The action of general anaesthetics on acetylcholine-induced inhibition in the central nervous system of Helix

Sense and Insensibility - An Appraisal of the Effects of Clinical Anesthetics on Gastropod and Cephalopod Molluscs as a Step to Improved Welfare of Cephalopods

Recent progress in animal welfare legislation stresses the need to treat cephalopod molluscs, such as Octopus vulgaris, humanely, to have regard for their wellbeing and to reduce their pain and suffering resulting from experimental procedures. Thus, appropriate measures for their sedation and analgesia are being introduced. Clinical anesthetics are renowned for their ability to produce unconsciousness in vertebrate species, but their exact mechanisms of action still elude investigators. In vertebrates it can prove difficult to specify the differences of response of particular neuron types given the multiplicity of neurons in the CNS. However, gastropod molluscs such as Aplysia, Lymnaea, or Helix, with their large uniquely identifiable nerve cells, make studies on the cellular, subcellular, network and behavioral actions of anesthetics much more feasible, particularly as identified cells may also be studied in culture, isolated from the rest of the nervous system. To date, the sorts of study outlined above have never been performed on cephalopods in the same way as on gastropods. However, criteria previously applied to gastropods and vertebrates have proved successful in developing a method for humanely anesthetizing Octopus with clinical doses of isoflurane, i.e., changes in respiratory rate, color pattern and withdrawal responses. However, in the long term, further refinements will be needed, including recordings from the CNS of intact animals in the presence of a variety of different anesthetic agents and their adjuvants. Clues as to their likely responsiveness to other appropriate anesthetic agents and muscle relaxants can be gained from background studies on gastropods such as Lymnaea, given their evolutionary history.

Microelectronic neural bridging of toad nerves to restore leg function

The present study used a microelectronic neural bridge comprised of electrode arrays for neural signal detection, functional electrical stimulation, and a microelectronic circuit including signal amplifying, processing, and functional electrical stimulation to bridge two separate nerves, and to restore the lost function of one nerve. The left leg of one spinal toad was subjected to external mechanical stimulation and functional electrical stimulation driving. The function of the left leg of one spinal toad was regenerated to the corresponding leg of another spinal toad using a microelectronic neural bridge. Oscilloscope tracings showed that the electromyographic signals from controlled spinal toads were generated by neural signals that controlled the spinal toad, and there was a delay between signals. This study demonstrates that microelectronic neural bridging can be used to restore neural function between different injured nerves.

Anesthetic treatment blocks synaptogenesis but not neuronal regeneration of cultured Lymnaea neurons

Trauma and injury necessitate the use of various surgical interventions, yet such procedures themselves are invasive and often interrupt synaptic communications in the nervous system. Because anesthesia is required during surgery, it is important to determine whether long-term exposure of injured nervous tissue to anesthetics is detrimental to regeneration of neuronal processes and synaptic connections. In this study, using identified molluscan neurons, we provide direct evidence that the anesthetic propofol blocks cholinergic synaptic transmission between soma-soma paired Lymnaea neurons in a dose-dependent and reversible manner. These effects do not involve presynaptic secretory machinery, but rather postsynaptic acetylcholine receptors were affected by the anesthetic. Moreover, we discovered that long-term (18-24 h) anesthetic treatment of soma-soma paired neurons blocked synaptogenesis between these cells. However, after several hours of anesthetic washout, synapses developed between the neurons in a manner similar to that seen in vivo. Long-term anesthetic treatment of the identified neurons visceral dorsal 4 (VD4) and left pedal dorsal 1 (LPeD1) and the electrically coupled Pedal A cluster neurons (PeA) did not affect nerve regeneration in cell culture as the neurons continued to exhibit extensive neurite outgrowth. However, these sprouted neurons failed to develop chemical (VD4 and LPeD1) and electrical (PeA) synapses as observed in their control counterparts. After drug washout, appropriate synapses did reform between the cells, although this synaptogenesis required several days. Taken together, this study provides the first direct evidence that the clinically used anesthetic propofol does not affect nerve regeneration. However, the formation of both chemical and electrical synapses is severely compromised in the presence of this drug. This study emphasizes the importance of short-term anesthetic treatment, which may be critical for the restoration of synaptic connections between injured neurons.

Sevoflurane induced suppression of inhibitory synaptic transmission between soma-soma paired Lymnaea neurons

The cellular and synaptic mechanisms by which general anesthetics affect cell-cell communications in the nervous system remain poorly defined. In this study, we sought to determine how clinically relevant concentrations of sevoflurane affected inhibitory synaptic transmission between identified Lymnaea neurons in vitro. Inhibitory synapses were reconstructed in cell culture, between the somata of two functionally well-characterized neurons, right pedal dorsal 1 (RPeD1, the giant dopaminergic neuron) and visceral dorsal 4 (VD4). Clinically relevant concentrations of sevoflurane (1-4%) were tested for their effects on synaptic transmission and the intrinsic membrane properties of soma-soma paired cells. RPeD1- induced inhibitory postsynaptic potentials (IPSPs) in VD4 were completely and reversibly blocked by sevoflurane (4%). Sevoflurane also suppressed action potentials in both RPeD1 and VD4 cells. To determine whether the anesthetic-induced synaptic depression involved postsynaptic transmitter receptors, dopamine was pressure applied to VD4, either in the presence or absence of sevoflurane. Dopamine (10(-]5) M) activated a voltage-insensitive K(+) current in VD4. The same K(+) current was also altered by sevoflurane; however, the effects of two compounds were nonadditive. Because transmitter release from RPeD1 requires Ca(2+) influx through voltage-gated Ca(2+) channels, we next tested whether the anesthetic-induced synaptic depression involved these channels. Individually isolated RPeD1 somata were whole cell voltage clamped, and Ca(2+) currents were analyzed in control and various anesthetic conditions. Clinically relevant concentrations of sevoflurane did not significantly affect voltage-activated Ca(2+) channels in RPeD1. Taken together, this study provides the first direct evidence that sevoflurane-induced synaptic depression involves both pre- and postsynaptic ion channels.

Depressant and convulsant barbiturates both inhibit neuronal nicotinic acetylcholine receptors

Neuronal nicotinic acetylcholine receptors (neuronal nAchRs) are sensitive to many anesthetics, including barbiturates, which suggests that these receptors are potential sites for anesthetic action. Subtle changes in molecular structures of the anesthetic barbiturates can produce compounds with potent convulsant activity. Whereas R(-) isomer of 1-methyl-5-phenyl-5-propyl barbituric acid (MPPB) exerts anesthetic action, S(+)MPPB exhibits pure excitatory effects, including convulsion. 5-(2-cyclohexilidene-ethyl)-5-ethyl barbituric acid is another example of a convulsant barbiturate. We compared the effects of depressant and convulsant barbiturates on the neuronal nAchR-mediated current to determine whether inhibition of neuronal nAchRs contributes to the anesthetic action of barbiturates. Whole cell nicotine-induced currents were recorded in PC12 derived from rat pheochromocytoma, using the conventional whole cell patch clamp technique in the presence and absence of barbiturates. Both depressant and convulsant barbiturates inhibited the nicotine-induced inward current reversibly and in a dose-dependent manner when co-applied with nicotine. All barbiturates accelerated the current decay. There was no significant difference between the concentrations for 50% inhibition for MPPB isomers. There was no correlation between inhibition of ganglionic nAchRs and anesthetic effects of the barbiturates. These results strongly oppose the idea that inhibition of neuronal nAchRs contributes to the anesthetic action of barbiturates.

IMPLICATIONS

We found that both convulsant and depressant barbiturates inhibit the current mediated through ganglionic nicotinic acetylcholine receptors in PC12 cells. This finding suggests that the inhibition of neuronal nicotinic acetylcholine receptors does not contribute to the anesthetic action of barbiturates.

Actions of general anaesthetics on a neuronal nicotinic acetylcholine receptor in isolated identified neurones of Lymnaea stagnalis

1. Completely isolated identified neurones from the right parietal ganglion of the pond snail Lymnaea stagnalis were studied under two-electrode voltage-clamp. Neuronal nicotinic acetylcholine receptor currents were studied at low acetylcholine (ACh) concentrations (< or = 200 nM). At these levels, control currents were non-desensitizing and proportional to the square of the ACh concentration. 2. IC50 concentrations were determined for the steady-state inhibition of the ACh-activated current by 31 general anaesthetics plus the non-anaesthetic alcohol n-tridecanol. The general anaesthetics included inhalational agents, n-alcohols, n-alkane-(alpha,omega)-diols, cycloalcohols and an n-alkane. 3. Anaesthetic inhibition was independent of voltage and consistent with two anaesthetic-binding sites on the receptor. 4. IC50 concentrations for inhibiting the neuronal nicotinic ACh receptor correlated well (r = 0.97) with EC50 concentrations for general anaesthesia. The maximum deviation from the line of identity was less than fourfold. The inhalational agents tended to be more potent as inhibitors of the ACh receptor than as general anaesthetics, while the alcohols and diols were less potent. 5. The inhibition of the ACh-induced current by the homologous series of n-alcohols exhibited a cutoff at the same position (just after dodecanol) as found for the induction of general anaesthesia in tadpoles. 6. Polarity profile maps of the anaesthetic-binding sites on the neuronal nicotinic ACh receptor were calculated from IC50 concentrations for the homologous series of n-alcohols and n-alkane-(alpha,omega)-diols. They reveal amphiphilic sites with apolar regions capable of accommodating the hydrocarbon chains of n-alcohols as large as decanol. A striking resemblance was found to profiles previously calculated from data for tadpole general anaesthesia.

Stereospecific effects of inhalational general anesthetic optical isomers on nerve ion channels

Although it is generally agreed that general anesthetics ultimately act on neuronal ion channels, there is considerable controversy over whether this occurs by direct binding to protein or secondarily by nonspecific perturbation of lipids. Very pure optical isomers of the inhalational general anesthetic isoflurane exhibited clear stereoselectivity in their effects on particularly sensitive ion channels in identified molluscan central nervous system neurons. At the human median effect dose (ED50) for general anesthesia, the (+)-isomer was about twofold more effective than the (-)-isomer both in eliciting the anesthetic-activated potassium current IK(An) and in inhibiting a current mediated by neuronal nicotinic acetylcholine receptors. For inhibiting the much less sensitive transient potassium current IA, the (-)-isomer was marginally more potent than the (+)-isomer. Both isomers were equally effective at disrupting lipid bilayers.

Actions of anaesthetics and avermectin on GABAA chloride channels in mammalian dorsal root ganglion neurones

1. The gamma-aminobutyric acid (GABA)-mimetic actions of some anaesthetics and the antehelminthic avermectin B1a were examined on freshly isolated mammalian dorsal root ganglion (DRG) neurones by use of suction electrodes and a single electrode voltage clamp. 2. Pentobarbitone (60 microM-3 mM), chloralose (600 microM-1 mM), etomidate (10-100 microM), alphaxalone (10-60 microM) and avermectin (10-60 microM) directly activated chloride channels in GABA-sensitive DRG neurones. The agonist action was sensitive to block by bicuculline and picrotoxinin. 3. Steady-state current-voltage (I-V) curves for the anaesthetics were either linear, or rectified in the opposite direction to steady-state I-V curves obtained with GABA. Current relaxations in response to voltage jumps were also of the opposite direction. An extra surge of current ('bounce') was commonly observed on washout of some of these agonists. 4. Pentobarbitone was ineffective as an agonist at alkali pH (10.4 and 9.4), but was approximately twice as effective at acid (5.4) than at normal (7.4) pH values. 5. These results suggest that some anaesthetics and avermectin are capable of 'blocking' GABA channels in addition to activating them.

Anesthetics produce differential actions on membrane responses of the crayfish stretch receptor neuron

The actions of ethanol, halothane and pentobarbital on the membrane electrical properties and synaptic transmission of isolated crayfish stretch receptor neurons were studied to determine possible sites of action contributing to differential effects previously described on physiological discharge activity. The three agents depressed GABA-mediated transmission and altered postsynaptic membrane electrical properties. Both pre- and postsynaptic sites of action appeared to contribute to the anesthetic-induced alteration of neuronal function. The agents studied produced different, concentration-dependent, membrane effects which included biphasic actions on membrane resistance and spike threshold. The results suggest that multiple-sites of action are involved and different anesthetics may not act via the same mechanism(s) at these sites.

Ketamine depression of excitatory and inhibitory cholinergic responses in Aplysia neurons

The effects of ketamine on the cholinergic excitatory and inhibitory (Cl component) responses in Aplysia neurons were examined using the iontophoretic application of ACh and the two-microelectrode voltage clamp technique. Ketamine reduced both responses non-competitively to the same extent in a dose-dependent and reversible manner at concentrations between 10(-6) and 10(-3) M, without changing the reversal potentials. These findings suggest that ketamine depresses the cholinergic responses by affecting the gating mechanism at postsynaptic membranes.

Action of enflurane on cholinergic transmission in identified Aplysia neurones

Effects of enflurane on the cholinergic transmission in Aplysia neurones were studied by current and voltage clamp methods. Acetylcholine (ACh) evoked three types of postsynaptic responses on different identified neurones: (1) a depolarizing response due to an increase in Na and K conductances (D-response), (2) a fast hyperpolarizing response due to an increase in C1 conductance (C1-response), and (3) a slow hyperpolarizing response due to an increase in K conductance (K-response). Enflurane altered neither the action potential nor the membrane resistance of the neurones but depressed the three ACh-induced responses, non-competitively, in a dose-dependent manner. The K-response was less suppressed than the other two. Blockade of the closed state of ion channel was suggested by a reduction in the first ACh response evoked 1 min after administration of enflurane. The anaesthetic facilitated the decay of the neurally evoked e.p.s.c. and i.p.s.c. in suggesting a reduction in the mean open time of the postsynaptic ion channel. It is concluded that enflurane depresses excitatory and inhibitory cholinergic transmission by reducing the postsynaptic currents.