https://amandajaynecarr.owlstown.net https://amandajaynecarr.owlstown.net/publications https://amandajaynecarr.owlstown.net/projects https://amandajaynecarr.owlstown.net/people https://amandajaynecarr.owlstown.net/courses https://amandajaynecarr.owlstown.net/posts https://amandajaynecarr.owlstown.net/pages https://amandajaynecarr.owlstown.net/cv https://amandajaynecarr.owlstown.net/contact_form https://amandajaynecarr.owlstown.net/publications/19828-translational-readthrough-as-a-potential-therapeutic-for-aipl-1-associated-leber-congenital-amaurosis-in-a-patient-derived-ipsc-retinal-organoid-model https://amandajaynecarr.owlstown.net/publications/19829-bestrophinopathies-perspectives-on-clinical-disease-bestrophin-1-function-and-developing-therapies https://amandajaynecarr.owlstown.net/publications/19831-bestrophin1-a-gene-that-causes-many-diseases https://amandajaynecarr.owlstown.net/publications/19830-phenotypic-and-functional-characterization-of-muller-glia-isolated-from-induced-pluripotent-stem-cell-derived-retinal-organoids-improvement-of-retinal-ganglion-cell-function-upon-transplantation https://amandajaynecarr.owlstown.net/publications/19832-phase-1-clinical-study-of-an-embryonic-stem-cell-textendash-derived-retinal-pigment-epithelium-patch-in-age-related-macular-degeneration https://amandajaynecarr.owlstown.net/publications/19833-regulation-of-retinal-pigment-epithelial-cell-phenotype-by-annexin-a8 https://amandajaynecarr.owlstown.net/publications/19834-rescue-of-the-mertk-phagocytic-defect-in-a-human-ipsc-disease-model-using-translational-read-through-inducing-drugs https://amandajaynecarr.owlstown.net/publications/19835-spontaneous-generation-of-patient-specific-retinal-pigment-epithelial-cells-using-induced-pluripotent-stem-cell-technology https://amandajaynecarr.owlstown.net/publications/19837-mislocalisation-of-best-1-in-ipsc-derived-retinal-pigment-epithelial-cells-from-a-family-with-autosomal-dominant-vitreoretinochoroidopathy-advirc https://amandajaynecarr.owlstown.net/publications/19836-identification-and-correction-of-mechanisms-underlying-inherited-blindness-in-human-ipsc-derived-optic-cups https://amandajaynecarr.owlstown.net/publications/19839-using-stem-cells-to-model-diseases-of-the-outer-retina https://amandajaynecarr.owlstown.net/publications/19841-neural-retinal-regeneration-with-pluripotent-stem-cells https://amandajaynecarr.owlstown.net/publications/19840-engineering-efficient-retinal-pigment-epithelium-differentiation-from-human-pluripotent-stem-cells https://amandajaynecarr.owlstown.net/publications/19838-translational-read-through-of-the-rp-2-arg120stop-mutation-in-patient-ipsc-derived-retinal-pigment-epithelium-cells https://amandajaynecarr.owlstown.net/publications/19842-development-of-human-embryonic-stem-cell-therapies-for-age-related-macular-degeneration https://amandajaynecarr.owlstown.net/publications/19843-stem-cells-in-retinal-regeneration-past-present-and-future https://amandajaynecarr.owlstown.net/publications/19847-the-expression-of-retinal-cell-markers-in-human-retinal-pigment-epithelial-cells-and-their-augmentation-by-the-synthetic-retinoid-fenretinide https://amandajaynecarr.owlstown.net/publications/19844-degeneration-of-cortical-function-in-the-royal-college-of-surgeons-rat https://amandajaynecarr.owlstown.net/publications/19845-lbrace-ips-rbrace-cells-an-alternative-source-of-lbrace-rpe-rbrace https://amandajaynecarr.owlstown.net/publications/19846-induction-of-differentiation-by-pyruvate-and-lbrace-dmem-rbrace-in-the-human-retinal-pigment-epithelium-cell-line-lbrace-arpe-rbrace-19 https://amandajaynecarr.owlstown.net/publications/19849-molecular-characterization-and-functional-analysis-of-phagocytosis-by-human-embryonic-stem-cell-derived-rpe-cells-using-a-novel-human-retinal-assay https://amandajaynecarr.owlstown.net/publications/19848-protective-effects-of-human-ips-derived-retinal-pigment-epithelium-cell-transplantation-in-the-retinal-dystrophic-rat https://amandajaynecarr.owlstown.net/publications/19850-embryonic-stem-cells-and-retinal-repair https://amandajaynecarr.owlstown.net/publications/19851-light-reaches-the-very-heart-of-the-zebrafish-clock https://amandajaynecarr.owlstown.net/publications/19854-the-tau-mutation-in-the-syrian-hamster-differentially-reprograms-the-circadian-clock-in-the-scn-and-peripheral-tissues https://amandajaynecarr.owlstown.net/publications/19852-the-fish-watch-zebrafish-a-clock-in-every-cell https://amandajaynecarr.owlstown.net/publications/19853-zebrafish-circadian-clocks-cells-that-see-light https://amandajaynecarr.owlstown.net/publications/19855-imaging-of-single-light-responsive-clock-cells-reveals-fluctuating-free-running-periods https://amandajaynecarr.owlstown.net/publications/19858-evidence-for-an-endogenous-per1-and-icer-independent-seasonal-timer-in-the-hamster-pituitary-gland https://amandajaynecarr.owlstown.net/publications/19856-photoperiod-differentially-regulates-circadian-oscillators-in-central-and-peripheral-tissues-of-the-syrian-hamster https://amandajaynecarr.owlstown.net/publications/19857-photoperiod-differentially-regulates-circadian-oscillators-in-central-and-peripheral-tissues-of-the-syrian-hamster https://amandajaynecarr.owlstown.net/projects/2286-untitled