Blechschmidt S, Haufe V, Benndorf K, Zimmer T (2008) Voltagegated Na+ channel transcript patterns in the mammalian heart are species-dependent. Prog Biophys Mol Biol98: 309-318

Caldwell JH, Schaller KL, Lasher RS, Peles E, Levinson SR (2000) Sodium channel Na(v)1.6 is localized at nodes of Ranvier, dendrites, and synapses. Proc Natl Acad Sci USA97: 5616-5620

Chahine M, O’Leary ME (2014) Regulation/modulation of sensory neuron sodium channels. Handb Exp Pharmacol221: 111-135

Chatelier A, Dahllund L, Eriksson A, Krupp J, Chahine M (2008) Biophysical properties of human Na v1.7 splice variants and their regulation by protein kinase A. J Neurophysiol99: 2241-2250

Dib-Hajj SD, Yang Y, Black JA, Waxman SG (2013) The Na(V)1.7 sodium channel: from molecule to man. Nat Rev Neurosci14: 49-62

Eckrich T, Varakina K, Johnson SL, Franz C, Singer W, Kuhn S, Knipper M, Holley MC, Marcotti W (2012) Development and function of the voltage-gated sodium current in immature mammalian cochlear inner hair cells. PLoS One7: e45732

Goldin AL, Barchi RL, Caldwell JH, Hofmann F, Howe JR, Hunter JC, Kallen RG, Mandel G, Meisler MH, Netter YB (2000) Nomenclature of voltage-gated sodium channels. Neuron28: 365-368

Hains BC, Klein JP, Saab CY, Craner MJ, Black JA, Waxman SG (2003) Upregulation of sodium channel Nav1.3 and functional involvement in neuronal hyperexcitability associated with central neuropathic pain after spinal cord injury. J Neurosci23: 8881-8892

Housley GD, Marcotti W, Navaratnam D, Yamoah EN (2006) Hair cells–beyond the transducer. J Membr Biol209: 89-118

Jarecki BW, Sheets PL, Xiao YC, Jackson JO, Cummins TR (2009) Alternative splicing of Na(V)1.7 exon 5 increases the impact of the painful PEPD mutant channel I1461T. Channels3: 259-267

Marcotti W, Johnson SL, Rusch A, Kros CJ (2003) Sodium and calcium currents shape action potentials in immature mouse inner hair cells. J Physiol552: 743-761

Plummer NW, McBurney MW, Meisler MH (1997) Alternative splicing of the sodium channel SCN8A predicts a truncated two-domain protein in fetal brain and non-neuronal cells. J Biol Chem272: 24008-24015

Schroeter A, Walzik S, Blechschmidt S, Haufe V, Benndorf K, Zimmer T (2010) Structure and function of splice variants of the cardiac voltage-gated sodium channel Na(v)1.5. J Mol Cell Cardiol49: 16-24

Thimmapaya R, Neelands T, Niforatos W, Davis-Taber RA, Choi W, Putman CB, Kroeger PE, Packer J, Gopalakrishnan M, Faltynek CR (2005) Distribution and functional characterization of human Nav1.3 splice variants. Eur J Neurosci22: 1-9

Xu R, Thomas EA, Jenkins M, Gazina EV, Chiu C, Heron SE, Mulley JC, Scheffer IE, Berkovic SF, Petrou S (2007) A childhood epilepsy mutation reveals a role for developmentally regulated splicing of a sodium channel. Mol Cell Neurosci35: 292-301

Zubovic L, Baralle M, Baralle FE (2012a) Mutually exclusive splicing regulates the Na-v 1.6 sodium channel function through a combinatorial mechanism that involves three distinct splicing regulatory elements and their ligands. Nucleic Acids Res40: 6255-6269

Zubovic L, Baralle M, Baralle FE (2012b) Mutually exclusive splicing regulates the Nav 1.6 sodium channel function through a combinatorial mechanism that involves three distinct splicing regulatory elements and their ligands. Nucleic Acids Res40: 6255-6269