Molecular determinants of voltage-dependent gating and binding of pore-blocking drugs in transmembrane segment IIIS6 of the Na(+) channel alpha subunit.
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Mutations of amino acid residues in the inner two-thirds of the S6 segment in domain III of the rat brain type IIA Na(+) channel (G1460A to I1473A) caused periodic positive and negative shifts in the voltage dependence of activation, consistent with an alpha-helix having one face on which mutations to alanine oppose activation. Mutations in the outer one-third of the IIIS6 segment all favored activation. Mutations in the inner half of IIIS6 had strong effects on the voltage dependence of inactivation from closed states without effect on open-state inactivation. Only three mutations had strong effects on block by local anesthetics and anticonvulsants. Mutations L1465A and I1469A decreased affinity of inactivated Na(+) channels up to 8-fold for the anticonvulsant lamotrigine and its congeners 227c89, 4030w92, and 619c89 as well as for the local anesthetic etidocaine. N1466A decreased affinity of inactivated Na(+) channels for the anticonvulsant 4030w92 and etidocaine by 3- and 8-fold, respectively, but had no effect on affinity of the other tested compounds. Leu-1465, Asn-1466, and Ile-1469 are located on one side of the IIIS6 helix, and mutation of each caused a positive shift in the voltage dependence of activation. Evidently, these amino acid residues face the lumen of the pore, contribute to formation of the high-affinity receptor site for pore-blocking drugs, and are involved in voltage-dependent activation and coupling to closed-state inactivation. (+info)
Role of amino acid residues in transmembrane segments IS6 and IIS6 of the Na+ channel alpha subunit in voltage-dependent gating and drug block.
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Alanine-scanning mutagenesis of transmembrane segments IS6 and IIS6 of the rat brain Na(v)1.2 channel alpha subunit identified mutations N418A in IS6 and L975A in IIS6 as causing strong positive shifts in the voltage dependence of activation. In contrast, mutations V424A in IS6 and L983A in IIS6 caused strong negative shifts. Most IS6 mutations opposed inactivation from closed states, but most IIS6 mutations favored such inactivation. Mutations L421C and L983A near the intracellular ends of IS6 and IIS6, respectively, exhibited significant sustained Na(+) currents at the end of 30-ms depolarizations, indicating a role for these residues in Na(+) channel fast inactivation. These residues, in combination with residues at the intracellular end of IVS6, are well situated to form an inactivation gate receptor. Mutation I409A in IS6 reduced the affinity of the local anesthetic etidocaine for the inactivated state by 6-fold, and mutations I409A and N418A reduced use-dependent block by etidocaine. No IS6 or IIS6 mutations studied affected inactivated-state affinity or use-dependent block by the neuroprotective drug sipatrigine (compound 619C89). These results suggest that the local anesthetic receptor site is formed primarily by residues in segments IIIS6 and IVS6 with the contribution of a single amino acid in segment IS6. (+info)
Long-acting local anesthetics in dentistry.
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Long-acting local anesthetics have proved to be effective for the suppression of both intraoperative and postoperative pain. They are useful for lengthy dental treatments and for prevention of severe pain following many types of surgical procedures. Although the currently available long-acting local anesthetics for dentistry have minimal side effects in the doses usually employed, there are potential problems. Bupivacaine, for example, can cause significant cardiac depressant and dysrhythmogenic responses. Etidocaine has less pronounced effects on the cardiovascular system, but its use may be associated with inadequate control of intraoperative bleeding. A new long-acting local anesthetic, ropivacaine, appears to offer advantages over either of the currently used long-acting agents. (+info)
On the mechanism by which bupivacaine conducts protons across the membranes of mitochondria and liposomes.
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Bupivacaine and etidocaine possess the remarkable property of stimulating mitochondrial respiration to levels comparable with those observed with classical anionic protonophores (Dabadie, P., Bendriss, P., Erny, P., and Mazat, J.P. (1987) FEBS Lett. 226, 77-82). We show that these amphiphilic amines conduct protons across the membranes of mitochondria and liposomes and stimulate respiration by a true protonophoretic mechanism. The kinetics of drug-induced H+ flux exhibited integer Hill coefficients that were greater than two under all conditions, suggesting that multimers are required for H+ transport. When the energy barrier for ion transport was lowered in mitochondria, by increasing the membrane potential, or in liposomes, by adding phloretin, the Hill coefficients decreased to lower integer numbers. Protonophoretic activity depended exclusively on medium concentration of free base, leading us to conclude that bupivacaine and etidocaine conduct protons as associated, intramembrane multimers of the free base. Bupivacaine-induced H+ leak was ohmic rather than nonohmic, as would be expected of a mobile charged carrier. This kinetic behavior seems improbable for a multimeric mobile carrier mechanism and suggests a channel mechanism, in which ohmicity results from splitting of the energy barrier by energy wells along the transport pathway (Garlid, K. D., Beavis, A. D., and Ratkje, S. K. (1989) Biochim. Biophys. Acta 976, 109-120). We hypothesize that bupivacaine and etidocaine act by a novel "flickering channel" mechanism, in which transient linear complexes of free base molecules provide weak binding sites (energy wells) for protons within lipid bilayer membranes. (+info)
Visual evoked potentials after retrobulbar or periocular anaesthesia.
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The effect of the local anaesthetic agent, etidocaine, on the optic nerve function was examined at regional ophthalmic anaesthesia. Visual evoked potential (VEP) was recorded before and 15 minutes after injection of the anaesthetic agent in 19 patients scheduled for elective cataract surgery (seven retrobulbar and 12 periocular). Both the anaesthetised--that is, the eye to be operated on--and the fellow eye were examined. In the retrobulbar group, two patients displayed non-recordable VEPs while one had virtually non-detectable waves following the anaesthesia. In two retrobulbarly anaesthetised eyes, later peaks were unidentifiable while two other eyes had decreased amplitudes. In the periocular group, in nine patients, there was no clearcut effect on VEP resulting from the anaesthetic. In three patients of this group mild changes in the anaesthetised eyes were found. The differences in the effect of retrobulbarly or periocularly injected anaesthetics on VEP are probably due to the different concentration of the anaesthetic agent around the optic nerve. (+info)
A clinical trial of long-acting local anesthetics for periodontal surgery.
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The efficacy of long-acting local anesthetics for anesthesia during periodontal surgery and for analgesia during the immediate postoperative period was evaluated. The rationale for using long-acting local anesthetics such as etidocaine and bupivacaine is that they can provide surgical anesthesia and, because of their long duration, prevent discomfort that may occur for 4-6 hours postoperatively. Two clinical trials were performed. The first enrolled patients requiring bilateral periodontal surgery. Using a matched pair design and double-blind randomized study conditions, 2% lidocaine 1/100,000 epinephrine was compared with 1.5% etidocaine 1/200,000 epinephrine for periodontal surgery. The time until complete recovery and the time until pain onset were found to be longer for the etidocaine surgeries. Postoperative pain appeared more severe, and the need for oral analgesics was greater for the lidocaine surgeries. Surgeons' rating of surgical bleeding was significantly greater for the etidocaine procedures. When matched bilateral surgeries were not available, a second double-blind randomized parallel trial was performed that compared 1.5% etidocaine 1/200,000 epinephrine to 0.5% bupivacaine 1/200,000 epinephrine. No significant differences were seen in the quality of anesthesia, degree of bleeding, or postoperative pain between these two long-acting anesthetics. (+info)
Effect of local anaesthetics on mitochondrial membrane potential in living cells.
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Using the laser dye rhodamine 123, we demonstrated that local anaesthetics can reach mitochondria in cell culture and reversibly decrease, or even collapse, their transmembrane potential. This effect is highly dependent on the lipid-solubility of the local anaesthetic and can be facilitated by the presence of a lipophilic anion. (+info)
Inhibition of sodium currents by local anesthetics in chloramine-T-treated squid axons. The role of channel activation.
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In order to test the requirement of Na channel inactivation for the action of local anesthetics, we investigated the inhibitory effects of quaternary and tertiary amine anesthetics on normally inactivating and noninactivating Na currents in squid axons under voltage clamp. Either the enzymatic mixture pronase, or chloramine-T (CT), a noncleaving, oxidizing reagent, was used to abolish Na channel inactivation. We found that both the local anesthetics QX-314 and etidocaine, when perfused internally at 1 mM, elicited a "tonic" (resting) block of Na currents, a "time-dependent" block that increased during single depolarizations, and a "use-dependent" (phasic) block that accumulated as a result of repetitive depolarizations. All three effects occurred in both control and CT-treated axons. As in previous reports, little time-dependent or phasic block by QX-314 appeared in pronase-treated axons, although tonic block remained. Time-dependent block was greatest and fastest at large depolarizations (Em greater than +60 mV) for both the control and CT-treated axons. The recovery kinetics from phasic block were the same in control and CT-modified axons. The voltage dependence of the steady state phasic block in CT-treated axons differed from that in the controls; an 8-10% reduction of the maximum phasic block and a steepening and shift of the voltage dependence in the hyperpolarizing direction resulted from CT treatment. The results show that these anesthetics can bind rapidly to open Na channels in a voltage-dependent manner, with no requirement for fast inactivation. We propose that the rapid phasic blocking reactions in nerve are consequences primarily of channel activation, mediated by binding of anesthetics to open channels, and that the voltage dependence of phasic block arises directly from that of channel activation. (+info)