TY - JOUR
T1 - Stem Cell-Derived Systems in Toxicology Assessment
AU - Suter-Dick, Laura
AU - Alves, Paula M.
AU - Blaauboer, Bas J.
AU - Bremm, Klaus-Dieter
AU - Brito, Catarina
AU - Coecke, Sandra
AU - Flick, Burkhard
AU - Fowler, Paul
AU - Hescheler, Juergen
AU - Ingelman-Sundberg, Magnus
AU - Jennings, Paul
AU - Kelm, Jens M.
AU - Manou, Irene
AU - Mistry, Pratibha
AU - Moretto, Angelo
AU - Roth, Adrian
AU - Stedman, Donald
AU - van de Water, Bob
AU - Beilmann, Mario
PY - 2015/6/1
Y1 - 2015/6/1
N2 - Industrial sectors perform toxicological assessments of their potential products to ensure human safety and to fulfill regulatory requirements. These assessments often involve animal testing, but ethical, cost, and time concerns, together with a ban on it in specific sectors, make appropriate in vitro systems indispensable in toxicology. In this study, we summarize the outcome of an EPAA (European Partnership of Alternatives to Animal Testing)-organized workshop on the use of stem cell-derived (SCD) systems in toxicology, with a focus on industrial applications. SCD systems, in particular, induced pluripotent stem cell-derived, provide physiological cell culture systems of easy access and amenable to a variety of assays. They also present the opportunity to apply the vast repository of existing nonclinical data for the understanding of in vitro to in vivo translation. SCD systems from several toxicologically relevant tissues exist; they generally recapitulate many aspects of physiology and respond to toxicological and pharmacological interventions. However, focused research is necessary to accelerate implementation of SCD systems in an industrial setting and subsequent use of such systems by regulatory authorities. Research is required into the phenotypic characterization of the systems, since methods and protocols for generating terminally differentiated SCD cells are still lacking. Organotypical 3D culture systems in bioreactors and microscale tissue engineering technologies should be fostered, as they promote and maintain differentiation and support coculture systems. They need further development and validation for their successful implementation in toxicity testing in industry. Analytical measures also need to be implemented to enable compound exposure and metabolism measurements for in vitro to in vivo extrapolation. The future of SCD toxicological tests will combine advanced cell culture technologies and biokinetic measurements to support regulatory and research applications. However, scientific and technical hurdles must be overcome before SCD in vitro methods undergo appropriate validation and become accepted in the regulatory arena.
AB - Industrial sectors perform toxicological assessments of their potential products to ensure human safety and to fulfill regulatory requirements. These assessments often involve animal testing, but ethical, cost, and time concerns, together with a ban on it in specific sectors, make appropriate in vitro systems indispensable in toxicology. In this study, we summarize the outcome of an EPAA (European Partnership of Alternatives to Animal Testing)-organized workshop on the use of stem cell-derived (SCD) systems in toxicology, with a focus on industrial applications. SCD systems, in particular, induced pluripotent stem cell-derived, provide physiological cell culture systems of easy access and amenable to a variety of assays. They also present the opportunity to apply the vast repository of existing nonclinical data for the understanding of in vitro to in vivo translation. SCD systems from several toxicologically relevant tissues exist; they generally recapitulate many aspects of physiology and respond to toxicological and pharmacological interventions. However, focused research is necessary to accelerate implementation of SCD systems in an industrial setting and subsequent use of such systems by regulatory authorities. Research is required into the phenotypic characterization of the systems, since methods and protocols for generating terminally differentiated SCD cells are still lacking. Organotypical 3D culture systems in bioreactors and microscale tissue engineering technologies should be fostered, as they promote and maintain differentiation and support coculture systems. They need further development and validation for their successful implementation in toxicity testing in industry. Analytical measures also need to be implemented to enable compound exposure and metabolism measurements for in vitro to in vivo extrapolation. The future of SCD toxicological tests will combine advanced cell culture technologies and biokinetic measurements to support regulatory and research applications. However, scientific and technical hurdles must be overcome before SCD in vitro methods undergo appropriate validation and become accepted in the regulatory arena.
KW - HEPATOCYTE-LIKE CELLS
KW - SCALABLE SUSPENSION-CULTURE
KW - RENAL PROXIMAL TUBULES
KW - FUNCTIONAL HUMAN LIVER
KW - QUANTITATIVE IN-VITRO
KW - ORGAN BUD TRANSPLANT
KW - LONG-QT SYNDROME
KW - DRUG DEVELOPMENT
KW - EFFICIENT DIFFERENTIATION
KW - HEPATIC DIFFERENTIATION
U2 - 10.1089/scd.2014.0540
DO - 10.1089/scd.2014.0540
M3 - Literature review
SN - 1547-3287
VL - 24
SP - 1284
EP - 1296
JO - Stem Cells and Development
JF - Stem Cells and Development
IS - 11
ER -