Regulation of blood flow in diabetic retinopathy

Amy R. Nippert; Eric A. Newman

doi:10.1017/S0952523820000036

Regulation of blood flow in diabetic retinopathy

Amy R. Nippert, Eric A. Newman

Neuroscience

Research output: Contribution to journal › Review article › peer-review

18 Scopus citations

Abstract

Blood flow in the retina increases in response to light-evoked neuronal activity, ensuring that retinal neurons receive an adequate supply of oxygen and nutrients as metabolic demands vary. This response, termed "functional hyperemia,"is disrupted in diabetic retinopathy. The reduction in functional hyperemia may result in retinal hypoxia and contribute to the development of retinopathy. This review will discuss the neurovascular coupling signaling mechanisms that generate the functional hyperemia response in the retina, the changes to neurovascular coupling that occur in diabetic retinopathy, possible treatments for restoring functional hyperemia and retinal oxygen levels, and changes to functional hyperemia that occur in the diabetic brain.

Original language	English (US)
Article number	E004
Journal	Visual Neuroscience
DOIs	https://doi.org/10.1017/S0952523820000036
State	Accepted/In press - 2020

Bibliographical note

Publisher Copyright:
© 2020 The Author(s). Published by Cambridge University Press.

Keywords

Diabetic retinopathy
Müller cells
blood flow
hypoxia
neurovascular coupling
neurovascular unit

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title = "Regulation of blood flow in diabetic retinopathy",

abstract = "Blood flow in the retina increases in response to light-evoked neuronal activity, ensuring that retinal neurons receive an adequate supply of oxygen and nutrients as metabolic demands vary. This response, termed {"}functional hyperemia,{"}is disrupted in diabetic retinopathy. The reduction in functional hyperemia may result in retinal hypoxia and contribute to the development of retinopathy. This review will discuss the neurovascular coupling signaling mechanisms that generate the functional hyperemia response in the retina, the changes to neurovascular coupling that occur in diabetic retinopathy, possible treatments for restoring functional hyperemia and retinal oxygen levels, and changes to functional hyperemia that occur in the diabetic brain.",

keywords = "Diabetic retinopathy, M{\"u}ller cells, blood flow, hypoxia, neurovascular coupling, neurovascular unit",

author = "Nippert, {Amy R.} and Newman, {Eric A.}",

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journal = "Visual Neuroscience",

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AU - Nippert, Amy R.

AU - Newman, Eric A.

PY - 2020

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AB - Blood flow in the retina increases in response to light-evoked neuronal activity, ensuring that retinal neurons receive an adequate supply of oxygen and nutrients as metabolic demands vary. This response, termed "functional hyperemia,"is disrupted in diabetic retinopathy. The reduction in functional hyperemia may result in retinal hypoxia and contribute to the development of retinopathy. This review will discuss the neurovascular coupling signaling mechanisms that generate the functional hyperemia response in the retina, the changes to neurovascular coupling that occur in diabetic retinopathy, possible treatments for restoring functional hyperemia and retinal oxygen levels, and changes to functional hyperemia that occur in the diabetic brain.

KW - Diabetic retinopathy

KW - Müller cells

KW - blood flow

KW - hypoxia

KW - neurovascular coupling

KW - neurovascular unit

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JO - Visual Neuroscience

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ER -

Regulation of blood flow in diabetic retinopathy

Abstract

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Keywords

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