ABSTRACT
Devices capable of recording or stimulating neuronal signals have created new opportunities to understand normal physiology and treat sources of pathology in the brain. However, it is possible that the initial surgical insertion and subsequent tissue response to implanted electrodes may influence the nature of the signals detected or stimulated. In this study, we characterized structural and functional changes in pyramidal neurons surrounding silicon or polyimide-based electrodes implanted in the motor cortex of rats. Devices were captured in 300 μm-thick tissue slices collected at the 1 or 6 week time point post-implantation, and individual neurons were assessed using a combination of whole-cell electrophysiology and 2-photon imaging. We observed disruption of the dendritic arbor of neurons near (<100 μm) the device surface at both time points, as well as a significant reduction in spine densities. These effects were accompanied by a decrease in the frequency of spontaneous excitatory post-synaptic currents (sEPSCs), a loss in sag amplitude, and an increase in spike frequency adaptation at the 6 week time point. Interestingly, we also noted a significant increase in filopodial density in neurons surrounding devices. Results were similar for polyimide and silicon-based electrodes. We hypothesize that the effects observed in this study may contribute to the signal loss and instability that often accompany chronically implanted electrodes.
Competing Interest Statement
The authors have declared no competing interest.