Device for detection of activity-dependent changes in neural spheroids at MHz and GHz frequencies

TL;DR

This study introduces a novel device that uses electromagnetic waves in the MHz-GHz range to detect activity-dependent intracellular changes in neural spheroids, offering a label-free method to monitor neuronal activity.

Contribution

The paper presents the first device capable of detecting activity-dependent intracellular changes in neural tissue using broadband EM wave transmission in the MHz-GHz range.

Findings

Neuronal activity reversibly alters EM wave transmission.

Pharmacological suppression of activity abolishes transmission changes.

Time constants of transmission changes are in seconds to tens of seconds.

Abstract

Intracellular processes triggered by neural activity include changes in ionic concentrations, protein release, and synaptic vesicle cycling. These processes play significant roles in neurological disorders. The beneficial effects of brain stimulation may also be mediated through intracellular changes. There is a lack of label-free techniques for monitoring activity-dependent intracellular changes. Electromagnetic (EM) waves at frequencies larger than 1x10^6 Hz (1 MHz) were previously used to probe intracellular contents of cells, as cell membrane becomes transparent at this frequency range. EM waves interact with membranes of intracellular organelles, proteins, and water in the MHz-GHz range. In this work, we developed a device for probing the interaction between intracellular contents of active neurons and EM waves. The device used an array of grounded coplanar waveguides (GCPWs) to deliver EM waves to a three-dimensional (3D) spheroid of rat cortical neurons. Neural activity was evoked using optogenetics, with synchronous detection of propagation of EM waves. Broadband measurements were conducted in the MHz-GHz range to track changes in transmission coefficients. Neuronal activity was found to reversibly alter EM wave transmission. Pharmacological suppression of neuronal activity abolished changes in transmission. Time constants of changes in transmission were in the range of seconds to tens of seconds, suggesting the presence of relatively slow, activity-dependent intracellular processes. This study provides the first evidence that EM transmission through neuronal tissue is activity-dependent in MHz-GHz range. Device developed in this work may find future applications in studies of the mechanisms of neurological disorders and the development of new therapies.