[HTML][HTML] How astrocyte networks may contribute to cerebral metabolite clearance

M Asgari, D De Zélicourt, V Kurtcuoglu - Scientific reports, 2015 - nature.com
Scientific reports, 2015nature.com
The brain possesses an intricate network of interconnected fluid pathways that are vital to
the maintenance of its homeostasis. With diffusion being the main mode of solute transport
in cerebral tissue, it is not clear how bulk flow through these pathways is involved in the
removal of metabolites. In this computational study, we show that networks of astrocytes may
contribute to the passage of solutes between tissue and paravascular spaces (PVS) by
serving as low resistance pathways to bulk water flow. The astrocyte networks are …
Abstract
The brain possesses an intricate network of interconnected fluid pathways that are vital to the maintenance of its homeostasis. With diffusion being the main mode of solute transport in cerebral tissue, it is not clear how bulk flow through these pathways is involved in the removal of metabolites. In this computational study, we show that networks of astrocytes may contribute to the passage of solutes between tissue and paravascular spaces (PVS) by serving as low resistance pathways to bulk water flow. The astrocyte networks are connected through aquaporin-4 (AQP4) water channels with a parallel, extracellular route carrying metabolites. Inhibition of the intracellular route by deletion of AQP4 causes a reduction of bulk flow between tissue and PVS, leading to reduced metabolite clearance into the venous PVS or, as observed in animal studies, a reduction of tracer influx from arterial PVS into the brain tissue.
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