TGFβ superfamily signaling regulates the state of human stem cell pluripotency and capacity to create well-structured telencephalic organoids | Zendy

Momoko Watanabe | Zendy; Jessie E. Buth | Zendy; Jillian R. Haney | Zendy; Neda Vishlaghi | Zendy; Felix Turcios | Zendy; Lubayna S. Elahi | Zendy; Wen Gu | Zendy; Caroline A. Pearson | Zendy; Arinnae Kurdian | Zendy; Natella V. Baliaouri | Zendy; Amanda J. Collier | Zendy; Osvaldo A. Miranda | Zendy; Natassia Dunn | Zendy; Di Chen | Zendy; Shan Sabri | Zendy; Luis de la Torre-Ubieta | Zendy; Amander T. Clark | Zendy; Kathrin Plath | Zendy; Heather R. Christofk | Zendy; Harley I. Kornblum | Zendy; Michael J. Gandal | Zendy; Bennett G. Novitch | Zendy

Open Access

TGFβ superfamily signaling regulates the state of human stem cell pluripotency and capacity to create well-structured telencephalic organoids

Author(s) -

Momoko Watanabe,

Jessie E. Buth,

Jillian R. Haney,

Neda Vishlaghi,

Felix Turcios,

Lubayna S. Elahi,

Wen Gu,

Caroline A. Pearson,

Arinnae Kurdian,

Natella V. Baliaouri,

Amanda J. Collier,

Osvaldo A. Miranda,

Natassia Dunn,

Di Chen,

Shan Sabri,

Luis de la Torre-Ubieta,

Amander T. Clark,

Kathrin Plath,

Heather R. Christofk,

Harley I. Kornblum,

Michael J. Gandal,

Bennett G. Novitch

Publication year - 2022

Publication title -

stem cell reports

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 3.207

H-Index - 76

ISSN - 2213-6711

DOI - 10.1016/j.stemcr.2022.08.013

Subject(s) - organoid , induced pluripotent stem cell , biology , transcriptome , microbiology and biotechnology , cellular differentiation , fibroblast growth factor , reprogramming , stem cell , transforming growth factor , neuroscience , computational biology , embryonic stem cell , cell , genetics , gene , gene expression , receptor

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