Stimulation-induced ectopicity and propagation windows in model damaged axons
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- 作者:Mathieu Lachance (1) (2)
André Longtin (2)
Catherine E. Morris (3)
Na Yu (2)
Béla Joós (2) - 关键词:Ectopicity onset ; Phase locking ; Neuropathic pain ; Coupled left ; shift (CLS) ; Nav1.6 acquired channelopathies
- 刊名:Journal of Computational Neuroscience
- 出版年:2014
- 出版时间:December 2014
- 年:2014
- 卷:37
- 期:3
- 页码:523-531
- 全文大小:1,021 KB
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16. Hao, J., Padilla, F., Dandonneau, M., Lavebratt, C., Lesage, F., No?l, J., & Delmas, P. (2013). Kv1. 1 channels Act as mechanical brake in the senses of touch and pain. / Neuron, 77(5), 899-14. André Longtin (2)
Catherine E. Morris (3)
Na Yu (2)
Béla Joós (2)
1. Département de physique, Cégep de l’Outaouais, 820 de la Gappe, Gatineau, Québec, J8T 7T7, Canada
2. Ottawa-Carleton Institute for Physics, University of Ottawa, 150 Louis Pasteur, Ottawa, ON, K1N 6N5, Canada
3. Neurosciences, Ottawa Hospital Research Institute, Ottawa, ON, K1H 8M5, Canada - ISSN:1573-6873
文摘
Neural tissue injuries render voltage-gated Na+ channels (Nav) leaky, thereby altering excitability, disrupting propagation and causing neuropathic pain related ectopic activity. In both recombinant systems and native excitable membranes, membrane damage causes the kinetically-coupled activation and inactivation processes of Nav channels to undergo hyperpolarizing shifts. This damage-intensity dependent change, called coupled left-shift (CLS), yields a persistent or “subthreshold-Nav window conductance. Nodes of Ranvier simulations involving various degrees of mild CLS showed that, as the system’s channel/pump fluxes attempt to re-establish ion homeostasis, the CLS elicits hyperexcitability, subthreshold oscillations and neuropathic type action potential (AP) bursts. CLS-induced intermittent propagation failure was studied in simulations of stimulated axons, but pump contributions were ignored, leaving open an important question: does mild-injury (small CLS values, pumps functioning well) render propagation-competent but still quiescent axons vulnerable to further impairments as the system attempts to cope with its normal excitatory inputs? We probe this incipient diffuse axonal injury scenario using a 10-node myelinated axon model. Fully restabilized nodes with mild damage can, we show, become ectopic signal generators (“ectopic nodes- because incoming APs stress Na+/K+ gradients, thereby altering spike thresholds. Comparable changes could contribute to acquired sodium channelopathies as diverse as epileptic phenomena and to the neuropathic amplification of normally benign sensory inputs. Input spike patterns, we found, propagate with good fidelity through an ectopically firing site only when their frequencies exceed the ectopic frequency. This “propagation window-is a robust phenomenon, occurring despite Gaussian noise, large jitter and the presence of several consecutive ectopic nodes.