Epilepsy, a condition of recurrent spontaneous seizures, affects 0.5-1% of the population, and remains an intractable condition in many cases. Additionally, the problem of anticipating incipient seizures, based on brain electrical signals, remains difficult. Very fast brain oscillations (VFOs) at >100 Hz are a locational marker of epileptogenic tissue;they can occur during interictal (""""""""between-seizure"""""""") potentials, and also can occur - as a harbinger - just prior to frank seizures. [Some authors, such as A. Bragin and J. Engel, Jr., distinguish """"""""ripples"""""""" at <~250 Hz from """"""""fast ripples"""""""" at >~250 Hz, but for the present, let us lump them together.] VFO, however, also occurs during normal brain events, such as physiological sharp-wave ripple (SPW-R) complexes, events that appear important in the consolidation of spatial memories: thus, VFO may be critical for normal cognitive processes. The similar appearance of pathological and physiological VFO events (although not fast ripples) suggests shared mechanisms. We are therefore faced with a dilemma: on the one hand, it is essential to distinguish the mechanisms underlying pathological vs. normal VFO, because suppressing pathological VFO might prevent seizures, while suppressing normal VFO might interfere with memory;but on the other hand, the likely sharing of mechanisms implies that this distinction may not be straightforward. VFO can occur experimentally in conditions when chemical synapses are blocked. A large body of evidence suggests that VFO originates from gap junctional coupling of pyramidal neurons, via axons. Models based on electrical coupling account for multiple features of VFO, including the frequency range, spatial properties (in epileptic neocortex), intracellular potentials and synaptic currents, pH sensitivity, and pharmacology. (Other models of VFO, based on chemical synapses and/or field effects have run afoul of experiments showing persistence of VFO with synapses blocked, and of the very small amplitudes of the extracellular potentials.) Other aspects of VFO are not understood: for example, the limited somatic firing during physiological sharp- wave ripples;or the ability of pathological tissue to generate either """"""""ripples"""""""" or """"""""fast ripples"""""""", one after the other, as apparently discrete, separable events. Nor is it known how, during a physiological SPW-R, VFO occurs superimposed upon summated synaptic potentials;while, prior to a seizure, VFO can occur by itself. This proposal seeks to investigate these and other aspects of VFO, using both highly detailed and also highly simplified network models;and using data from rodent experiments as well as human tissue recorded in situ and in vitro. The computational models will be predictive and motivate further experimental and eventually clinical investigations. A long-term goal is to use refined understanding of VFO mechanisms to be able to prevent or suppress pathological fast brain oscillations, with minimal perturbation of the normal ones.
This proposal addresses the roles of axons, and gap junctions, in generating very fast brain oscillations, which occur during memory-related brain processes, as well as prior to and during epileptic seizures. If successful, the work will suggest means to anticipate, and perhaps abort, incipient seizures, without detriment to normal cognition.
|Hunt, Mark J; Kopell, Nancy J; Traub, Roger D et al. (2017) Aberrant Network Activity in Schizophrenia. Trends Neurosci 40:371-382|
|Hall, S; Hunt, M; Simon, A et al. (2015) Unbalanced Peptidergic Inhibition in Superficial Neocortex Underlies Spike and Wave Seizure Activity. J Neurosci 35:9302-14|
|Cheron, G; Prigogine, C; Cheron, J et al. (2014) Emergence of a 600-Hz buzz UP state Purkinje cell firing in alert mice. Neuroscience 263:15-26|
|Simon, Anna; Traub, Roger D; Vladimirov, Nikita et al. (2014) Gap junction networks can generate both ripple-like and fast ripple-like oscillations. Eur J Neurosci 39:46-60|
|Traub, Roger D; Cunningham, Mark O; Whittington, Miles A (2014) What is a seizure network? Very fast oscillations at the interface between normal and epileptic brain. Adv Exp Med Biol 813:71-80|
|Carracedo, Lucy M; Kjeldsen, Henrik; Cunnington, Leonie et al. (2013) A neocortical delta rhythm facilitates reciprocal interlaminar interactions via nested theta rhythms. J Neurosci 33:10750-61|
|Vladimirov, Nikita; Tu, Yuhai; Traub, Roger D (2013) Synaptic gating at axonal branches, and sharp-wave ripples with replay: a simulation study. Eur J Neurosci 38:3435-47|
|Traub, Roger D; Schmitz, Dietmar; Maier, Nikolaus et al. (2012) Axonal properties determine somatic firing in a model of in vitro CA1 hippocampal sharp wave/ripples and persistent gamma oscillations. Eur J Neurosci 36:2650-60|
|Cunningham, Mark O; Roopun, Anita; Schofield, Ian S et al. (2012) Glissandi: transient fast electrocorticographic oscillations of steadily increasing frequency, explained by temporally increasing gap junction conductance. Epilepsia 53:1205-14|
|Vivar, Carmen; Traub, Roger D; Gutierrez, Rafael (2012) Mixed electrical-chemical transmission between hippocampal mossy fibers and pyramidal cells. Eur J Neurosci 35:76-82|
Showing the most recent 10 out of 24 publications