Blood-brain barrier permeable ß-blockers linked to lower risk of Alzheimer's disease in hypertension.

Alzheimer's disease is a neurodegenerative disorder in which the pathological accumulation of amyloid-ß and tau begins years before symptom onset. Emerging evidence suggests that ß-blockers (ß-adrenergic antagonists) increase brain clearance of these metabolites by enhancing CSF flow. Our objective was to determine whether ß-blocker treatments that easily cross the blood-brain barrier reduce the risk of Alzheimer's disease compared to less permeable ß-blockers. Data from the Danish national registers were used to identify a retrospective cohort of individuals with hypertension, and those treated with ß-blockers were included in the analysis. People with indications for ß-blocker use other than hypertension (e.g. heart failure) were only retained in a sensitivity analysis. ß-blockers were divided into three permeability groups: low, moderate and high. We used multivariable cause-specific Cox regression to model the effect of ß-blocker blood-brain barrier permeability on time to dementia outcomes, adjusting for baseline comorbidities, demographics and socioeconomic variables. Death was modelled as a competing risk. The 10-year standardized absolute risk was estimated as the averaged person-specific risks per treatment. In a cohort of 69 081 (median age = 64.4 years, 64.8% female) people treated with ß-blockers for hypertension, highly blood-brain barrier-permeable ß-blockers were associated with reduced risk of Alzheimer's disease versus low permeability ß-blockers (-0.45%, P < 0.036). This effect was specific to Alzheimer's diagnoses and did not extend to dementia in general. Propensity score analysis matching high and low blood-brain barrier-permeable patients also detected a decreased Alzheimer's risk (-0.92%, P < 0.001) in the high permeability group compared to the low, as did a 1-year landmark analysis (-0.57%, P < 0.029) in which events within the first year of follow-up were ignored as likely unrelated to treatment. Our results suggest that amongst people taking ß-blockers for hypertension, treatment with highly blood-brain barrier permeable ß-blockers reduces the risk of Alzheimer's disease compared to low permeability drugs. Our findings support the hypothesis that highly permeable ß-blockers protect against Alzheimer's disease by promoting waste brain metabolite clearance.

Haplotype of the astrocytic water channel AQP4 is associated with slow wave energy regulation in human NREM sleep.

Cerebrospinal fluid (CSF) flow through the brain parenchyma is facilitated by the astrocytic water channel aquaporin 4 (AQP4). Homeostatically regulated electroencephalographic (EEG) slow waves are a hallmark of deep non-rapid eye movement (NREM) sleep and have been implicated in the regulation of parenchymal CSF flow and brain clearance. The human AQP4 gene harbors several single nucleotide polymorphisms (SNPs) associated with AQP4 expression, brain-water homeostasis, and neurodegenerative diseases. To date, their role in sleep-wake regulation is unknown. To investigate whether functional variants in AQP4 modulate human sleep, nocturnal EEG recordings and cognitive performance were investigated in 123 healthy participants genotyped for a common eight-SNP AQP4-haplotype. We show that this AQP4-haplotype is associated with distinct modulations of NREM slow wave energy, strongest in early sleep and mirrored by changes in sleepiness and reaction times during extended wakefulness. The study provides the first human evidence for a link between AQP4, deep NREM sleep, and cognitive consequences of prolonged wakefulness.