AbstractBackgroundAPPswe/PS1dE9 mice reproduce features of amyloid β (Aβ) pathology and neuronal dysfunction as reflected in electrophysiological recordings of neuronal hyperexcitability. This leads to changes in sleep‐wake‐rhythm, downstream affecting brain clearance functionality. Our objective is to investigate the effect of circadian rhythm and Aβ pathology on clearance efficacy in APPswe/PS1dE9 mice.MethodFirst, we examined the brain wide distribution of an intrahippocampal injected fluorescent dye. Dye was injected at 6 am (post wake period) or 6 pm (post sleep period) and sampled 1 or 3 h post injection for histological analysis (Figure 1A) in n = 3 transgenic mice and n = 3 non‐transgenic mice per group. Secondly, in an in vivo approach we analyzed the brain wide distribution of a gadolinium based contrast agent using a T2‐RARE sequence in a 7 Tesla small animal MRI scanner (Bruker BioSpin GmbH, Germany) (Figure 1B) in n = 4 transgenic mice and n = 4 non‐transgenic mice. We measured values for brightness in manually defined regions of interest with PMOD software (version 3.7; PMOD Technologies LLC, Switzerland).ResultIn the first experiment, we were able to observe dye distribution in the brain parenchyma as surrogate for interstitial clearance net flux. Preliminary results point to an effect of circadian rhythm, as a trend of better dye distribution shortly after the sleep period was observed. Furthermore, a possible detrimental effect of the Aβ phenotype on clearance was observed in transgenic mice. In comparison to non‐transgenic mice they showed a trend of lesser dye distribution independent of day‐time. With the second approach, we were able to observe influx and efflux of applied contrast agent into cerebrospinal fluid. Preliminary data point to a trend of an increased slope of the influx as well as decreased slope of the efflux in transgenic mice.ConclusionHistological analysis of a stereotactic injected dye is a feasible method for investigation of dye distribution outlining a possible effect of daytime and amyloid pathology. However, MR‐imaging is a promising tool as we will be able to observe the disease progression in mice longitudinally. Further experiments will be needed to ensure these preliminary results and maybe also point to underlying mechanistic basis.
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