Perspective

Retinal Pigment Epithelium Transplantation: Past,
Present, and Future

Ayyad Zartasht Khan1, MD, PhD; Tor Paaske Utheim2, 3, 4, 5, 6, MD, PhD; Jon Roger Eidet6, MD, PhD

1Department of Medical Biochemistry, Oslo University Hospital, Kirkeveien 166, Nydalen, Oslo, Norway
2Department of Oral Biology, Faculty of Dentistry, University of Oslo, Sognsvannsveien 10, Oslo, Norway

3Department of Plastic and Reconstructive Surgery, Oslo University Hospital, Kirkeveien 166, Nydalen, Oslo, Norway
4Department of Ophthalmology, Sørlandet Hospital Arendal, Lundsiden, Kristiansand, Norway

5Department of Ophthalmology, Stavanger University Hospital, Stavanger, Norway
6Department of Ophthalmology, Oslo University Hospital, Kirkeveien 166, Nydalen, Oslo, Norway

ORCID:
Ayyad Zartasht Khan: https://orcid.org/0000-0002-2048-225X

Abstract

Retinal pigment epithelium (RPE) is a monolayer of cells situated between
photoreceptors and the underlying choroid. It is essential for normal retinal
function. Damaged RPE is associated with diseases such as age-related macular
degeneration, Stargardt’s macular dystrophy, and retinitis pigmentosa. RPE cells
can easily be visualized in vivo, sustainable in vitro, and differentiated from
stem cells with a relatively straightforward protocol. Due to these properties
and the clinical significance of this epithelium in various retinal diseases, RPE
transplantation as a treatment modality has gained considerable interest in the
last decade. This paper presents the main techniques for RPE transplantation and
discusses recent clinically relevant publications.

Keywords: Retinal Pigment Epithelium; Retinal Pigment Epithelium Transplantation;
Regenerative Medicine; Vitreoretinal Surgery; Tissue Engineering.

J Ophthalmic Vis Res 2022; 17 (4): 574–580

INTRODUCTION

Retinal pigment epithelium (RPE) is a cell layer
sandwiched between photoreceptors apically and
Bruch’s membrane basally. RPE cells are cuboidal
with apical microvilli gaping photoreceptor
outer segments.[1] Their cytoplasms contain

Correspondence to:

Ayyad Zartasht Khan, MD, PhD. Department of Medical
Biochemistry, Oslo University Hospital, Kirkeveien 166,
P.O. Box 4956, Nydalen, 0424 Oslo, Norway.
Email: aakhan@studmed.uio.no
Received: 05-02-2022 Accepted: 12-05-2022

Access this article online

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

DOI: 10.18502/jovr.v17i4.12325

melanin pigments, lipofuscin granules,
melanolipofuscins, and phagosomes.[1] These
cells adhere to each other via zonula occludentes,
creating a mosaic-patterned layer of tightly
adjoined hexagonally shaped cells. RPE performs
several functions essential for vision, such as
adsorption of excessive light, transport of nutrients
to and from the neuroretina, protection against
photooxidation, regeneration of 11 cis-retinal

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: Khan AZ, Utheim TP, Eidet JR. Retinal
Pigment Epithelium Transplantation: Past, Present, and Future. J
Ophthalmic Vis Res 2022;17:574–580.

574 © 2022 Khan et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E

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RPE Transplantation; Khan et al

for the visual cycle, and phagocytosis of shed
photoreceptor outer segments.[1, 2] It also
constitutes the outer part of the blood–retinal
barrier.[1]

RPE dysfunction is seen in several
retinal disorders, such as age-related
macular degeneration (AMD),[3] proliferative
vitreoretinopathy (PVR), and retinitis pigmentosa
(RP). Regarding AMD, it is still unclear whether
drusen formation is a consequence or a cause
of RPE dysfunction.[4] However, both are strongly
associated with each other.[5] In PVR, RPE cells
contribute to the folding of the retina by detaching
and translocating from the underlying basement
membrane.[6–8] Similarly, RPE disintegration and
migration are responsible for the bone-spicule
pigmentation that is pathognomonic for RP.[9] Thus,
when RPE fails to function correctly, the retina
suffers.

Replacing RPE cells is an idea that arose shortly
after the characterization of these cells about
40 years ago.[10] Their anatomical accessibility, in
vitro resilience, and clinical importance made them
attractive for transplantation scientists. The first
proof-of-concept study of RPE transplantation was
performed in 1984 by Gouras et al in monkeys.[11]
Four years later, Li and Turner published a report
demonstrating that subretinal injection of RPE cells
prevented photoreceptor degeneration in rats.[12]
The field has subsequently matured at a rapid
pace with not only animal studies,[13–15] but also
human trials, using RPE of fetal,[16, 17] post-mortem
adult,[18–20] autologous,[21–23] induced pluripotent
stem cell (iPSC)-derived[24] and embryonic stem
cell (ESC)-derived origin.[25–27]

The introduction of IPSC- and ESC-derived RPE
have been critical for the advancement of clinical
RPE research during the recent years, and has,
to a large extent, solved the issue of sourcing
RPE donor tissue. While iPSCs offer an unlimited
supply of autologous cells and (to some degree)
do not require the use of immunosuppressants,
they may carry patients’ own genetic vulnerabilities
contributing to disease processes.[28] This can
be avoided by using ESCs. However, ESCs raise
ethical concerns[29–31] and are, in contrast to iPSCs,
neither autologous nor unlimited in supply. The
methods for generating RPE cells from iPSCs[32, 33]
and ESCs[34, 35] have been described in detail.
As the succeeding paragraphs will demonstrate,
ongoing clinical trials employ these two stem cell

sources to generate mature, transplantation-ready
RPE.

Transplantation Techniques

There are currently three techniques for subretinal
RPE transplantation: (1) surgical placement of RPE
as an intact cell sheet (with or without scaffold),
(2) injection of RPE as a cell suspension, and (3)
macular translocation.

Transplantation of RPE as an intact cell sheet
was first described in 1991 by Peyman et al,
who treated one patient with an autologous
pedicle flap and another with an allogeneic
graft consisting of RPE with an underlying
choroid.[19] Similar procedures have later been
performed by others.[24, 26, 36, 37] Delivering RPE
as a patch increases the likelihood of correct
anatomical placement and the structural integrity
of the graft. Major complications associated
with this technique are subretinal hemorrhage and
proliferative vitreoretinopathy. Delivery by injection
is technically easier and probably less traumatizing
to the adjacent tissue. However, cell clumping,
poor attachment, and disorganization of RPE upon
injection[38] are important drawbacks. The third
approach, macular translocation, involves rotating
the retina away from a subretinal pathology to an
area of healthy RPE. This technique is surgically
less straightforward and complicated by cataract,
retinal detachment, and diplopia.[39]

Current State of the RPE Transplantation

To give the reader an idea of the current state
of RPE transplantation, selected recent studies are
briefly discussed below.

In a phase 1/2 clinical trial, Schwartz and
associates injected human ESC-derived RPE
subretinally via a small 38-gauge retinotomy
in 18 patients; nine with AMD and nine with
Stargardt’s Macular Dystrophy (SMD).[27] Visual
acuity improved in the majority of patients. No
ocular or systemic safety issues were registered,
apart from surgery-associated complications,
such as vitreous inflammation, cataract, and
endophthalmitis. This study suggested that ESC-
derived RPE is a potential and safe source of cells
for the treatment of retinal disorders.

While Schwartz et al delivered the cells via
injection, Kashani and colleagues described a

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RPE Transplantation; Khan et al

Table 1. RPE transplantation trials listed on ClinicalTrials.gov.

No. Study title Status Publications Conditions Sponsor/

Collaborators

Phase Study type Estimated

study start

Estimated

study

completion

Study

location

(country)

NCT number Related

projects (NCT

numbers)

1 Safety and

Tolerability of

RPESC-derived

RPE

Transplantation in

Patients with

dAMD

Not yet

recruiting

No

Publications

Available

dAMD Luxa

Biotechnology,

LLC; NIH; NEI;

Regenerative

Research

Foundation

Phase 1/2 Interventional February

2022

September

2025

USA NCT04627428

2 Treatment of RP

and LCA by

Primary RPE

Transplantation

Unknown

status

No

Publications

Available

LCA; RP Eyecure

Therapeutics

Inc.; Beijing

Tongren

Hospital

Phase 1 Interventional August

2018

March 2020 China NCT03566147

3 Autologous

Transplantation of

Induced

Pluripotent Stem

Cell-Derived RPE

for Geographic

Atrophy

Associated with

AMD

Recruiting No

Publications

Available

AMD NIH; NEI Phase 1/2 Interventional September

2020

May 2029 U.S.A. NCT04339764

4 Subretinal

Transplantation of

RPE in Treatment

of AMD

Unknown

status

No

Publications

Available

dAMD Chinese

Academy of

Sciences;

Beijing Tongren

Hospital

Phase 1/2 Interventional January

2018

December

2020

China NCT02755428 NCT03944239

5 Treatment of

dAMD with RPE

Derived from

Human Embryonic

Stem Cells

Unknown

status

No

Publications

Available

dAMD Chinese

Academy of

Sciences; The

First Affiliated

Hospital of

Zhengzhou

University

Phase 1/2 Interventional September

2017

December

2020

China NCT03046407

6 Clinical Study of

Subretinal

Transplantation of

Human Embryo

Stem Cell Derived

RPE in Treatment

of Macular

Degeneration

Diseases

Unknown

status

No

Publications

Available

AMD; SMD Southwest

Hospital, China

Phase 1/2 Interventional May 2015 December

2019

China NCT02749734

7 Transplantation of

Autologous RPE

Versus

Translocation of

Autologous RPE

and Choroid in

AMD

Completed [42] AMD The Ludwig

Boltzmann

Institute of

Retinology and

Biomicroscopic

Laser Surgery

Not

Applicable

Interventional February

2004

September

2008

Austria NCT00401713

576 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 4, October-December 2022



RPE Transplantation; Khan et al

Table 1. (Continued).

No. Study title Status Publications Conditions Sponsor/

Collaborators

Phase Study type Estimated

study start

Estimated

study

completion

Study

location

(country)

NCT number Related

projects (NCT

numbers)

8 Safety and

Tolerability of

Sub-retinal

Transplantation of

Human Embryonic

Stem Cell Derived

RPE in Patients

With SMD

Completed [27, 43] SMD Astellas Institute

for Regenerative

Medicine

Phase 1/2 Interventional December

13, 2011

September

30, 2015

U.K. NCT01469832 NCT02941991;

NCT01345006;

NCT01344993;

NCT02445612;

NCT02463344;

NCT02563782;

NCT02122159;

NCT03167203

9 Study of Subretinal

Implantation of

Human Embryonic

Stem Cell-Derived

RPE Cells in

Advanced dAMD

Active, not

recruiting

[40, 41] dAMD Regenerative

Patch

Technologies,

LLC

Phase 1/2 Interventional February

2016

June 2023 U.S.A.

10 RPE Safety Study

for Patients in

B4711001

Active, not

recruiting

[26] AMD Moorfields Eye

Hospital NHS

Foundation

Trust

Phase 1/2 Interventional September

2016

October

2020

U.K. NCT03102138

11 A Phase I/IIa,

Open-Label,

Single-Center,

Prospective Study

to Determine the

Safety and

Tolerability of

Sub-retinal

Transplantation of

Human Embryonic

Stem Cell Derived

RPE (MA09-hRPE)

in Patients with

Advanced dAMD

Unknown

status

No

Publications

Available

dAMD CHABiotech

CO., Ltd

Phase 1/2 Interventional September

2012

June 2020 Republic

of Korea

NCT01674829 NCT01625559;

NCT03305029

12 Safety and Efficacy

Study of OpRegen

for Treatment of

Advanced

Dry-Form

Age-Related

Macular

Degeneration

Active, not

recruiting

No

Publications

Available

AMD Lineage Cell

Therapeutics,

Inc.; CellCure

Neurosciences

Ltd.

Phase 1/2 Interventional April 2015 December

2024

U.S.A.;

Israel

NCT02286089

NCT, National Clinical Trial; RPESC, retinal pigment epithelial stem cell; dAMD, dry age-related macular degeneration; NIH, National Institutes of Health; NEI, National Eye Institute; RP,

retinitis pigmentosa; LCA, Leber congenital amaurosis; RPE, retinal pigment epithelium; AMD, age-related macular degeneration; SMD, Stargardt’s macular dystrophy; MMD, myopic macular

degeneration.

patch of ESC-derived RPE monolayer attached to
a synthetic parylene substrate.[40] The initiative
is called California Project to Cure Blindness.
They implanted this engineered patch in 16
patients with advanced non-neovascular AMD
with a median age of 78 years in a single-
arm, open-label, prospective, non-randomized,
phase 1/2 study.[41] Critical inclusion criteria were

advanced non-neovascular AMD, pseudophakia,
and severe vision loss. Mild to moderate subretinal
hemorrhages and macular holes were reported as
adverse events. One patient developed ischemic
colitis, possibly related to immunosuppression.

Employing a similar approach, an initiative
called “The London Project to Cure Blindness”
published data on a phase 1 trial encompassing

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RPE Transplantation; Khan et al

two patients with severe wet AMD.[26] Their patch
was also made of differentiated ESC-derived RPE,
but the scaffold was made of polyester membrane
coated with human vitronectin. Using purpose-
built microsurgical tools, the RPE patches were
delivered subretinally to one eye in each of the two
patients with severe exudative AMD. They reported
successful delivery and survival of the RPE patch
and a visual acuity gain of 29 and 21 letters in
the two patients, respectively, over 12 months.
Importantly, preclinical safety studies did not reveal
tumorigenicity or notable proliferative capacity of
the ESC-derived RPE cells. Undifferentiated ESCs
were not detected in the final differentiated RPE
product. Furthermore, investigation of systemic
biodistribution 26 weeks after implantation of the
RPE grafts in pigs did not provide any evidence
of migration of cells distant to the administration
site. Although the number of patients included in
the study is too low to conclude on the clinical
efficiency of the RPE patch, the report provides
valuable information about the surgical technique,
stability of the transplant, and the safety of the ESC-
derived cells.

CONCLUSION

As the aforementioned reports indicate, human
RPE transplantation is still in its early days.
Significant challenges related to graft composition,
graft vehicle, and surgical technique need to
be addressed. However, it is encouraging that,
despite these challenges, the mentioned studies
report positive outcomes following transplantation.
Future clinical trials are therefore eagerly
awaited. As of this writing, 12 RPE transplantation
projects are listed on the clinical trials database
ClinicalTrials.gov [Table 1], all being phase 1/2
trials assessing safety, side effects, and dosing.
The most frequently occurring indication remains
AMD. However, SMD, RP, and Leber congenital
amaurosis are other diseases listed as indications
for some ongoing trials. The majority of the projects
seem to employ RPE cells derived from ESC. Based
on this and the aforementioned recent studies, it is
the authors’ impression that the current front-line
of RPE transplantation is based on cell delivery as
a patch using ESC-derived RPE.

Financial Support and Sponsorship

None.

Conflicts of Interest

There are no conflicts of interest.
TPU and JRE hold a patent on the culture

of retinal pigment epithelial cells: https://patents.
google.com/patent/US20180119097A1/en.

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