A single-cell level comparison of human inner ear organoids with the human cochlea and vestibular organs
Wouter H. van der Valk, Edward S. A. van Beelen, Matthew R. Steinhart, Carl Nist-Lund, Daniel Osorio, John C.M.J. de Groot, Liang Sun, Peter Paul G. van Benthem, Karl R. Koehler, Heiko Locher
Abstract
(Cell Reports 42, 112623; June 27, 2023) The authors acknowledge the presence of the following errors identified in the STAR Methods section of the article. The errors have now been corrected online. •Original: Mouse monoclonal anti-WRHN (1:50)•Correction: Mouse monoclonal anti-WHRN (1:50)•Original: Mouse monoclonal anti-TUBB3A (1:100) Biolegend•Correction: Mouse monoclonal anti-TUBB3 (1:100) Biolegend•Original: Mouse monoclonal anti-TUBB3A (1:100) R&D Systems•Correction: Mouse monoclonal anti-TUBB3 (1:100) R&D Systems •Original: 50 μg/mL bFGF•Correction: 50 ng/mL bFGF These errors arose from oversight during the proofreading process and were not identified until after publication. We sincerely apologize for any confusion they may have caused. The corrections aim to ensure the accuracy and clarity of the methods described in the STAR Methods. The authors regret this error. A single-cell level comparison of human inner ear organoids with the human cochlea and vestibular organsvan der Valk et al.Cell ReportsJune 6, 2023In BriefVan der Valk et al. highlight the potential of human stem cell-derived inner ear organoids for studying disorders. Single-cell transcriptomics identified various cell types linked to inner ear dysfunction, which are shared between organoids and the human inner ear. They offer an atlas for studying genetic inner ear disorders with organoids. Full-Text PDF Open Access