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CL Schauf and A Sattin
Department of Biology, Indiana University-Purdue University at Indianapolis.
In voltage-clamped Myxicola giant axons internally and externally applied tetrahydroaminoacridine (THA) blocked K+ channels with a dissociation constant of 100 microM and slowed their rate of activation. At a concentration of 10 microM, internal THA primarily slowed inactivation of conducting Na+ channels. At 100 microM the decline of the Na+ current during depolarizing pulses was biphasic, with an initial phase 2 to 3 times faster than in control axons. In the presence of THA there was a steady-state inward current accompanied by an increase in amplitude and time constant of Na+ tail currents, as if THA blocked Na+ channels by first entering them and then rendered THA- occluded channels resistant to fast inactivation. THA did not alter activation, prepulse-induced fast inactivation or slow inactivation. The effects of THA on voltage-dependent axonal ion channels might account for central nervous system hyperexcitability seen in some patients treated with THA. Because THA is a potent, centrally active anticholinesterase, even subtle ion channel-directed effects might contribute to its putative antidementia action in clinical states involving a central nervous system deficiency of acetylcholine by selective augmentation of acetylcholine release and/or negation of autoreceptor effects of endogeneous acetylcholine.
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