Purpose: Although it is widely used in clinical practice, the mechanisms of action of 2,6-di-isopropylphenol (propofol) are not completely understood. We examined the electrophysiologic effects of propofol on an in vitro model of epileptic activity obtained from a slice preparation. Methods: The effects of propofol were tested both on membrane properties and on epileptiform events consisting of long-lasting, paroxysmal depolarization shifts (PDSs) induced by reducing the magnesium concentration from the solution and by adding bicuculline and 4-aminopyridine.These results were integrated with a patch-clamp analysis of Na+ and high-voltage activated (HVA) calcium (Ca2+) currents from isolated cortical neurons. Results: In bicuculline, to avoid any interference by gamma-aminobutyric acid (GABA)-A receptors, propofol (3-100 mu M) did not cause significant changes in the current-evoked, sodium (Na+)-dependent action-potential discharge. However, propofol reduced both the duration and the number of spikes of PDSs recorded from cortical neurons. Interestingly, relatively low concentrations of propofol [half-maximal inhibitory concentration (IC50), 3.9 mu M) consistently inhibited the "persistent" fraction of Na+ currents, whereas even high doses (<= 300 mu M) had negligible effects on the "fast" component of Na+ currents. HVA Ca2+ currents were significantly reduced by propofol, and the pharmacologic analysis of this effect showed that propofol selectively reduced L-type HVA Ca2+ currents, without affecting N or P/Q-type channels. Conclusions: These results suggest that propofol modulates neuronal excitability by selectively suppressing persistent Na+ currents and L-type HVA Ca2+ conductances in cortical neurons. These effects might cooperate with the opening of GABA-A-gated chloride channels, to achieve depression of cortical activity during both anesthesia and status epilepticus.
Inhibition of persistent sodium current fraction and voltage-gated L-type calcium current by propofol in cortical neurons: Implications for its antiepileptic activity
Natoli S;Pisani A
2005-01-01
Abstract
Purpose: Although it is widely used in clinical practice, the mechanisms of action of 2,6-di-isopropylphenol (propofol) are not completely understood. We examined the electrophysiologic effects of propofol on an in vitro model of epileptic activity obtained from a slice preparation. Methods: The effects of propofol were tested both on membrane properties and on epileptiform events consisting of long-lasting, paroxysmal depolarization shifts (PDSs) induced by reducing the magnesium concentration from the solution and by adding bicuculline and 4-aminopyridine.These results were integrated with a patch-clamp analysis of Na+ and high-voltage activated (HVA) calcium (Ca2+) currents from isolated cortical neurons. Results: In bicuculline, to avoid any interference by gamma-aminobutyric acid (GABA)-A receptors, propofol (3-100 mu M) did not cause significant changes in the current-evoked, sodium (Na+)-dependent action-potential discharge. However, propofol reduced both the duration and the number of spikes of PDSs recorded from cortical neurons. Interestingly, relatively low concentrations of propofol [half-maximal inhibitory concentration (IC50), 3.9 mu M) consistently inhibited the "persistent" fraction of Na+ currents, whereas even high doses (<= 300 mu M) had negligible effects on the "fast" component of Na+ currents. HVA Ca2+ currents were significantly reduced by propofol, and the pharmacologic analysis of this effect showed that propofol selectively reduced L-type HVA Ca2+ currents, without affecting N or P/Q-type channels. Conclusions: These results suggest that propofol modulates neuronal excitability by selectively suppressing persistent Na+ currents and L-type HVA Ca2+ conductances in cortical neurons. These effects might cooperate with the opening of GABA-A-gated chloride channels, to achieve depression of cortical activity during both anesthesia and status epilepticus.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
