Cerebral Vessels: An Overview of Anatomy, Physiology, and Role in the Drainage of Fluids and Solutes

Cerebral Vessels: An Overview of Anatomy, Physiology, and Role in the Drainage of Fluids and Solutes

The cerebral vasculature is made up of highly specialized structures that assure constant brain perfusion necessary to meet the very high demand for oxygen and glucose by neurons and glial cells. A dense, redundant network of arteries is spread over the entire pial surface from which penetrating art...

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Bibliographic Details
Published in:Frontiers in neurology Vol. 11; p. 611485
Main Authors: Agarwal, Nivedita, Carare, Roxana Octavia
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 13-01-2021
Subjects:
cerebral vessel
glymphatic
intramural periarterial drainage
neurodegeneration
Neurology
perivascular space
small vessel disease
perivascular space
glymphatic
neurodegeneration
small vessel disease
intramural periarterial drainage
cerebral vessel
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Summary:The cerebral vasculature is made up of highly specialized structures that assure constant brain perfusion necessary to meet the very high demand for oxygen and glucose by neurons and glial cells. A dense, redundant network of arteries is spread over the entire pial surface from which penetrating arteries dive into the cortex to reach the neurovascular units. Besides providing blood to the brain parenchyma, cerebral arteries are key in the drainage of interstitial fluid (ISF) and solutes such as amyloid-beta. This occurs along the basement membranes surrounding vascular smooth muscle cells, toward leptomeningeal arteries and deep cervical lymph nodes. The dense microvasculature is made up of fine capillaries. Capillary walls contain pericytes that have contractile properties and are lined by a highly specialized blood-brain barrier that regulates the entry of solutes and ions and maintains the integrity of the composition of ISF. They are also important for the production of ISF. Capillaries drain into venules that course centrifugally toward the cortex to reach cortical veins and empty into dural venous sinuses. The walls of the venous sinuses are also home to meningeal lymphatic vessels that support the drainage of cerebrospinal fluid, although such pathways are still poorly understood. Damage to macro- and microvasculature will compromise cerebral perfusion, hamper the highly synchronized movement of neurofluids, and affect the drainage of waste products leading to neuronal and glial degeneration. This review will present vascular anatomy, their role in fluid dynamics, and a summary of how their dysfunction can lead to neurodegeneration.
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Edited by: Yulin Ge, New York University, United States
Reviewed by: Mariel Kozberg, Massachusetts General Hospital and Harvard Medical School, United States; Maxime Gauberti, INSERM U1237 Physiopathologie et imagerie des troubles Neurologiques (PhIND), France
This article was submitted to Stroke, a section of the journal Frontiers in Neurology
ISSN:1664-2295
1664-2295
DOI:10.3389/fneur.2020.611485