Peter W. Zandstra
Affiliations: | Biomedical Engineering | University of Toronto, Toronto, ON, Canada |
Area:
Biomedical Engineering, Molecular Biology, Cell BiologyWebsite:
https://www.ccrm.ca/Peter_ZandstraGoogle:
"Peter William Zandstra" OR "Peter W Zandstra"Bio:
Parents
Sign in to add mentor| Connie J. Eaves | grad student | 1997 | UBC (Cell Biology Tree) | |
| (co-supervisor) | ||||
| James M. Piret | grad student | 1997 | UBC (E-Tree) | |
| (Cytokine-dependent regulation of human hematopoietic cell self-renewal and differentiation in suspension cultures.) | ||||
| George Q. Daley | post-doc | 1997-1998 | MIT (Chemistry Tree) | |
| Linda Griffith | post-doc | 1997-1998 | MIT (Chemistry Tree) | |
| Doug A. Lauffenburger | post-doc | 1997-1998 | MIT (Chemistry Tree) | |
Children
Sign in to add trainee| Alborz Mahdavi | grad student | University of Toronto (Chemistry Tree) | |
| Sowmya Viswanathan | grad student | 2003 | University of Toronto |
| Stephen Dang | grad student | 2004 | University of Toronto |
| Gerard J. Madlambayan | grad student | 2004 | University of Toronto |
| Kelly A. Purpura | grad student | 2010 | University of Toronto |
| Kento Onishi | grad student | 2014 | University of Toronto |
| Nika Shakiba | grad student | 2010-2017 |
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Publications
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| Michaels YS, Major MC, Bonham-Carter B, et al. (2024) Tracking the gene expression programs and clonal relationships that underlie mast, myeloid, and T lineage specification from stem cells. Cell Systems |
| Dattani A, Corujo-Simon E, Radley A, et al. (2024) Naive pluripotent stem cell-based models capture FGF-dependent human hypoblast lineage specification. Cell Stem Cell |
| Michaels YS, Durland LJ, Zandstra PW. (2023) Engineering T Cell Development for the Next Generation of Stem Cell-Derived Immunotherapies. Gen Biotechnology. 2: 106-119 |
| Li B, Rodrigo-Torres D, Pelz C, et al. (2023) Cell networks in the mouse liver during partial hepatectomy. Biorxiv : the Preprint Server For Biology |
| Elbaz J, Puri MC, Faiz M, et al. (2022) Highly efficient reprogrammable mouse lines with integrated reporters to track the route to pluripotency. Proceedings of the National Academy of Sciences of the United States of America. 119: e2207824119 |
| Prochazka L, Michaels YS, Lau C, et al. (2022) Synthetic gene circuits for cell state detection and protein tuning in human pluripotent stem cells. Molecular Systems Biology. 18: e10886 |
| Kaul H, Werschler N, Jones RD, et al. (2022) Virtual cells in a virtual microenvironment recapitulate early development-like patterns in human pluripotent stem cell colonies. Stem Cell Reports |
| Michaels YS, Edgar JM, Major MC, et al. (2022) DLL4 and VCAM1 enhance the emergence of T cell-competent hematopoietic progenitors from human pluripotent stem cells. Science Advances. 8: eabn5522 |
| Edgar JM, Michaels YS, Zandstra PW. (2022) Multi-objective optimization reveals time- and dose-dependent inflammatory cytokine-mediated regulation of human stem cell derived T-cell development. Npj Regenerative Medicine. 7: 11 |
| Ma J, Tran G, Wan AMD, et al. (2021) Microdroplet-based one-step RT-PCR for ultrahigh throughput single-cell multiplex gene expression analysis and rare cell detection. Scientific Reports. 11: 6777 |