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Journal of Computational Neuroscience

Erschienen in:

01.06.2010

Mechanisms of very fast oscillations in networks of axons coupled by gap junctions

verfasst von: Erin Munro, Christoph Börgers

Erschienen in: Journal of Computational Neuroscience | Ausgabe 3/2010

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Abstract

Because electrical coupling among the neurons of the brain is much faster than chemical synaptic coupling, it is natural to hypothesize that gap junctions may play a crucial role in mechanisms underlying very fast oscillations (VFOs), i.e., oscillations at more than 80 Hz. There is now a substantial body of experimental and modeling literature supporting this hypothesis. A series of modeling papers, starting with work by Roger Traub and collaborators, have suggested that VFOs may arise from expanding waves propagating through an “axonal plexus”, a large random network of electrically coupled axons. Traub et al. also proposed a cellular automaton (CA) model to study the mechanisms of VFOs in the axonal plexus. In this model, the expanding waves take the appearance of topologically circular “target patterns”. Random external stimuli initiate each wave. We therefore call this kind of VFO “externally driven”. Using a computational model, we show that an axonal plexus can also exhibit a second, distinctly different kind of VFO in a wide parameter range. These VFOs arise from activity propagating around cycles in the network. Once triggered, they persist without any source of excitation. With idealized, regular connectivity, they take the appearance of spiral waves. We call these VFOs “re-entrant”. The behavior of the axonal plexus depends on the reliability with which action potentials propagate from one axon to the next, which, in turn, depends on the somatic membrane potential V _s and the gap junction conductance g _gj. To study these dependencies, we impose a fixed value of V _s, then study the effects of varying V _s and g _gj. Not surprisingly, propagation becomes more reliable with rising V _s and g _gj. Externally driven VFOs occur when V _s and g _gj are so high that propagation never fails. For lower V _s or g _gj, propagation is nearly reliable, but fails in rare circumstances. Surprisingly, the parameter regime where this occurs is fairly large. Even a single propagation failure can trigger re-entrant VFOs in this regime. Lowering V _s and g _gj further, one finds a third parameter regime in which propagation is unreliable, and no VFOs arise. We analyze these three parameter regimes by means of computations using model networks adapted from Traub et al., as well as much smaller model networks.

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http://senselab.med.yale.edu/modeldb/, accession number 120907.

Re-entrant VFO frequencies refer to the last 25 ms of the simulation, in order to get a pure re-entrant oscillation with no transitory externally driven waves.

Bragin, A., Engel, J., Jr., Wilson, C. L., Fried, I., & Mathern, G. W. (1999). Hippocampal and entorhinal cortex high-frequency oscillations (100–500 Hz) in human epileptic brain and in kainic acid-treated rats with chronic seizures. Epilepsia, 40(2), 127–137.CrossRefPubMed

Bragin, A., Mody, I., Wilson, C. L., & Engel, J., Jr. (2002). Local generation of fast ripples in epileptic brain. Journal of Neuroscience, 22(5), 2012–2021.PubMed

Bragin, A., Wilson, C. L., Almajano, J., Mody, I., & Engel, J., Jr. (2004). High-frequency oscillations after status epilepticus: Epileptogenesis and seizure genesis. Epilepsia, 45(9), 1017–1023.CrossRefPubMed

Clemens, Z., Mölle, M., Eross, L., Barsi, P., Halász, P., & Born, J. (2007). Temporal coupling of parahippocampal ripples, sleep spindles and slow oscillations in humans. Brain, 130(Pt. 11), 2868–2878.CrossRefPubMed

de Solages, C., Szapiro, G., Brunel, N., Hakim, V., Isope, P., Buisseret, P., et al. (2008). High-frequency organization and synchrony of activity in the Purkinje cell layer of the cerebellum. Neuron, 58(5), 775–788.CrossRefPubMed

Draguhn, A., Traub, R. D., Schmitz, D., & Jefferys, J. G. (1998). Electrical coupling underlies high-frequency oscillations in the hippocampus in vitro. Nature, 394(6689), 189–192.CrossRefPubMed

Engel, J., Jr., Bragin, A., Staba, R., & Mody, I. (2009). High-frequency oscillations: What is normal and what is not? Epilepsia, 50(4), 598–604.CrossRefPubMed

Erdös, P., & Rényi, A. (1960). On the evolution of random graphs. Publications of the Mathematical Institute of the Hungarian Academy of Sciences, 5, 17–61.

Fisher, R. S., Webber, W. R., Lesser, R. P., Arroyo, S., & Uematsu, S. (1992). High-frequency EEG activity at the start of seizures. Journal of Clinical Neurophysiology, 9(3), 441–448.CrossRefPubMed

Gansert, J., Golowasch, J., & Nadim, F. (2007). Sustained rhythmic activity in gap-junctionally coupled networks of model neurons on depends on the diameter of coupled dendrites. Journal of Neurophysiology, 98(6), 3450–3460.CrossRefPubMed

Garrey, W. E. (1924). Auricular fibrillation. Physiological Reviews, 4(2), 215–250.

Greenberg, J. M., & Hastings, S. P. (1978). Spatial patterns for discrete models of diffusion in excitable media. SIAM Journal on Applied Mathematics, 34, 515–523.CrossRef

Grenier, F., Timofeev, I., & Steriade, M. (2001). Focal synchronization of ripples (80–200 Hz) in neocortex and their neuronal correlates. Journal of Neurophysiology, 86(4), 1884–1898.PubMed

Grenier, F., Timofeev, I., & Steriade, M. (2003). Neocortical very fast oscillations (ripples, 80–200 Hz) during seizures: Intracellular correlates. Journal of Neurophysiology, 89(2), 841–852.CrossRefPubMed

Hamzei-Sichani, F., Kamasawa, N., Janssen, W. G., Yasumura, T., Davidson, K. G., Hof, P. R., et al. (2007). Gap junctions on hippocampal mossy fiber axons demonstrated by thin-section electron microscopy and freeze-fracture replica immunogold labeling. Proceedings of the National Academy of Sciences of the United States of America, 104(30), 12548–12553.CrossRefPubMed

Jacobs, J., LeVan, P., Chander, R., Hall, J., Dubeau, F., & Gotman, J. (2008). Interictal high-frequency oscillations (80–500 Hz) are an indicator of seizure onset areas independent of spikes in the human epileptic brain. Epilepsia, 49(11), 1893–1907.CrossRefPubMed

Kandel, A., & Buzsáki, G. (1997). Cellular-synaptic generation of sleep spindles, spike-and-wave discharges, and evoked thalamocortical responses in the neocortex of the rat. Journal of Neuroscience, 17(17), 6783–6797.PubMed

Le Van Quyen, M., Bragin, A., Staba, R., Crépon, B., Wilson, C. L., & Engel, J., Jr. (2008). Cell type-specific firing during ripple oscillations in the hippocampal formation of humans. Journal of Neuroscience, 28(24), 6104–6110.CrossRef

Lewis, T. J., & Rinzel, J. (2000). Self-organized synchronous oscillations in a network of excitable cells coupled by gap junctions. Network, 11(4), 299–320.CrossRefPubMed

Lewis, T. J., & Rinzel, J. (2001). Topological target patterns and population oscillations in a network with random gap junctional coupling. Neurocomputers, 38–40, 763–768.CrossRef

Maex, R., & De Schutter, E. (2007). Mechanism of spontaneous and self-sustained oscillations in networks connected through axo-axonal gap junctions. European Journal of Neuroscience, 25(11), 3347–3358.CrossRefPubMed

Maier, N., Nimmrich, V., & Draguhn, A. (2003). Cellular and network mechanisms underlying spontaneous sharp wave-ripple complexes in mouse hippocampal slices. Journal of Physiology, 550(Pt. 3), 873–887.CrossRefPubMed

Middleton, S. J., Racca, C., Cunningham, M. O., Traub, R. D., Monyer, H., Knöpfel, T., et al. (2008). High-frequency network oscillations in cerebellar cortex. Neuron, 58(5), 763-774.CrossRefPubMed

Moe, G. K., Rheinboldt, W. C., & Abildskov, J. A. (1964). A computer model of atrial fibrillation. American Heart Journal, 67, 200–220.CrossRefPubMed

Munro, E. C. (2008). The axonal plexus: A description of the behavior of a network of axons connected by gap junctions. Ph.D. thesis, Tufts University.

Muratov, C. B., Vanden-Eijnden, E., & Weinan, E. (2007). Noise can play an organizing role for the recurrent dynamics in excitable media. Proceedings of the National Academy of Sciences of the United States of America, 104(3), 702–707.CrossRefPubMed

Nimmrich, V., Maier, N., Schmitz, D., & Draguhn, A. (2005). Induced sharp wave-ripple complexes in the absence of synaptic inhibition in mouse hippocampal slices. Journal of Physiology, 563(Pt. 3), 663–670.CrossRefPubMed

Ponomarenko, A. A., Korotkova, T. M., Sergeeva, O. A., & Haas, H. L. (2004). Multiple GABA_A receptor subtypes regulate hippocampal ripple oscillations. European Journal of Neuroscience, 20(8), 2141–2148.CrossRefPubMed

Roopun, A. K., Simonotto, J. D., Pierce, M. L., Jenkins, A., Nicholson, C., Schofield, I. S., et al. (2010). A nonsynaptic mechanism underlying interictal discharges in human epileptic neocortex. Proceedings of the National Academy of Sciences of the United States of America, 107(1), 338–343.CrossRefPubMed

Schmitz, D., Schuchmann, S., Fisahn, A., Draguhn, A., Buhl, E. H., Petrasch-Parwez, E., et al. (2001). Axo-axonal coupling: A novel mechanism for ultrafast neuronal communication. Neuron, 31(5), 831–840.CrossRefPubMed

Staba, R. J., Wilson, C. L., Bragin, A., Jhung, D., Fried, I., & Engel, J., Jr. (2004). High-frequency oscillations recorded in human medial temporal lobe during sleep. Annals of Neurology, 56(1), 108–115.CrossRefPubMed

Traub, R. D., Schmitz, D., Jefferys, J. G., & Draguhn, A. (1999). High-frequency population oscillations are predicted to occur in hippocampal pyramidal neural networks interconnected by axo-axonal gap junctions. Neuroscience, 92(2), 407–426.CrossRefPubMed

Traub, R. D., Bibbig, A., Fisahn, A., LeBeau, F. E., Whittington, M. A., & Buhl, E. H. (2000). A model of gamma-frequency network oscillations induced in the rat CA3 region by carbachol in vitro. European Journal of Neuroscience, 12(11), 4093–4106.CrossRefPubMed

Traub, R. D., & Bibbig, A. (2000). A model of high-frequency ripples in the hippocampus based on synaptic coupling plus axon–axon gap junctions between pyramidal neurons. Journal of Neuroscience, 20(6), 2086–2093.PubMed

Traub, R. D., Whittington, M. A., Buhl, E. H., LeBeau, F. E., Bibbig, A., Boyd, S., et al. (2001). A possible role for gap junctions in generation of very fast EEG oscillations preceding the onset of, and perhaps initiating, seizures. Epilepsia, 42(2), 153–170.CrossRefPubMed

Traub, R. D. (2003). Fast oscillations and epilepsy. Epilepsy Currents, 3(3), 77–79.CrossRefPubMed

Traub, R. D., Cunningham, M. O., Gloveli, T., LeBeau, F. E., Bibbig, A., Buhl, E. H., et al. (2003a). GABA-enhanced collective behavior in neuronal axons underlies persistent gamma frequency oscillations. Proceedings of the National Academy of Sciences of the United States of America, 100(19), 11047–11052.CrossRefPubMed

Traub, R. D., Pais, I., Bibbig, A., LeBeau, F. E., Buhl, E. H., Hormuzdi, S. G., et al. (2003b). Contrasting roles of axonal (pyramidal cell) and dendritic (interneuron) electrical coupling in the generation of neuronal network oscillations. Proceedings of the National Academy of Sciences of the United States of America, 100(3), 1370–1374.CrossRefPubMed

Traub, R. D., Contreras, D., & Whittington, M. A. (2005). Combined experimental/simulation studies of cellular and network mechanisms of epileptogenesis in vitro and in vivo. Journal of Clinical Neurophysiology, 22(5), 330–342.PubMed

Traub, R. D., Middleton, S. J., Knöpfel, T., & Whittington, M. A. (2008). Model of very fast (> 75 Hz) network oscillations generated by electrical coupling between the proximal axons of cerebellar Purkinje cells. European Journal of Neuroscience, 28(8), 1603–1661.CrossRefPubMed

Traub, R. D., Duncan, R., Russell, A. J., Baldeweg, T., Tu, Y., Cunningham, M. O., et al. (2009). Spatiotemporal patterns of electrocorticographic very fast oscillations (>80 Hz) consistent with a network model based on electrical coupling between principal neurons. Epilepsia, published online December 2009.

Tseng, S. H., Tsai, L. Y., & Yeh, R. R. (2008). Induction of high-frequency oscillations in a junction-coupled network. Journal of Neuroscience, 28(28), 7165–7173.CrossRefPubMed

Urrestarazu, E., Chander, R., Dubeau, F., & Gotman, J. (2008). Interictal high-frequency oscillations (100–500 Hz) in the intracerebral EEG of epileptic patients. Brain, 130(Pt. 9), 2354–2366.

Veenhuyzen, G. D., Simpson, C. S., & Abdollah, H. (2004). Atrial fibrillation. CMAJ, 171(7), 755–760.PubMed

Worrell, G. A., Parish, L., Cranstoun, S. D., Jonas, R., Baltuch, G., & Litt, B. (2004). High-frequency oscillations and seizure generation in neocortical epilepsy. Brain, 127(Pt. 7), 1496–1506.CrossRefPubMed

Ylinen, A., Bragin, A., Nádasdy, Z., Jandó, G., Szabó, I., Sik, A., et al. (1995). Sharp wave-associated high-frequency oscillation (200 Hz) in the intact hippocampus: Network and intracellular mechanisms. Journal of Neuroscience, 15(1 Pt. 1), 30–46.PubMed

Titel: Mechanisms of very fast oscillations in networks of axons coupled by gap junctions
verfasst von: Erin Munro
Christoph Börgers
Publikationsdatum: 01.06.2010
Verlag: Springer US
Erschienen in: Journal of Computational Neuroscience / Ausgabe 3/2010
Print ISSN: 0929-5313
Elektronische ISSN: 1573-6873
DOI: https://doi.org/10.1007/s10827-010-0235-6

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