas and Higher Order

Aberrations

Fabrizio Franco1, MD; Marco Branchetti1, MD; Lidia Vicchio1, MD; Federica Serino1, MD; Marco Piergentili1, MD;
Vito Spagnuolo1, MD; Francesca Santoro1, BS; Gianni Virgili1, 2, MD; Fabrizio Giansanti1, 2, MD

1Department of Ophthalmology, Careggi Teaching Hospital, Florence, Italy
2Department of Neurosciences, Faculty of Psychology, University of Florence, Pharmacology and Children Health, Florence,

Italy

ORCID:
Fabrizio Franco: https://orcid.org/0000-0002-3583-5898
Marco Branchetti: https://orcid.org/0000-0003-4242-4875

Abstract

Purpose: Corneal irregularities can lead to high order aberrations (HOAs) and may
influence the outcomes in terms of intraocular lens (IOL) selection and visual acuity
assessment. The aim of this study was to evaluate the visual acuity and satisfaction after
IC-8 implants in patients characterized by corneal irregularities and HOAs who could
not undergo refractive surgery due to the poor residual thickness of the cornea or other
conditions such as astigmatism secondary to previous radial keratotomy.
Methods: This descriptive, retrospective cohort study was conducted on nine eyes in
six patients affected by corneal irregularities and HOAs who had undergone IC-8 IOL
implantation. The primary endpoint was the best-corrected visual acuity (BCVA), the
subjective visual function, and the visual field.
Results: Nine eyes of six patients (three bilateral implantation) were enrolled. For each
patient, BCVA, vision, and lifestyle quality were evaluated. In all patients, we noticed an
improvement in all parameters without visual field defects.
Conclusion: Our work encourages the use of the IC8 lens to improve visual acuity
in patients with irregular corneas and HOAs who cannot be treated with customized
refractive surgery. Patients experience a subjective improvement of their quality of vision
and also more self-confidence in their daily life. IC-8 lenses do not interfere with the
visualization of retinal fundus and there is no impairment of the visual field detected by
patients.

Keywords: Aberrations; Cataract; IC-8; Pinhole

J Ophthalmic Vis Res 2022; 17 (3): 317–323

Correspondence to:

Marco Branchetti MD. Largo Piero Palagi 1, 50139,
Florence, Italy.
E-mail: marco.branchetti89@gmail.com
Received: 27-12-2020 Accepted: 23-01-2022

Access this article online

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

DOI: 10.18502/jovr.v17i3.11568

This is an open access journal, and articles are distributed under the terms of
the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 License, which
allows others to remix, tweak, and build upon the work non-commercially, as
long as appropriate credit is given and the new creations are licensed under the
identical terms.

How to cite this article: Franco F, Branchetti M, Vicchio L, Serino F,
Piergentili M, Spagnuolo Vito, Santoro F, Virgili G, Giansanti F. Implantation
of a Small Aperture Intraocular Lens in Eyes with Irregular Corneas and
Higher Order Aberrations. J Ophthalmic Vis Res 2022;17:317–323.

© 2022 Franco et al . THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E 317

http://crossmark.crossref.org/dialog/?doi=10.18502/jovr.v17i3.11568&domain=pdf&date_stamp=2019-07-17
https://knepublishing.com/index.php/JOVR


IC-8 IOL in Irregular Corneas; Franco et al

INTRODUCTION

Cataract surgery is the most performed ophthalmic
procedure worldwide. Patients have higher
expectations regarding postoperative refractive
results and relative independence from spectacles,
than in the past.[1]

To determine the desired refractive results, a
complete biometric measure should be performed
to calculate the power of the intraocular lens (IOL).
Central corneal power (K) is an important factor in the
calculation formula to decide the power of the IOL to
be implanted.[2]

Nowadays, Scheimpflug and OCT-swept source
ray tracing technology allow to study in a better
way the anterior and posterior faces of the cornea
with the aim of estimating its total power.[3] Corneal
irregularities could lead to high order aberrations
(HOAs) that can influence the outcomes in terms of
IOL selection and visual acuity.[4]

Recently, AcuFocus (Irivne, CA) has made available
IC-8: a one-piece, acrylic, hydrophobic, posterior
chamber small-aperture IOL that provides an increase
in the range of vision from far to near, by extending
the depth of focus.[5]

It works by using the principle of the pinhole
to improve visual acuity and minimize dysphotopsia
symptoms by applying the same small-aperture
principle optics as the Kamra inlay: where peripheral
rays are stopped while central light rays are allowed
to pass with no interference and focus on the retina.[6]

It is a biconvex lens with a total length of 12.50 mm
and a diameter of 6 mm composed of polyvinylidene
fluoride and nanoparticles of carbon incorporating a
non-diffractive 3.23-mm diameter opaque mask with
a 1.36-mm central aperture.

The IC-8 could be implanted in conjunction with an
aspheric monofocal IOL implantation in the dominant
eye, which will improve intermediate and near vision
while preserving far vision in the eye with a monofocal
optic IOL.[7]

The aim of this study was to evaluate the visual
acuity and satisfaction after IC-8 implant in patients
characterized by previous corneal irregularities and
HOAs who cannot undergo refractive surgery due to
the poor residual thickness of the cornea or other
conditions such as stigmata related to previous radial
keratotomy.

SURGICAL METHOD

This was a descriptive, retrospective cohort study
of nine eyes in six patients affected by corneal

irregularities and HOAs who had undergone IC-
8 IOL implantation between October 2019 and
January 2020 at Careggi Hospital in Florence. All
had monolateral implants except for three patients.
Patients with significative comorbidities affecting
visual acuity such as glaucomatous neuropathy and
maculopathy were excluded from the study.

Patients included in the study were subjected to
a protocol that provided a baseline and three follow-
up visits at day 1, month 1 and month 3, which
included Snellen best-corrected visual acuity (BCVA),
biomicroscopy, Goldmann applanation tonometry,
corneal topography and study of the corneal HOAs
(Sirius CSO Florence), fundoscopy (Volk lens) in
miosis and after pharmacological dilation, AS-OCT
(MS 30, CSO Florence).

The aberrometry (Osiris, CSO Florence) was
performed, but the diameter of the opaque mask
(1.36 mm central aperture) did not allow the machine’s
rays to reach a good acquisition. All patients also
underwent preoperatively and postoperatively a 30:2
Humphrey visual field and Esterman 120 points visual
field.

Surgical Technique

All 9 IC-8 implants were performed by the same
surgeon (FF) after phacoemulsification (clear lens
extractions) under topical anesthesia.

We used a dispersive viscoelastic device (OVD)
into the anterior chamber and we made a 2.4
mm corneal incision. Then, the surgeon performed
a capsulorhexis, hydrodissection, hydrodelineation,
and phacoemulsification. All small-aperture IOLs
were placed in the capsular bag using the small-
aperture IOL injection system with haptic orientation
at 12 o’clock and 6 o’clock. IC-8 IOL was centered
referring to the Purkinje reflex.

Finally, the viscoelastic was removed with
irrigation and aspiration and we hydrated the
two paracenteses. In this study, no intraoperative or
postoperative complications happened [Figure 1].

Outcomes

Primary outcomes were determined by the
improvement of logMAR BCVA and the evaluation
of the postoperative visual fields (Humphrey 30:2
and Esterman 120 points). Secondary outcomes
were reflected in the increase of visual quality and
patients’ satisfaction, as revealed from performing
the visual function questionnaire 25 (VFQ-25).

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



IC-8 IOL in Irregular Corneas; Franco et al

Informed consent was obtained from all patients
who underwent surgery. The study protocol was
approved by the local ethics committee in compliance
with the tenets of the Declaration of Helsinki.

We used the VFQ-25 questionnaire to assess
self-reported vision-targeted health statuses. Patients
were contacted via telephone and answered the
questionnaire; the answers were converted into
numerical representative values.

RESULTS

The study sample included six patients, two males
(33%) and four females (67%), with a mean age of 57
years old, three of which underwent surgery in both
eyes.

In total, nine eyes had been subjected to IC-8
implantation: four right eyes (44%) and five left eyes
(56%).

Almost the entire sample (78%) presented corneal
irregularity due to previous radial keratotomy, one
(11%) had a previous decentralized refractive surgery
with low residual corneal thickness and one (11%) had
a previous pterygiectomy with residual irregularities
on the anterior and posterior face of the cornea. In this
case, we performed a photo-therapeutic keratectomy
(PTK) on the anterior face with an unsuccessful result
because of the irregular posterior face.

We evaluated the high order corneal aberration
(Sirius CSO Florence): in six eyes (67%) the main
HOA was coma (mean value 1.13 µm), in two patients
(22%) four-leaf clover (mean value 1.41 µm), and in one
patient (11%) clover (0.90 µm) [Table 1].

BCVA increased from a preoperative mean of
LogMAR 0.32 (±0.17) to 0.26 (±0.30) on day 7, 0.22
(±0.20) at month 1, and 0.20 (±0.15) at month 3 [Table
2]. The percentage reduction of mean LogMAR BCVA
at the end of the follow-up period (month 3) was 25%,
compared to the one at the preoperative visit.

Our patients underwent a clear lens extraction
and monofocal small aperture lenses were then
implanted. This is very important because the
prevalence of HOAs is not influenced by cloudy
lenses (all HOAs come from corneal shape). The
1.36 mm central aperture and the non-diffractive 3.23
mm diameter opaque mask of the IC-8 recreate the
pinhole principle. So, it is possible to “reflect” this
effect onto the corneal surface: only the central 2 mm
of the cornea becomes fundamental for vision. HOAs
are influenced by the central corneal diameter that we
focused on: less corneal diameter means little HOAs
at topography study. Aberrometric reviews confirmed
the reduction of the major HOAs of the patients in our

study [Table 3]. Less HOAs meant a better quality of
eye vision.

It is important to increase the number of selected
patients with irregular cornea and IC-8 implants
to ensure the validity of the data obtained. In
fact, increasing the selection facilitates greater
understanding of establishing the origins of the
corneal irregularities and would also assist in
determining which specific HOAs would obtain the
appropriate results with the implementations IC-8
IOLs.

During this study, there were no instances of
intraoperative or postoperative complications.

DISCUSSION

We focused our attention on the use of IC-8 IOLs in
patients who suffered with cataract, severe corneal
irregularities, and HOAs. Generally, when the corneal
thickness allowed it, we preferred to correct the
corneal irregularities with a customized laser ablation
before the cataract surgery was performed. However,
in this study, the corneas of patients could not
be treated with refractive surgery due to the poor
residual thickness of their cornea or presence of other
conditions such as posterior corneal astigmatism.

In our study, seven eyes (78%) had previous
radial keratotomy (RK), one eye (11%) had a previous
decentralized refractive surgery, and one (11%) had
a previous pterygectomy with irregularity of the
posterior face of the cornea. HOAs cause difficult
night vision, glare, halos, blurring, starburst patterns
or double vision (diplopia), and cannot be corrected
through conventional techniques (i.e., toric IOLs).
Furthermore, in these cases, the calculation of IOL
power is more challenging since the corneal power
is hard to be assessed. In our study, the nine eyes
in which the small-aperture IC-8 has been implanted
experienced an increase of BCVA, and a subjective
vision quality improvement (objective and subjective
visual outcomes).

Since the irregularities of the cornea cannot be
corrected with customized refractive surgery because
of the risk of low residual corneal thicknesses
occurring or because of the resulting presence of
many radial cuts, we decided to act according to
the principles of a pinhole. A small pinhole, which
reduce the effective pupil size, leads to a disruption
of peripheral rays, while allowing central focused
light to reach the retina, and increasing the depth
of focus. Ogle et al[8] found that there is an inverse
relationship between the pupil size and the depth
of focus. Moreover, a relationship could be found

JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 3, July-September 2022 319



IC-8 IOL in Irregular Corneas; Franco et al

Figure 1. IC-8 IOL placed in the capsular bag, cornea with previous radial keratotomy (left). Small aperture IOL specifications: optic
and mask design (right).

Figure 2. Predictive modifications of Zernicke’s summary and visual summary from 5 to 2 mm of corneal diameter (Sirius CSO).

between pupil size and HOAs, where small pupils can
attenuate the visual effect of corneal aberrations.[9, 10]

The simulation of the visual quality of the Sirius
takes into account the corneal aberrations and
demonstrates an aberration index Point Spread
Function (PSF describes the shape of an image in an
optical system) and the related Strehl Ratio change
according to the size of the pupil. In all patients, the
PSF value was better at 2 mm (mean value 0.17569)

than at 5 mm (mean value 0.06249). So, we decided
to implant the IC-8 and take advantage of the small
aperture IOL principle to reduce visual aberrations
and to improve the PSF [Figure 2].

The pinhole effect has been already exploited by
the add-on XtraFocus lens (Morcher), a total black
IOL for sulcus implantation, specifically designed for
cases with corneal irregularities.[11–13] Compared to
the XtraFocus lens, which is an add-on lens without

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



IC-8 IOL in Irregular Corneas; Franco et al

 

Figure 3. Visual field 30 – 2 (left) and 120 (right): no alterations related to IC8 lens.

PSF, point spread function; RMS, root mean square; HOAs, high order aberrations; IPF, irregularity’s 

posterior face of the cornea; RK, radial keratotomy; DRS, decentralized refractive surgery  
 

Figure 4. Corneal topography study.

LogMAr best-corrected visual acuity (BCVA) during follow-up. 

Figure 5. Visual acuity study.

JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 3, July-September 2022 321



IC-8 IOL in Irregular Corneas; Franco et al

PSF, point spread function; RMS, root mean square; HOAs, high order aberrations; IPF, irregularity’s 

posterior face of the cornea; RK, radial keratotomy; DRS, decentralized refractive surgery  
 

Figure 6. Major HOAs study.

optical power, the IC-8 has optical power and can
be placed directly in the capsular bag during the
cataract surgery, with a 1.36 mm central aperture and
a non-diffractive 3.23 mm diameter opaque mask that
allows the possibility of studying the retina, and also
performing retinal surgery.

After the implantation of the IC-8 IOL, we achieved
a decrease of LogMAR BCVA from a preoperative
mean of 0.35 (±0.18) to 0.25 (±0.22) at month
3. Subjective improvement of self-reported vision-
targeted health status was observed as patients
reported their satisfaction while answering the VFQ-
25 questionnaire. Especially, after receiving bilateral
implants, patients reported that they felt more
confident in daily life.

The preoperative visual impairment that patients
experienced was mainly related to the presence of
HOAs and on a smaller scale due to the presence of
cataract.

Our findings confirm data reported in prior
literature: Shajari[3] reported in 17 eyes an
improvement of corrected distance visual acuity
(CDVA) from the preoperative value of 0.37 to 0.19
LogMAR at month 3 after the IC-8 lens implantation
in eyes with severe corneal irregularities. Grabner
et al[14] registered a similar result. Schultz and Dick
reported the use of the IC-8 lens in a case of a patient
with irregular cornea because of trauma: after surgery
they experienced an improvement in visual acuity
across all distances.[15] Agarwal[16] implanted IC-8
IOL in patients who had previous refractive surgery
and HOAs: she reported that the small-aperture IOL
reduced the effects of HOAs on visual acuity and
provides continuous depth of focus.

Examination of the posterior segment was always
possible, although in non-mydriatic conditions,
during the follow-up visits. The mask only extends
to 3.23 mm in total, so that peripheral IOL is
clear and doesn’t preclude visualization of the
peripheral retina with Volk lens. These findings

corroborate Srinivasan’s[17] data from 15 patients:
optical coherence tomography, posterior segment
investigations including fundus photography, and
perimetry could be safely performed in eyes with IC8
IOLs. Moreover, Srinivasan et al did not report any
issues according to the intraoperative view and the
surgeon could perform all vitrectomy procedures,
without distortions and disc halos on the retina, as
is common with diffractive and refractive multifocal
lenses.[18]

Despite the presence of the opaque mask,
measuring 3.23 mm, the field of vision was
maintained. We performed a visual field (VF)
Humphrey 30:2 and a full-field 120-point screening
test, where, even with the presence of the opaque
mask, in the most extreme periphery of the visual
field we did not detect any shrinkage or defect. We
achieved the visual fields even in pharmacological
mydriasis conditions to assess whether the visual
impairment due to the mask would have been greater
in a situation mimicking low light conditions. Both
conditions of the VF were performed at month 3 of
follow-up to ensure that the patients were adapting
to the presence of the IC-8 IOL. In our study, we
registered a good subjective adaptation, without any
resultant shrinkage in visual field, in both bilateral
(50% of the cases) and monolateral cases [Figure 3].

No adverse events occurred during the follow-
up. Only one patient developed significant posterior
capsule opacification (PCO) that required YAG laser
capsulotomy only in the 1.36 mm central aperture.
Previous works have reported a small PCO rate
after IC-8 implantation (6.8% in Ang’s work,[19] 7% in
Shajari’s study,[20] and 12% in Hooshmand’s study,[21]
which were treated with the YAG laser without further
complications.

In summary, the result of our work encourages
the use of the IC-8 lens to improve visual acuity
in patients with irregular corneas and HOAs that
cannot be treated with customized refractive surgery.

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



IC-8 IOL in Irregular Corneas; Franco et al

Patients feel a subjective improvement in their quality
of vision and more confident in daily life. The IC-8
lens does not interfere with visualization of fundus
and no impairment of the visual field are detected by
patients.

Financial Support and Sponsorship

None.

Conflicts of Interest

There are no conflicts of interest.

REFERENCES

1. Hawker MJ, Madge SN, Baddeley PA, Perry SR. Refractive
expectations of patients having cataract surgery. J
Cataract Refract Surg 2005;31:1970–1975.

2. Barrett GD. An improved theoretical formula for
intraocular lens power prediction. J Cataract Refract
Surg 1993;19:713–720.

3. Shajari M, Mackert M, Langer J, Kreutzer T, Wolf A, Kohnen
T, et al. Safety and efficacy of a small-aperture capsular
bag-fixated intraocular lens in eyes with severe corneal
irregularities J Cataract Refract Surg 2020;46:188–192.

4. Braga-Mele R, Chang D, Dewey S, Foster G, Henderson
BA, Hill W, et al. Multifocal intraocular lenses: Relative
indications and contraindications for implantation. J
Cataract Refract Surg 2014;40:313–322.

5. Grabner G, Ang RE, Vilupuru S. The small aperture IC-8
intraocular lens: A new concept for added depth of focus
in cataract patient. Am J Ophthalmology 2015;160:1176–
1184.e1.

6. Tucker J, Charman WN. The depth-of-focus of the
human eye for Snellen letters. Am J Optom Physiol Opt
1975;52:3–21.

7. Ang RE. Visual performance of a small-aperture intraocular
lens: First comparison of results after contralateral and
bilateral implantation. J Refract Surg 2020;36:12–19.

8. Ogle KN, Schwartz JT. Depth of focus of the human eye. J
Opt Soc Am 1959;49:273–280.

9. Yuan Y, Shao Y, Tao A, Shen M, Wang J, Shi G, et al. Ocular
anterior segment biometry and high-order wavefront

aberrations during accommodation. Invest Ophthalmol Vis
Sci 2013;54:7028–7037.

10. Munoz G, Rohrweck S, Sakla HF, Altroudi W. Pinhole iris-
fixated intraocular lens for dysphotopsia and photophobia.
J Cataract Refract Surg 2015;41:487–491.

11. Trinidade BLC, Trindade FC, Trindade CLC, Santhiago MR.
Phacoemulsification with intraocular pinhole implantation
associated with Descemet membrane endothelial
keratoplasty to treat failed full-thickness graft with dense
cataract. J Cataract Refract Surg 2018;44:1280–1283.

12. Trinidade CC, Trindade BC, Trindade FC, Werner L, Osher
R, Santhiago MR. New pinhole sulcus implant for the
correction of irregular corneal astigmatism. J Cataract
Refract Surg 2017;43:1297–1306.

13. Tsaousis KT, Werner L, Trindade CLC, Guan J, Li J, Reiter
N. Assessment of a novel pinhole supplementary implant
for sulcus fixation in pseudophakic cadaver eyes. Eye
2018;32:637–645.

14. Grabner G, Ang RE, Vilupuru S. The small aperture IC-8
intraocular lens: A new concept for added depth of focus
in cataract patient. Am J Ophthalmology 2015;160:1176–
1184.e1.

15. Schultz T, Dick HB. Small-aperture intraocular lens
implantation in a patient with an irregular cornea. J Refract
Surg 2016;32:706–708.

16. Agarwal Franzco S, Thornell E. Cataract surgery with
a small-aperture intraocular lens after previous corneal
refractive surgery: Visual outcomes and spectacle
independence. J Cataract Refract Surg 2018;44:1150–
1154.

17. Srinivasan S, Khoo LW, Koshy Z. Posterior segment
visualization in eyes with small aperture intraocular lens.
J Refract Surg 2019;35:538–542.

18. Holladay JT, Van Dijk H, Lang A, Portney V, Willis TR, Sun R,
et al. Optical performance of multifocal intraocular lenses.
J Cataract Refract Surg 1990;16:413–422.

19. Ang RE. Visual performance of a small-aperture intraocular
lens: First comparison of results after contralateral and
bilateral implantation. J Refract Surg 2020;36:12–19.

20. Shajai M, Mackert M, Langer J, Kreutzer T, Wolf A, Kohnen
T, et al. Safety and efficacy of a small-aperture capsular
bag-fixated intraocular lens in eyes with severe corneal
irregularities. J Cataract Refract Surg 2020;46:188–192.

21. Hooshmand J, Allen P, Huynh T, Chan C, Singh R,
Moshegov C, et al. Small aperture IC-8 intraocular lens
in cataract patients: Achieving extended depth of focus
through small aperture optics [EPub Ahead of Print]. Eye;
2019.

JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 3, July-September 2022 323