Early micro and nanoscopic responses of microglia to blood-brain barrier modulation by transcranial-focused ultrasound
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Modulation of the blood-brain barrier (BBB) using transcranial-focused ultrasound (FUS) has rapidly progressed to clinical trials. In combination with phospholipid microspheres, also known as microbubbles, administered in the bloodstream, ultrasound energy is guided by magnetic resonance imaging (MRI) to target specific brain regions with millimetric precision. At the targeted area, the interaction between FUS and microbubbles increases local BBB permeability for 4 to 6 hours, with an ensuing inflammation that resolves within days to weeks. Microglia, as the resident immune cells of the brain, are triggered by FUS-BBB modulation, although the time course of this response is unclear. Thus, the goal of this study was to characterize the early cellular (i.e., density, distribution, and morphology) and subcellular (i.e., ultrastructure) changes in microglial activities following FUS-BBB modulation.
Methods
We targeted the hippocampi of adult mice with FUS, in the presence of intravenous microbubbles and guided by MRI, and performed analyses 1 hour and 24 hours after FUS-BBB modulation. Microglia were investigated at the population, cellular and subcellular levels, where hippocampal BBB permeability was identified by the entry of endogenous immunoglobulin (Ig)G in the parenchyma. Respective outcome measures included i) the density and distribution of ionized calcium binding adaptor molecule-positive (Iba)1-positive (+) cells; ii) the morphology of the soma and processes of Iba1+ cells; and iii) the quantification of microglial organelles (e.g., phagosomes) and contacts with blood vessels and synapses using chip mapping scanning electron microscopy.
Results
No significant changes in baseline density and distribution of microglia were found in IgG-positive hippocampal areas at 1 hour and 24 hours after FUS-BBB modulation. By contrast, FUS-BBB modulation was associated with more elongated microglial cell bodies at both time points. The relative distribution of morphologies at 1 hour shifted toward compact shapes with stubby processes, whereas at 24 hours, shapes were bigger, with fewer processes. At the nanoscale, microglia maintained their interactions with blood vessel elements, except vessels most affected by swollen endfeet, which occurred regardless of treatment. In the parenchyma, 24 hours after FUS-BBB modulation, microglia reduced the frequency of contacts with pre-synaptic elements and extracellular space pockets, while showing features of increased metabolic demand and reduced lysosomal activity.
Conclusion
At 1 hour and 24 hours after FUS-BBB modulation, traits of microglial surveillance activity were largely maintained, with shifts in the shape of a subset of cells, which adopted a morphology associated with injury shielding. FUS-BBB modulation also appears to temporarily modify the digestive, but not the phagocytic activity, of microglia and to reduce pre-synaptic remodeling early after treatment.
