Chronic traumatic encephalopathy (CTE) is a neurodegenerative disease associated with repeated traumatic brain injury (TBI). CTE is a tauopathy, in which cognitive decline is accompanied by the accumulation of neurofibrillary tangles of the protein tau in patients’ brains. We recently found that mechanical force alone can induce tau mislocalization to dendritic spines and loss of synaptic function in in vitro neuronal cultures with random cell organization. However, in the brain, neurons are highly aligned, so here we aimed to determine how neuronal organization influences early-stage tauopathy caused by mechanical injury. Using microfabricated cell culture constructs to control the growth of neurites and an in vitro simulated-TBI device to apply controlled mechanical deformation, we found that neuronal orientation with respect to the direction of a uniaxial high-strain rate stretch injury influences the degree of tau pathology in injured neurons. We found that a mechanical stretch applied parallel to the neurite alignment induces greater mislocalization of tau proteins to dendritic spines than does a stretch with the same strain applied perpendicular to the neurites. Synaptic function, characterized by the amplitude of miniature excitatory post-synaptic currents, was similarly decreased in neurons with neurites aligned parallel to stretch, while in neurons aligned perpendicular to stretch had little to no functional loss. Experimental injury parameters (strain, strain rate, direction of stretch) were combined with a standard viscoelastic solid model to show that, in our in vitro model, neurite work density during stretch correlates with tau mislocalization. These findings suggest that, in a TBI, the magnitude of brain deformation is not wholly predictive of neurodegenerative consequences of TBI, but that deformation relative to local neuronal architecture and the neurite mechanical energy during injury are better metrics for predicting trauma-induced tauopathy.
Copyright © 2021. Published by Elsevier Inc.

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