LSFM4LIFE | Production and characterization of endocrine cells derived from human pancreas organoids for the cell-based therapy of type 1 diabetes

Summary
Self-renew and multilineage potential characterize stem cells. We have recently described that pancreas progenitor cells extracted from adult donors can be expanded long-term in vitro into 3D structures, which we have termed organoids. Pancreas organoids reproduce in vitro all the features of pancreas ductal epithelia, and have a limitless expansion potential. Thus, pancreas organoids promise to boost cell therapy of type 1 diabetes. We have recently observed that progenitor cells organoids preserve their genetic stability over a long time in culture. That represents an advantage, when compared to iPS or hES derived approaches, where genetic instability raises concerns for their future therapeutic applications. While progenitor organoids are promising for the future of cell therapy, bringing stem cell-based therapies to patients requires a reliable characterization (“knowing what the cells do and how they do it”, i.e. a phenotypic and molecular biology characterization), chemically well-defined culture media, and the capacity of mass-production under GLP/GMP conditions.
The LSFM4LIFE consortium aims to the mass production of pancreas organoids for the cellular therapy of type 1 diabetes. The goals of the project are: (1) optimize growth and differentiation of human pancreas stem-cell organoids by employing phenotypic and molecular high-throughput screening (2) standardize the growth and differentiation of the organoids under well-defined biochemical conditions, and (3) achieve GLP/GMP-production of the human organoids for preclinical studies and phase I clinical studies. The close collaboration in the consortium between academic researchers and industry, as well as its cross-disciplinary composition, are essential to realize the goals of the project. The work packages of the project will have a technological impact in the form of patents and first market replication.
Unfold all
/
Fold all
More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/668350
Start date: 01-01-2016
End date: 31-12-2019
Total budget - Public funding: 5 120 275,00 Euro - 4 666 400,00 Euro
Cordis data

Original description

Self-renew and multilineage potential characterize stem cells. We have recently described that pancreas progenitor cells extracted from adult donors can be expanded long-term in vitro into 3D structures, which we have termed organoids. Pancreas organoids reproduce in vitro all the features of pancreas ductal epithelia, and have a limitless expansion potential. Thus, pancreas organoids promise to boost cell therapy of type 1 diabetes. We have recently observed that progenitor cells organoids preserve their genetic stability over a long time in culture. That represents an advantage, when compared to iPS or hES derived approaches, where genetic instability raises concerns for their future therapeutic applications. While progenitor organoids are promising for the future of cell therapy, bringing stem cell-based therapies to patients requires a reliable characterization (“knowing what the cells do and how they do it”, i.e. a phenotypic and molecular biology characterization), chemically well-defined culture media, and the capacity of mass-production under GLP/GMP conditions.
The LSFM4LIFE consortium aims to the mass production of pancreas organoids for the cellular therapy of type 1 diabetes. The goals of the project are: (1) optimize growth and differentiation of human pancreas stem-cell organoids by employing phenotypic and molecular high-throughput screening (2) standardize the growth and differentiation of the organoids under well-defined biochemical conditions, and (3) achieve GLP/GMP-production of the human organoids for preclinical studies and phase I clinical studies. The close collaboration in the consortium between academic researchers and industry, as well as its cross-disciplinary composition, are essential to realize the goals of the project. The work packages of the project will have a technological impact in the form of patents and first market replication.

Status

CLOSED

Call topic

PHC-16-2015

Update Date

26-10-2022
Images
No images available.
Geographical location(s)
Structured mapping
Unfold all
/
Fold all
Horizon 2020
H2020-EU.3. SOCIETAL CHALLENGES
H2020-EU.3.1. SOCIETAL CHALLENGES - Health, demographic change and well-being
H2020-EU.3.1.3. Treating and managing disease
H2020-EU.3.1.3.0. Cross-cutting call topics
H2020-PHC-2015-two-stage
PHC-16-2015 Tools and technologies for advanced therapies