Electric fields influence the propagation of electrical activity in primary neurons and in neuron-like cells

Coupling between excitable systems is well known, and recent work has focused on excitability in neural & cardiovascular systems through recording microelectrodes. Building on this, we use noninvasive voltage indicators to probe the electrical dynamics of in vitro primary rat cortical neurons & a human embryonic kidney (HEK-293) cell line that has been engineered to be electrically excitable through expression of sodium (Na+) & potassium (K+) channels (NK-HEKs). To accomplish this, we 1) apply direct current (DC) or alternating current (AC) stimulation to cells, 2) image changes in transmembrane potential using fast acting voltage sensitive dyes, & 3) quantify signal propagation. We observe that NK-HEKs respond to both DC & AC stimulation, though the response to DC fields is more rapid. Neurons can also be electrically activated by DC fields, but the response depends on cell (and synapse) maturity. While the NK-HEKs “action potentials” are slower than those of neurons, NK-HEKs are tightly coupled, allowing for fast spiral waves &/or propagation of waves. In future work, we hope to use what we have learned about electrical dynamics & coupling in these cell types to make inferences about other excitable systems.