Bioreactor-produced iPSCs-derived dopaminergic neuron-containing neural microtissues innervate and normalize rotational bias in a dose-dependent manner in a Parkinson rat model

A breadth of preclinical studies now support the rationale of pluripotent stem cell-derived cell replacement therapies to alleviate motor symptoms in Parkinsonian patients. Replacement of the primary dysfunctional cell population in the disease, i.e. the A9 dopaminergic neurons, is the major focus o...

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Published in:Neurotherapeutics 2024-09, Vol.21 (5), p.e00436, Article e00436
Main Authors: Prudon, Nicolas, Cordero-Espinoza, Lucía, Abarkan, Myriam, Gurchenkov, Basile, Morel, Chloé, Lepleux, Marilyn, De Luca, Valérie, Lartigue, Maxime, Cabanas, Hélène, Pujol, Nadège, Milvoy, Loanne, Morand, Pauline, Moncaubeig, Fabien, Wurtz, Hélène, Poinçot, Léa, De Marco, Maëlle, Jonckeau, Agathe, Pletenka, Justine, Luquet, Elisa, Sovera, Andrea, Hardoüin, Jérôme, Neves, Inês Januario, Machado-Hitau, Anaïs, Schmit, Kathleen, Piouceau, Lucie, Guilbert, Solenn, Manache-Alberici, Lucie, Lanero Fidalgo, Michaël, Dabée, Guillaume, Dufourd, Thibault, Schroeder, Jens, Alessandri, Kévin, Bezard, Erwan, Faggiani, Emilie, Feyeux, Maxime
Format: Article
Language:English
Subjects:
3D cell format
Animals
Bioreactors
Cell Differentiation - physiology
Cell therapy
Disease Models, Animal
Dopaminergic Neurons - physiology
Dopaminergic Neurons - transplantation
Humans
Induced Pluripotent Stem Cells - physiology
Induced Pluripotent Stem Cells - transplantation
Male
Midbrain
Off-the-shelf
Organoid
Parkinson Disease - therapy
Rats
Rats, Sprague-Dawley
Regenerative medicine
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Summary:A breadth of preclinical studies now support the rationale of pluripotent stem cell-derived cell replacement therapies to alleviate motor symptoms in Parkinsonian patients. Replacement of the primary dysfunctional cell population in the disease, i.e. the A9 dopaminergic neurons, is the major focus of these therapies. To achieve this, most therapeutical approaches involve grafting single-cell suspensions of DA progenitors. However, most cells die during the transplantation process, as cells face anoïkis. One potential solution to address this challenge is to graft solid preparations, i.e. adopting a 3D format. Cryopreserving such a format remains a major hurdle and is not exempt from causing delays in the time to effect, as observed with cryopreserved single-cell DA progenitors. Here, we used a high-throughput cell-encapsulation technology coupled with bioreactors to provide a 3D culture environment enabling the directed differentiation of hiPSCs into neural microtissues. The proper patterning of these neural microtissues into a midbrain identity was confirmed using orthogonal methods, including qPCR, RNAseq, flow cytometry and immunofluorescent microscopy. The efficacy of the neural microtissues was demonstrated in a dose-dependent manner using a Parkinsonian rat model. The survival of the cells was confirmed by post-mortem histological analysis, characterised by the presence of human dopaminergic neurons projecting into the host striatum. The work reported here is the first bioproduction of a cell therapy for Parkinson's disease in a scalable bioreactor, leading to a full behavioural recovery 16 weeks after transplantation using cryopreserved 3D format. [Display omitted]
ISSN:1878-7479
1878-7479
DOI:10.1016/j.neurot.2024.e00436