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Literature DB >> 25824961

Neuronal activity-dependent regulation of retinal blood flow.

Jonathan E Noonan¹, Ecosse L Lamoureux^1,2,3, Marc Sarossy¹.

Abstract

Blood flow in the retina is intrinsically regulated to meet the metabolic demands of its constituent cells. Flickering light or stationary contrast reversals induce an increase in blood flow within seconds of the stimulus onset. This phenomenon is thought to compensate for an increase in ganglion cell activity and energy consumption. Ganglion cell activity is in turn dependent on signals from photoreceptors, bipolar cells, horizontal cells and amacrine cells. The physiological properties of these neurons determine how each type is affected by a particular light characteristic. Neuronal activity then triggers the release of signalling molecules that dilate local blood vessels and increase blood flow. Nitric oxide has been implicated as an important mediator, but metabolites of arachidonic acid may also be involved. Detailed elucidation of these mechanisms, together with advances in imaging technology, may facilitate the use of neurovascular tests to improve the detection of retinal damage in pathological conditions.

Entities: Chemical Disease

Keywords: arachidonic acid; ganglion cell; neurovascular coupling; nitric oxide; retina

Mesh：

Year: 2015 PMID： 25824961 DOI： 10.1111/ceo.12530

Source DB: PubMed Journal: Clin Exp Ophthalmol ISSN： 1442-6404 Impact factor: 4.207

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Cited

10 in total

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3. [Changes in three-dimensional arterial spin labeling perfusion imaging of the hippocampus in depressive Itpr₂^-/- mice].

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4. Higher glucose level and systemic oxidative stress decrease the mean velocity index of the retinal artery during flickering light stimulation in type 1 diabetes.

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5. Pulsed Electrical Stimulation of the Human Eye Enhances Retinal Vessel Reaction to Flickering Light.

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6. Macular perfusion analysed by optical coherence tomography angiography after uncomplicated phacoemulsification: benefits beyond restoring vision.

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7. Fenofibrate Nano-Eyedrops Ameliorate Retinal Blood Flow Dysregulation and Neurovascular Coupling in Type 2 Diabetic Mice.

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Journal: Pharmaceutics Date: 2022-02-09 Impact factor: 6.321