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Journal Abstract Search

233 related items for PubMed ID: 23935981

  • 1. Lineage analysis of the late otocyst stage mouse inner ear by transuterine microinjection of a retroviral vector encoding alkaline phosphatase and an oligonucleotide library.
    Jiang H, Wang L, Beier KT, Cepko CL, Fekete DM, Brigande JV.
    PLoS One; 2013; 8(7):e69314. PubMed ID: 23935981
    [Abstract] [Full Text] [Related]

  • 2. Establishment of mice expressing EGFP in the placode-derived inner ear sensory cell lineage and FACS-array analysis focused on the regional specificity of the otocyst.
    Fujimoto C, Ozeki H, Uchijima Y, Suzukawa K, Mitani A, Fukuhara S, Nishiyama K, Kurihara Y, Kondo K, Aburatani H, Kaga K, Yamasoba T, Kurihara H.
    J Comp Neurol; 2010 Dec 01; 518(23):4702-22. PubMed ID: 20963824
    [Abstract] [Full Text] [Related]

  • 3. Gene transfer to the developing mouse inner ear by in vivo electroporation.
    Wang L, Jiang H, Brigande JV.
    J Vis Exp; 2012 Jun 30; (64):. PubMed ID: 22781586
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  • 4. Calbindin and S100 protein expression in the developing inner ear in mice.
    Buckiová D, Syka J.
    J Comp Neurol; 2009 Apr 10; 513(5):469-82. PubMed ID: 19226521
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  • 7. Lineage analysis in the chicken inner ear shows differences in clonal dispersion for epithelial, neuronal, and mesenchymal cells.
    Lang H, Fekete DM.
    Dev Biol; 2001 Jun 01; 234(1):120-37. PubMed ID: 11356024
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  • 8. Anti-clarin-1 AAV-delivered ribozyme induced apoptosis in the mouse cochlea.
    Aarnisalo AA, Pietola L, Joensuu J, Isosomppi J, Aarnisalo P, Dinculescu A, Lewin AS, Flannery J, Hauswirth WW, Sankila EM, Jero J.
    Hear Res; 2007 Aug 01; 230(1-2):9-16. PubMed ID: 17493778
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  • 9. Isolation and Characterization of Mammalian Otic Progenitor Cells that Can Differentiate into Both Sensory Epithelial and Neuronal Cell Lineages.
    Kojima K, Nishida AT, Tashiro K, Hirota K, Nishio T, Murata M, Kato N, Kawaguchi S, Zine A, Ito J, Van De Water TR.
    Anat Rec (Hoboken); 2020 Mar 01; 303(3):451-460. PubMed ID: 31943808
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  • 11. Distinct capacity for differentiation to inner ear cell types by progenitor cells of the cochlea and vestibular organs.
    McLean WJ, McLean DT, Eatock RA, Edge AS.
    Development; 2016 Dec 01; 143(23):4381-4393. PubMed ID: 27789624
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  • 12. SOX2 is required for inner ear growth and cochlear nonsensory formation before sensory development.
    Steevens AR, Glatzer JC, Kellogg CC, Low WC, Santi PA, Kiernan AE.
    Development; 2019 Jun 21; 146(13):. PubMed ID: 31152002
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  • 15. Effects of age and sex on the expression of estrogen receptor alpha and beta in the mouse inner ear.
    Motohashi R, Takumida M, Shimizu A, Konomi U, Fujita K, Hirakawa K, Suzuki M, Anniko M.
    Acta Otolaryngol; 2010 Feb 21; 130(2):204-14. PubMed ID: 19479455
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  • 16. Islet-1 expression in the developing chicken inner ear.
    Li H, Liu H, Sage C, Huang M, Chen ZY, Heller S.
    J Comp Neurol; 2004 Sep 06; 477(1):1-10. PubMed ID: 15281076
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  • 17. MicroRNA-183 family members regulate sensorineural fates in the inner ear.
    Li H, Kloosterman W, Fekete DM.
    J Neurosci; 2010 Mar 03; 30(9):3254-63. PubMed ID: 20203184
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  • 18. Immunolocalization of Na+, K(+)-ATPase, Ca(++)-ATPase, calcium-binding proteins, and carbonic anhydrase in the guinea pig inner ear.
    Ichimiya I, Adams JC, Kimura RS.
    Acta Otolaryngol; 1994 Mar 03; 114(2):167-76. PubMed ID: 8203199
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  • 19. Hair cells and supporting cells share a common progenitor in the avian inner ear.
    Fekete DM, Muthukumar S, Karagogeos D.
    J Neurosci; 1998 Oct 01; 18(19):7811-21. PubMed ID: 9742150
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  • 20. Role of mitochondrial uncoupling protein 4 in rat inner ear.
    Smorodchenko A, Rupprecht A, Fuchs J, Gross J, Pohl EE.
    Mol Cell Neurosci; 2011 Aug 01; 47(4):244-53. PubMed ID: 21397696
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