Drina D. Sta. Iglesia

Johns Hopkins University, Baltimore, Maryland, United States

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Publications (2)5.49 Total impact

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    ABSTRACT: To isolate and characterize progenitor cells derived from adult mammalian ciliary body. The authors isolated progenitor cells from the ciliary body of adult mice, rats, and human cadaver eyes and determined quantitative growth characteristics of groups of progenitor cells called neurosphere (NS) cells, including individual cell diameter, NS diameter, percentage of NS-forming cells, and cell number per eye in mouse, rat, and human eyes. The immunolabeling and ultrastructure of NS cells were investigated by confocal and transmission electron microscopy. Average diameters of individual cells and neurospheres after 1 week in culture were similar in mice, rats, and humans (cell diameters: 22 +/- 1.1, 21 +/- 0.3, 25 +/- 0.4 mum; NS diameters: 139 +/- 22, 137 +/- 9, 141 +/- 11 mum, respectively). Mean numbers of cells per NS were estimated to be 1183 in mice, 5360 in rats, and 685 in humans. Molecules that were identified by immunolabeling in NS cells included nestin, Chx-10, vimentin, GFAP, and Pax-6. Thy-1 was expressed in some NS cells. Ultrastructurally, NS cells displayed abundant rough endoplasmic reticulum and many cellular processes but no characteristics of mature retinal neurons or glia. Progenitor cells from adult mammalian ciliary body have significant, but limited, proliferation potential and express markers characteristic of other progenitor cells and seen during early retinal development. The ciliary body could be a source of cells for transplantation in experimental rodent eyes and for autotransplantation in human eyes.
    Full-text · Article · Apr 2007 · Investigative Ophthalmology & Visual Science
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    H A Quigley · D S Iglesia
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    ABSTRACT: Methods that exist now and that might be developed are suggested to replace retinal ganglion cells and their axons in the optic nerve, ultimately to re-establish functional vision in eyes blind from glaucoma.
    Preview · Article · Dec 2004 · Eye