Global ETD Search

1	The influence of the labyrinth upon the stability of stance Iverson, Thyrza Elizabeth. January 1937 (has links) Thesis (M.S.)--University of Wisconsin--Madison, 1937. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references. Labyrinth (Ear)
2	The morphology of the amphibian endolymphatic organ Dempster, W. T. January 1900 (has links) Thesis (Ph. D.)--University of Michigan, 1929. / Cover title. Descriptive letterpress on versos facing the plates. "Reprinted from the Journal of morphology and physiology, vol. 50, no. 1, September, 1930." "Literature cited": p. 114-120. Labyrinth (Ear) Amphibians
3	War deafness and its prevention report of the labyrinths of the animals used in testing of preventive measures. (Middle ears previously reported). Guild, Stacy Rufus, January 1900 (has links) Thesis (Ph. D.)--University of Michigan, 1918. / Cover title. "Reprint from the Journal of laboratory and clinical medicine, St. Louis, vol. IV, no. 4, January, 1919." Bibliography: p. 18. Deafness. Labyrinth (Ear)
4	Du role de certains médicaments et en particulier des anesthésique dans la genèse des troubles labyrinthiques ... Allanic, Jean François Marie. January 1901 (has links) Thèse--Faculté de medecine de Paris. / "Index bibliographique": p. [45]-47. Anesthetics. Labyrinth (Ear) Ear
5	Experiments on the labyrinth of the frog. McNally, William James, 1897-. January 1925 (has links) No description available. Frogs. Physiology. Labyrinth (Ear).
6	Bioinformatic and functional approaches to identify potential SOX9 target genes in inner ear development Mak, Chi-yan, Angel, 麥志昕 January 2010 (has links) published_or_final_version / Biochemistry / Doctoral / Doctor of Philosophy Transcription factors Labyrinth (Ear) - Growth
7	Sox2 and inner ear development Li, Junchang, 李俊畅 January 2012 (has links) Sox2, a HMG box transcription factor, is well known for its role in stem cell maintenance, iPS (induced pluripotent stem cell) induction, and development of neural tissues such as central nervous system and sensory organs. Sox2 has been demonstrated to be essential for the development of inner ear sensory patches. It has been shown that Sox2 is under the regulation of multiple regulatory elements to obtain a tissue specific manner. Two allelic mouse mutants, yellow submarine (Ysb) and Light coat and circling (Lcc) show hearing and balance impairments with different severity. They were made by random insertions of a transgene (pAA2) and X-ray irradiation respectively. Ysb and Lcc are both localized to chromosome 3 and involve complex chromosomal rearrangements. The Sox2 coding region is intact in the mutants, while the Sox2 expression in the otocyst is greatly reduced in Ysb and totally lost in Lcc, which indicates the tissue specific reduction of Sox2 may be due to the rearrangement of Sox2 regulatory element(s). Since Sox2 null mutants die before implantation, the two Sox2 inner ear mutants are valuable models for studying Sox2 knock down (Ysb) and Sox2 knock out (Lcc) condition in the inner ear. To understand the molecular basis behind Sox2 regulation in the inner ear, this project aims to identify the Sox2 otic regulatory elements, and potential Sox2 downstream targets involved in the development of inner ear. Previous work has indicated that Nop1 and Nop2 are the otic specific regulatory elements of Sox2 in chicken ear. In this project, transgenic mice were generated using Nop1-Nop2, and the result showed Nop1-Nop2 could drive Sox2 expression to the dorsal side of the otiv vesicle, which is different from the endogenous Sox2 expression pattern. Therefore, Nop1 and Nop2 may require other regulatory element(s) to gain a correct regulatory pattern. BAC(RP23-335P23), which contained the DNA sequences close to Ysb integration site 1 was also been tested in transgenic mice. Interestingly, the result showed that BAC(RP23-335P23) could drive Sox2 expression to the ventral side of the otic vesicle, indicating that this BAC may contain the Sox2 otic regulatory element(s). In this project, the binding relationship between Sox2 protein and Math1 enhancer has also been identified using chromatin immunoprecipitation (Ch-IP). Results showed that Sox2 could bind to Math1 enhancer A in the inner ear cochlea. So Sox2 may regulate Math1 through binding to Math1 enhancer A in inner ear development. Using a bioinformatics approach, potential Sox2 target genes in inner ear development have been identified from public microarray data on E9 to E15 inner ear tissue by the presence of conserved Sox2 binding sites. Among these potential targets, 4 genes (Itga6, Erbb3, Sox10 and Mycn) have been selected based on their known functions. Their expression patterns in the cochlea of wild type, Ysb and Lcc were verified. The identification of Sox2 downstream target genes using a bioinformatics approach will help us to understand the molecular basis of Sox2 regulation, and also understand the role of Sox2 in the inner ear development. / published_or_final_version / Biochemistry / Master / Master of Philosophy Transcription factors Labyrinth (Ear) - Growth
8	Effects of vestibular stimulation on motor development in cerebral palsy children / Chee, Francis Kou Wing. January 1975 (has links) Thesis (M.S.)--Ohio State University. / Bibliography: leaves 118-128. Available online via OhioLINK's ETD Center
9	Structure and function of the membranous sacs of the labyrinth in Acanthias vulgaris Vilstrup, Thure. January 1951 (has links) Afhandling - Copenhagen. / Summary in English and Danish. Bibliography: p. [131]-134.
10	The roles of Irx3 and Irx5 genes in mammalian inner ear development Liu, Yuchen, 刘雨辰 January 2012 (has links) Iroquois genes encode a family of highly conserved TALE homeodomain transcription factors that are involved in multiple developmental processes. Physiological tests indicated that Irx3 and Irx5 mutant mice displayed hearing impairment. However, the functions of these two genes during inner ear development are not known. The aim of this study is to characterize the roles of Irx3 and Irx5 during mammalian inner ear development using mouse models, in order to reveal the underlying mechanism for the hearing abnormality in the mutants. Two mouse mutants, Irx3tauLacZ and Irx3flox5EGFP with β-gal and EGFP reporters, were analyzed to examine the expression of these two genes in the otic vesicle and cochlear epithelium. In the otocyst, both Irx3 and Irx5 were expressed in the ventral-medial region. Irx5 expression was restricted to the non-sensory domain of the cochlear epithelia, while Irx3 was widely expressed, including the auditory sensory organ, the organ of Corti. The overlapping expression patterns of Irx3 and Irx5 suggest that they may share redundant functions. To investigate the roles of Irx3 and Irx5 during inner ear development, phenotypic analysis was performed on Irx3-/-, Irx5-/- and Irx3/5-/- mutant embryos. As shown by paint-filling analysis, Irx3/5-/- displayed shortened cochlear duct, enlarged cochlear lumen with fused sensory organ. Whole-mount phalloidin staining of hair cell bundles showed that Irx3-/- displayed occasional ectopic inner hair cells. Moreover, only supernumerary vestibular hair cell-like cells were developed in Irx3/5-/- mutant. These results suggest that Irx3 and Irx5 are required for inner ear morphogenesis and the formation of organ of Corti. To understand the effect of Irx3 and Irx5 in the cellular patterning of the cochlea, mutant cochleae were analyzed with markers for different regions of the cochlear epithelia. Altered expression domain of MyoVIIa, Sox2 and Gata2 in Irx3/5-/- cochlea revealed that the boundary between the Kolliker’s organ and the organ of Corti was lost and the location of sensory and non-sensory region was shifted. These results imply that Irx3 and Irx5 function in the establishment of the sensory/non-sensory boundary. It is known that p27kip1 regulates the wave of cell cycle exit in the developing organ of Corti and Sox2 takes part in prosensory specification. To explore the underlying reason for the patterning defects in Irx3/5-/- mutant, cochlear duct from prosensory stages were analyzed. Irx3/5-/- showed altered Sox2 and p27kip1 expression, with expanded prosensory domain and disrupted cell cycle exit. Ectopic prosensory proliferation was detected in the middle turn of the cochlear duct at E13.5 by BrdU incorporation assay. Therefore, Irx3 and Irx5 may participate in the subdivision of sensory territory in developing cochlea by controlling prosensory proliferation. In summary, this study demonstrates that Irx3 and Irx5 cooperate in multiple aspects of inner ear development: an early role to regulate prosensory proliferation and cell cycle exit; a second role to regulate cellular patterning of the cochlear duct by controlling the setting of sensory/non-sensory boundaries in the cochlea; a later role to regulate inner ear morphogenesis. This study supports the idea that Irx3 and Irx5 act as patterning genes during vertebrate evolution. / published_or_final_version / Biochemistry / Master / Master of Philosophy Transgenic mice Deafness - Genetic aspects Labyrinth (Ear)

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