TY - JOUR
T1 - Chimeric agents derived from the functionalized amino acid, lacosamide, and the α-aminoamide, safinamide
T2 - Evaluation of their inhibitory actions on voltage-gated sodium channels, and antiseizure and antinociception activities and comparison with lacosamide and safinamide
AU - Park, Ki Duk
AU - Yang, Xiao Fang
AU - Dustrude, Erik T.
AU - Wang, Yuying
AU - Ripsch, Matthew S.
AU - White, Fletcher A.
AU - Khanna, Rajesh
AU - Kohn, Harold
N1 - Publisher Copyright:
© 2014 American Chemical Society.
PY - 2015/2/18
Y1 - 2015/2/18
N2 - The functionalized amino acid, lacosamide ((R)-2), and the α-aminoamide, safinamide ((S)-3), are neurological agents that have been extensively investigated and have displayed potent anticonvulsant activities in seizure models. Both compounds have been reported to modulate voltage-gated sodium channel activity. We have prepared a series of chimeric compounds, (R)-7-(R)-10, by merging key structural units in these two clinical agents, and then compared their activities with (R)-2 and (S)-3. Compounds were assessed for their ability to alter sodium channel kinetics for inactivation, frequency (use)-dependence, and steady-state activation and fast inactivation. We report that chimeric compounds (R)-7-(R)-10 in catecholamine A-differentiated (CAD) cells and embryonic rat cortical neurons robustly enhanced sodium channel inactivation at concentrations far lower than those required for (R)-2 and (S)-3, and that (R)-9 and (R)-10, unlike (R)-2 and (S)-3, produce sodium channel frequency (use)-dependence at low micromolar concentrations. We further show that (R)-7-(R)-10 displayed excellent anticonvulsant activities and pain-attenuating properties in the animal formalin model. Of these compounds, only (R)-7 reversed mechanical hypersensitivity in the tibial-nerve injury model for neuropathic pain in rats.
AB - The functionalized amino acid, lacosamide ((R)-2), and the α-aminoamide, safinamide ((S)-3), are neurological agents that have been extensively investigated and have displayed potent anticonvulsant activities in seizure models. Both compounds have been reported to modulate voltage-gated sodium channel activity. We have prepared a series of chimeric compounds, (R)-7-(R)-10, by merging key structural units in these two clinical agents, and then compared their activities with (R)-2 and (S)-3. Compounds were assessed for their ability to alter sodium channel kinetics for inactivation, frequency (use)-dependence, and steady-state activation and fast inactivation. We report that chimeric compounds (R)-7-(R)-10 in catecholamine A-differentiated (CAD) cells and embryonic rat cortical neurons robustly enhanced sodium channel inactivation at concentrations far lower than those required for (R)-2 and (S)-3, and that (R)-9 and (R)-10, unlike (R)-2 and (S)-3, produce sodium channel frequency (use)-dependence at low micromolar concentrations. We further show that (R)-7-(R)-10 displayed excellent anticonvulsant activities and pain-attenuating properties in the animal formalin model. Of these compounds, only (R)-7 reversed mechanical hypersensitivity in the tibial-nerve injury model for neuropathic pain in rats.
KW - Chimeric compounds
KW - antinociception activity
KW - antiseizure activity
KW - functionalized amino acids (lacosamide)
KW - sodium channel activity
KW - α-aminoamides (safinamide)
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U2 - 10.1021/cn5002182
DO - 10.1021/cn5002182
M3 - Article
C2 - 25418676
AN - SCOPUS:84923241401
SN - 1948-7193
VL - 6
SP - 316
EP - 330
JO - ACS Chemical Neuroscience
JF - ACS Chemical Neuroscience
IS - 2
ER -