ライフサイエンスコーパス: voltage-dependent sodium channel

1 urons (appearance of tetrodotoxin-sensitive, voltage-dependent sodium channels).

2 ve expression of distinct genes encoding the voltage-dependent sodium channel.

3 e sensors and the outer pore of a eukaryotic voltage-dependent sodium channel.

4 e for subsequent assembly of ankyrin and the voltage-dependent sodium channel.

5 ed at nodes of Ranvier with ankyrinG and the voltage-dependent sodium channel.

6 osamide is an antiseizure agent that targets voltage-dependent sodium channels.

7 perexcitability), due to a local response of voltage-dependent sodium channels.

8 te outgrowth and the increased expression of voltage-dependent sodium channels.

9 rsal root ganglia and analyze the effects on voltage-dependent sodium channels.

10 of Ranvier and are candidates to couple the voltage-dependent sodium channel and neurofascin to the

11 ansmitter receptors and ion channels such as voltage-dependent sodium channels and GABA-gated chlorid

12 oxins that bind to the extracellular face of voltage-dependent sodium channels and retard channel ina

13 Tetrodotoxin (TTX, 0.3 microM), a voltage-dependent sodium channel antagonist that blocks

14 Voltage-dependent sodium channels are believed to have e

15 Voltage-dependent sodium channels are the central player

16 Voltage-dependent sodium channels are uniformly distribu

17 Blockade of voltage-dependent sodium channels by TTX also reduced CS

18 e fractions that also contain high levels of voltage-dependent sodium channels, caspr, and neuron-gli

19 Mutations in voltage-dependent sodium channels cause severe autism/in

20 Voltage-dependent sodium channels cluster at high densit

21 mbrane proteins (neurofascin, NrCAM, and the voltage-dependent sodium channel) colocalize within a sp

22 LQT3, is caused by mutations in the cardiac voltage-dependent sodium channel gene, SCN5A.

23 h--as well as changes in the inactivation of voltage-dependent sodium channels in living cells.

24 The type II voltage-dependent sodium channel is present in neuronal

25 Although action potentials are not involved, voltage-dependent sodium channels may enhance subthresho

26 Voltage-dependent sodium channels mediate transient curr

27 discovery of a new class of neuroprotective voltage-dependent sodium channel modulators exemplified

28 Rat GP neurons express fast, transient voltage-dependent sodium channels (NaF channels) in thei

29 Binding to the neuronal voltage-dependent sodium channel (NVSC) was evaluated fo

30 show that both glutamate NMDA receptors and voltage-dependent sodium channels play roles in CSD.

31 nes caused delayed inactivation of mammalian voltage-dependent sodium channels, resulting in a positi

32 distribution of ankyrinG 480/270 kDa and the voltage-dependent sodium channel, suggesting that the ad

33 evident when tetrodotoxin was added to block voltage-dependent sodium channels, suggesting that inter

34 ate subthreshold current carried by the same voltage-dependent sodium channels that underlie fast act

35 recruitment of ankyrinG 480/270 kDa and the voltage-dependent sodium channel to cluster sites contai

36 One neuronal target is NaV1.2, voltage-dependent sodium channel type II, to which CaM b

37 evealed that the pore-lining (P) segments of voltage-dependent sodium channels undergo sizable motion

38 Voltage-dependent sodium channels were studied in dissoc