Depth-resolved fiber photometry of amyloid plaque signals in freely behaving Alzheimer’s disease mice

Abstract:
Significance – Current preclinical evaluation of Alzheimer’s disease pathology in mouse models relies on post-mortem analyses, which hinders the development and optimization of therapeutic approaches. Although in vivo methods exist, monitoring amyloid plaque signals across multiple brain regions in freely behaving animals remains a significant challenge.
Aim – We aim to develop an optical approach to address this challenge.
Approach – We used flat and tapered optical fibers in an Alzheimer’s mouse model.
Results – We first confirmed that conventional flat fiber-based photometry can detect amyloid plaque signals across multiple brain regions under anesthesia after injecting a blood-brain-barrier-permeable tracer, Methoxy-X04. The depth profile of in vivo fluorescent signals is correlated with histological signals. A machine learning approach could distinguish between in vivo fluorescent signals of mice with and without amyloid plaques. Next, after validating the feasibility of depth-resolved fiber photometry ex vivo, we chronically implanted a tapered fiber to monitor amyloid plaque signals in freely behaving mice. After injecting Methoxy-X04, fluorescent signals increased in a depth-specific manner in Alzheimer’s mice, but not in their wild-type littermates.
Conclusions – Our approach expands the capabilities of fiber photometry to monitor molecular pathologies, such as amyloid plaques, even in a freely behaving condition.
Published:
September 2025
RAISE Affiliate:
Spoke 2
Name of the Journal:
Neurophotonics
Publication type:
Contribution in journal
DOI:
10.1117