PURPOSE: To analyze activity of identified dentate gyrus granular cells and interneurons during pathologic high-frequency oscillations (pHFOs). METHODS: Pilocarpine-treated epileptic mice were anesthetized with urethane and ketamine. Their heads were fixed in a stereotaxic frame. Extracellular unit activity was recoded with glass micropipettes, whereas multiunit and local field activity was simultaneously recorded with attached tungsten microelectrodes. After electrophysiologic experiments, recorded cells were labeled by neurobiotin and visualized by immunohistochemical methods. KEY FINDINGS AND SIGNIFICANCES: pHFOs containing more than three waves were recorded in our experiments, but pathologic single-population spikes also occurred. Identified granular cells discharged preferentially in synchrony with pHFOs and single population spikes, whereas interneurons decreased their discharge frequency during this time. These experiments provide additional confirmation that pHFOs in the dentate gyrus represent single or recurrent population spikes, which in turn reflect summated hypersynchronous discharges of principal cells. Wiley Periodicals, Inc.
PURPOSE: To analyze activity of identified dentate gyrus granular cells and interneurons during pathologic high-frequency oscillations (pHFOs). METHODS:Pilocarpine-treated epilepticmice were anesthetized with urethane and ketamine. Their heads were fixed in a stereotaxic frame. Extracellular unit activity was recoded with glass micropipettes, whereas multiunit and local field activity was simultaneously recorded with attached tungsten microelectrodes. After electrophysiologic experiments, recorded cells were labeled by neurobiotin and visualized by immunohistochemical methods. KEY FINDINGS AND SIGNIFICANCES: pHFOs containing more than three waves were recorded in our experiments, but pathologic single-population spikes also occurred. Identified granular cells discharged preferentially in synchrony with pHFOs and single population spikes, whereas interneurons decreased their discharge frequency during this time. These experiments provide additional confirmation that pHFOs in the dentate gyrus represent single or recurrent population spikes, which in turn reflect summated hypersynchronous discharges of principal cells. Wiley Periodicals, Inc.
Authors: Julia Jacobs; Pierre Levan; Claude-Edouard Châtillon; André Olivier; François Dubeau; Jean Gotman Journal: Brain Date: 2009-03-18 Impact factor: 13.501
Authors: Richard J Staba; Leonardo Frighetto; Eric J Behnke; Gary W Mathern; Tony Fields; Anatol Bragin; Jennifer Ogren; Itzhak Fried; Charles L Wilson; Jerome Engel Journal: Epilepsia Date: 2007-07-28 Impact factor: 5.864
Authors: Greg A Worrell; Andrew B Gardner; S Matt Stead; Sanqing Hu; Steve Goerss; Gregory J Cascino; Fredric B Meyer; Richard Marsh; Brian Litt Journal: Brain Date: 2008-02-07 Impact factor: 13.501