The Hamner Institutes and Cellular Dynamics Collaborate
News Dec 09, 2013
Current in vitro models of liver function employ immortalized cell lines, animal models and primary tissue isolates harvested from human cadavers. Each of these model systems presents limitations in functionality, reproducibility, translatability and availability.
Human iPS cell-derived hepatocytes could provide a consistent, reproducible and limitless source of liver tissue that reflects native liver function and may offer significant improvement over existing in vitro models.
CDI will provide iCell® Hepatocytes to The Hamner for use in an on-going program of research, referred to as “Toxicity Testing in the 21st Century: Toxicity Pathways and Network Biology.” This program employs several prototypical toxicity pathway case studies to develop human cell-based assays that map and model key cell signaling pathways in order to evaluate dose response. These assays, once validated with prototype chemicals, should enable toxicity testing and risk assessments based solely on in vitro test results, without progressing to toxicity studies in intact animals.
These in vitro-based toxicity testing schemes will speed testing of both important compounds in commerce and new compounds coming into use. More rapid testing will also help assess the backlog of thousands of chemicals for which there is very limited toxicity test data. As these test technologies mature, they could also provide a means to speed drug discovery by providing assessments of safety far earlier in the drug development process.
The Hamner toxicity pathway research program is a pre-competitive, multi-organization partnership designed to advance an integrated systems biology approach to toxicity testing research. Partners sponsoring the research include Agilent Technologies Inc., Illumina, Dow Chemical, Dow Corning Corporation, ExxonMobil, Unilever and CropLife America member companies. The Long-Range Research Initiative (LRI) of the American Chemistry Council supported earlier stages of this research. CDI will join this consortium and will collaborate with Hamner scientists on technical aspects of assay development.
“The Hamner’s multi-stakeholder toxicity testing program needs a variety of normal cell types for studying chemical toxicity in human cells. New iPS-cell technologies, spearheaded by CDI, promise to make many stem cell-derived products available to transform in vitro testing. We are particularly enthusiastic about the use of iCell Hepatocytes to create models of liver toxicity and for evaluating pathways of metabolism,” said Dr. Melvin Andersen, project director at The Hamner. “More broadly, stem cell products enhance work on the whole suite of pathways of interest to our diverse partners. As other stem cell platforms develop, we can connect them sequentially and examine multi-day treatment for many tissues with realistic exposures. These iCell Hepatocytes and other emerging stem cell-based products provide great value for safety assessments for all our partners.”
Chris Parker, chief commercial officer of CDI, said, “We are excited to be working with The Hamner and this consortium to work toward better predictivity of human response to chemical compounds. Current models miss toxicities that might only manifest themselves in a human cell model, or falsely misidentify toxicities for compounds that would be safe. Published studies have shown numerous examples of our human iPS cell-derived iCell products to be more predictive than comparison current cell models. Through this collaboration we hope to further improve the safety of chemical compounds as well as the efficiency of research studies.”
A report of a recent review of The Hamner program “Toxicity Testing in the 21st Century: Toxicity Pathways and Network Biology” is available at www.thehamner.org/tt21c and provides a synopsis of the first prototype pathways serving as examples of this integrated systems biology approach to toxicity testing.
Innate Reaction of Hematopoietic Stem Cells to Severe InfectionsNews
Researchers at the University of Zurich have shown for the first time that hematopoietic stem cells detect infectious agents themselves and begin to divide, without signals from growth factors.READ MORE
Using Milk Protein to 3D-Imprint Muscle and Bone CellsNews
Researchers from the University of Canterbury are replicating a 3D imprint of cells onto films made of milk protein. The films then gradually degrade, leaving the grown tissue behind.READ MORE
Comments | 0 ADD COMMENT
EMBL Conference: European Conference of Life Science Funders and Foundations
Apr 19 - Apr 20, 2018
EMBL Course: Transgenic Animals - Micromanipulation Techniques
Apr 10 - Apr 11, 2018
EMBO Practical Course: Extracellular Vesicles: From Biology to Biomedical Applications
Apr 09 - Apr 13, 2018