TY - JOUR T1 - Ionic Mechanisms Underlying Repetitive High-Frequency Burst Firing in Supragranular Cortical Neurons JF - The Journal of Neuroscience JO - J. Neurosci. SP - 4829 LP - 4843 DO - 10.1523/JNEUROSCI.20-13-04829.2000 VL - 20 IS - 13 AU - Joshua C. Brumberg AU - Lionel G. Nowak AU - David A. McCormick Y1 - 2000/07/01 UR - http://www.jneurosci.org/content/20/13/4829.abstract N2 - Neocortical neurons in awake, behaving animals can generate high-frequency (>300 Hz) bursts of action potentials, either in single bursts or in a repetitive manner. Intracellular recordings of layer II/III pyramidal neurons were obtained from adult ferret visual cortical slices maintained in vitro to investigate the ionic mechanisms by which a subgroup of these cells generates repetitive, high-frequency burst discharges, a pattern referred to as “chattering.” The generation of each but the first action potential in a burst was dependent on the critical interplay between the afterhyperpolarizations (AHPs) and afterdepolarizations (ADPs) that followed each action potential. The spike-afterdepolarization and the generation of action potential bursts were dependent on Na+, but not Ca2+, currents. Neither blocking of the transmembrane flow of Ca2+nor the intracellular chelation of free Ca2+ with BAPTA inhibited the generation of intrinsic bursts. In contrast, decreasing the extracellular Na+ concentration or pharmacologically blocking Na+ currents with tetrodotoxin, QX-314, or phenytoin inhibited bursting before inhibiting action potential generation. Additionally, a subset of layer II/III pyramidal neurons could be induced to switch from repetitive single spiking to a burst-firing mode by constant depolarizing current injection, by raising extracellular K+concentrations, or by potentiation of the persistent Na+ current with the Na+ channel toxin ATX II. These results indicate that cortical neurons may dynamically regulate their pattern of action potential generation through control of Na+ and K+currents. The generation of high-frequency burst discharges may strongly influence the response of postsynaptic neurons and the operation of local cortical networks. ER -