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Literature DB >> 23407356

Imaging light responses of retinal ganglion cells in the living mouse eye.

Lu Yin¹, Ying Geng, Fumitaka Osakada, Robin Sharma, Ali H Cetin, Edward M Callaway, David R Williams, William H Merigan.

Abstract

This study reports development of a novel method for high-resolution in vivo imaging of the function of individual mouse retinal ganglion cells (RGCs) that overcomes many limitations of available methods for recording RGC physiology. The technique combines insertion of a genetically encoded calcium indicator into RGCs with imaging of calcium responses over many days with FACILE (functional adaptive optics cellular imaging in the living eye). FACILE extends the most common method for RGC physiology, in vitro physiology, by allowing repeated imaging of the function of each cell over many sessions and by avoiding damage to the retina during removal from the eye. This makes it possible to track changes in the response of individual cells during morphological development or degeneration. FACILE also overcomes limitations of existing in vivo imaging methods, providing fine spatial and temporal detail, structure-function comparison, and simultaneous analysis of multiple cells.

Entities: Chemical Disease Species

Keywords: calcium imaging; in vivo adaptive optics imaging; retinal ganglion cells

Mesh：

Substances：
Calcium

Year: 2013 PMID： 23407356 PMCID： PMC3652215 DOI： 10.1152/jn.01043.2012

Source DB: PubMed Journal: J Neurophysiol ISSN： 0022-3077 Impact factor: 2.714

45 in total

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9. Dark light, rod saturation, and the absolute and incremental sensitivity of mouse cone vision.

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10. From candelas to photoisomerizations in the mouse eye by rhodopsin bleaching in situ and the light-rearing dependence of the major components of the mouse ERG.

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30 in total

Imaging light responses of retinal ganglion cells in the living mouse eye.

Review 1. Genetically engineered fluorescent voltage reporters.

2. The Psychophysics Toolbox.

3. Spectral and temporal sensitivity of cone-mediated responses in mouse retinal ganglion cells.

4. New rabies virus variants for monitoring and manipulating activity and gene expression in defined neural circuits.

5. Two different visual pigments in one retinal cone cell.

6. Rods and cones in the mouse retina. I. Structural analysis using light and electron microscopy.

7. The murine cone photoreceptor: a single cone type expresses both S and M opsins with retinal spatial patterning.

8. The primordial, blue-cone color system of the mouse retina.

9. Dark light, rod saturation, and the absolute and incremental sensitivity of mouse cone vision.

10. From candelas to photoisomerizations in the mouse eye by rhodopsin bleaching in situ and the light-rearing dependence of the major components of the mouse ERG.

1. In vivo two-photon imaging of the mouse retina.

Review 2. In vivo imaging methods to assess glaucomatous optic neuropathy.

3. Imaging translucent cell bodies in the living mouse retina without contrast agents.

4. Adaptive optics two-photon excited fluorescence lifetime imaging ophthalmoscopy of exogenous fluorophores in mice.

5. Imaging light responses of foveal ganglion cells in the living macaque eye.

6. High-speed adaptive optics line-scan OCT for cellular-resolution optoretinography.

7. Adaptive optics in the mouse eye: wavefront sensing based vs. image-guided aberration correction.

8. In Vivo Functional Imaging of Retinal Neurons Using Red and Green Fluorescent Calcium Indicators.

9. Image registration and averaging of low laser power two-photon fluorescence images of mouse retina.

10. Adaptive optics ophthalmoscopy.