Glial Associated Impairment of the Glymphatic System in Experimental Neonatal Hydrocephalus

Abstract Background Changes in aquaporin-4 (AQP4) and glial fibrillary acid protein (GFAP) expression by astrocytes have been observed in several pathologies. It is hypothesized that prolonged exposure to pathologically elevated intracranial pressure (ICP) may be linked to impaired glymphatic pathways. In this study we explore histological consequences of prolonged pressure-induced injury in a feline model of neonatal hydrocephalus through changes in AQP4 and GFAP expression. We discuss the implications this may have in gaining a better understanding of the underlying mechanisms of hydrocephalus (HCP). Methods Using a neonatal feline model, obstructive HCP was induced through kaolin injection into the cisterna magna. Time between injection and intervention via ventricular reservoir placement was used to divide groups into early and late treatment groups. Early and late animals received reservoirs at 1- and 2-weeks post kaolin injection, respectively. Controls underwent sham operations (saline injection instead of kaolin). Animals were sacrificed at 4 months allowing for a chronic treated hydrocephalic model at time of brain harvest. Immunofluorescent staining for GFAP, AQP4 and DAPI was performed on histological brain sections from each group, and densitometry was used to quantify the relative signal of protein expression. Results Hydrocephalus was seen in all animals receiving kaolin injection as demonstrated by magnetic resonance imaging, clinical examination and neurological sequelae. Hydrocephalic animals demonstrated lower levels of perivascular AQP4 expression, increased diffuse AQP4 expression and increased glial scarring of perivascular, ependymal and subependymal spaces. Cerebral microvasculature of early treatment groups demonstrated increased astrocytic processes in the perivascular spaces, while late treatment groups demonstrated increased glial scar formation. Overall, the glymphatic system was severely disrupted in chronic treated hydrocephalus compared to controls. Conclusions Reactive astrogliosis and AQP4 mislocation are evident in early and late reservoir-treated HCP. Glial scarring in the perivascular, ependymal and subependymal spaces concurrent with AQP4 internalization from the perivascular region are prominent in HCP conditions present within the neonatal period. Delay in treatment by 1 week demonstrates quantifiable increases in perivascular and ependymal glial scarring at 4 months of age. Further investigation is needed to correlate glymphatic disruption with impaired CSF absorption and its role in promoting progressive hydrocephalus.