Christelle Monville: Professor (UEVE)

Walter Habeler: Research associate (CECS)

Alexandra Plancheron: Qualified research technician (CECS)

Karim Ben M’Barek : Research associate (CECS)

Elise Herardot: Master student



Photoreceptors (PRs) convert light inputs into electrical signals that are further processed into the retina. These cells are in contact with the retinal pigment epithelium or RPE, which provides them trophic support and maintains PR homeostasis. A number of defects altering the functions of this RPE layer lead to some forms of PR degeneration. The loss of PRs, due to their malfunctions or to a primary dysfunction or death of RPE cells, might impact the vision of affected patients and in some cases ultimately lead to blindness. Retinitis Pigmentosa (RP) is a heterogeneous group of inherited disorders with more than 60 genes involved and could affect either the RPE, or the PRs or both. Taken individually, each monogenic dystrophy is rare but the global prevalence for RP is comprised between 1/3500 and 1/4000. Mutations affecting RPE functions account for 5% of all RP. Though the clinical picture is variable according to the nature of the mutation, patients usually experiment night vision loss followed by the reduction of visual field from the periphery to the centre (named tunnel vision). At late stages, central vision might also be lost leading to blindness. There is no available curative treatment for RP in Europe. In US, FDA approved the first gene therapy to treat RPE65 mutated patients. However, this treatment is susceptible to treat only a minority of patients.

Age-related macular degeneration (AMD) is the other main condition in which PRs degenerate. AMD, which represents the leading cause of blindness in western countries, is progressing among the population with an estimation of 288 million affected patients in 20401. The aetiology of AMD is multifactorial with a combination of genetic and environmental causes. Accumulation of deposits close to RPE cells, inflammatory modulation and oxidative damages seem to be at the origin of RPE alterations. Damages mainly occur in PRs located in the macular area, affecting thus the central vision. There is no curative treatment for 90% of AMD patients (dry form of AMD).

For all these diseases, a specific cell therapy strategy could be applied to fulfil this unmet medical need, depending on its stage in order to restore the degenerated tissue. For early cases of AMD, where RPE cells are lost and Bruch membrane damaged but PRs are still preserved and for RP associated to RPE defects also at early stages, a RPE cell therapy could be applied . We have developed such therapy recently with a phase I/II clinical trial for RP patients that will start by mid-2019.

When PRs are also lost or for RP associated to PR defects, a combination of PRs and RPE cell therapy corresponds to the more appropriated treatment. However, the proof of concept for this last combination was never demonstrated.



  • WO/2009/034108 (2009-03-19) PESCHANSKI, MARC; (FR). HABELER, Walter; (FR). MONVILLE, Christelle; (FR). An in vitro beating heart model.
  • Brevet National N°18/52114 (12/03/2018) Procédé et Dispositif pour la préparation d’un implant issu d’une culture de cellules souches. Ben M’Barek et al.


  • Dr. Olivier Goureau and Dr Emeline Nandrot, IDV, Inserm UMR S968, Paris, France, (ANR GPiPS)
  • Pr. Stéphane Blot, Laboratoire de Neuroscience, ENVA, Maisons-Alfort, France, (ANR Cardiostem)
  • Dr. Bijan Ghaleh and Pr Alain Berdeaux, Inserm U955, Créteil, France, (ANR Cardiostem)
  • Dr. Didier Letourneur and Dr Catherine Levisage, Inserm U698, Paris, France, (Utilisation de Matrices Biodégradables pour la culture et la greffe de cellules dérivées des hES)


More informations


Ben M’Barek K and Monville C. Cell Therapy for Retinal Dystrophies: From Cell Suspension Formulation to Complex Retinal Tissue Bioengineering, Stem Cells International. 2019 (2019).

Ben M'Barek K, Habeler W, Plancheron A, Jarraya M, Goureau O, Monville C. Engineering Transplantation-suitable Retinal Pigment Epithelium Tissue Derived from Human Embryonic Stem Cells. J Vis Exp. 2018 Sep 6;(139).

Voisin A, Monville C, Plancheron A, Balbous A, Gaillard A, Leveziel N. hRPE cells derived from induced pluripotent stem cells are more sensitive to oxidative stress than ARPE-19 cells. Exp Eye Res. 2018 Dec;177:76-86.

Ben M'Barek K, Habeler W, Goureau O, Monville C. [Treating retinal dystrophies affecting retinal pigment epithelium using tissue engineering obtained from human embryonic stem cells]. Med Sci (Paris). 2018 May;34(5):383-386.

Ben M'Barek K, Habeler W, Monville C. Stem Cell-Based RPE Therapy for Retinal Diseases: Engineering 3D Tissues Amenable for Regenerative Medicine. Adv Exp Med Biol. 2018;1074:625-632.

Ben M’Barek K, Habeler W, Plancheron A, Jarraya M, Régent F, Terray A, Yang Y, Chatrousse L, Domingues S, Masson Y, Sahel JA, Peschanski M, Goureau O, Monville C. Clinically compatible human ES-derived RPE cells grafted as an epithelium potentiates vision rescue in dystrophic rodent. Sci Transl Med. 2017 Dec 20;9(421).

Ben M'Barek K, Regent F, Monville C. Use of human pluripotent stem cells to study and treat retinopathies. World J Stem Cells. 2015 Apr 26;7(3):596-604.

Reichman S, Terray A, Slembrouck A, Nanteau C, Orieux G, Habeler W, Nandrot EF, Sahel JA, Monville C, Goureau O. From confluent human iPS cells to self-forming neural retina and retinal pigmented epithelium. Proc Natl Acad Sci USA. 2014 Jun 10;111(23):8518-23.