Abstract
AbstractEfficient metabolic waste clearance is essential for optimal brain function. Waste accumulation can cause inflammation, tissue damage, and potentially lead to dementia and other neurological disorders. The primary waste exit route is debated, with evidence suggesting the lymphatic system or arachnoid villi/granulations as possible pathways.This study uses an ultrastructural dataset to emphasize the potential underestimation of macrophages and arachnoid villi/granulations in waste removal.Based on brain surface ultrastructure analysis of the MICrONS dataset, waste clearance may occur through a transcellular route involving astrocytes to the perivascular space. Waste is then either phagocytosed by perivascular macrophages or directed to the subarachnoid space for meningeal macrophage phagocytosis.Evidence is provided that macrophages transport non-degradable waste in lysosomes to arachnoid villi for exocytosis into the villus lumen and venous system routing. Additionally, the study investigates fibroblast-macrophage interactions via primary cilia, potentially optimizing waste clearance. The role of astrocytes in brain water homeostasis and GFAP’s potential significance in water filtration are also examined. This study offers valuable insights into waste clearance mechanisms in the brain, potentially aiding dementia understanding and treatment.
Publisher
Cold Spring Harbor Laboratory