Effects of pentobarbitone and chlorpromazine on acoustically evoked potentials in the rat

Correlating stimulus-specific adaptation of cortical neurons and local field potentials in the awake rat

Changes in the sensory environment are good indicators for behaviorally relevant events and strong triggers for the reallocation of attention. In the auditory domain, violations of a pattern of repetitive stimuli precipitate in the event-related potentials as mismatch negativity (MMN). Stimulus-specific adaptation (SSA) of single neurons in the auditory cortex has been proposed to be the cellular substrate of MMN (Nelken and Ulanovsky, 2007). However, until now, the existence of SSA in the awake auditory cortex has not been shown. In the present study, we recorded single and multiunits in parallel with evoked local field potentials (eLFPs) in the primary auditory cortex of the awake rat. Both neurons and eLFPs in the awake animal adapted in a stimulus-specific manner, and SSA was controlled by stimulus probability and frequency separation. SSA of isolated units was significant during the first stimulus-evoked "on" response but not in the following inhibition and rebound of activity. The eLFPs exhibited SSA in the first negative deflection and, to a lesser degree, in a slower positive deflection but no MMN. Spike adaptation correlated closely with adaptation of the fast negative deflection but not the positive deflection. Therefore, we conclude that single neurons in the auditory cortex of the awake rat adapt in a stimulus-specific manner and contribute to corresponding changes in eLFP but do not generate a late deviant response component directly equivalent to the human MMN. Nevertheless, the described effect may reflect a certain part of the process needed for sound discrimination.

Modulation of gamma-aminobutyric acid type A receptor-mediated spontaneous inhibitory postsynaptic currents in auditory cortex by midazolam and isoflurane

BACKGROUND

Anesthetic agents that target gamma-aminobutyric acid type A (GABA(A)) receptors modulate cortical auditory evoked responses in vivo, but the cellular targets involved are unidentified. Also, for agents with multiple protein targets, the relative contribution of modulation of GABA(A) receptors to effects on cortical physiology is unclear. The authors compared effects of the GABA(A) receptor-specific drug midazolam with the volatile anesthetic isoflurane on spontaneous inhibitory postsynaptic currents (sIPSCs) in pyramidal cells of auditory cortex.

METHODS

Whole cell recordings were obtained in murine brain slices at 34 degrees C. GABA(A) sIPSCs were isolated by blocking ionotropic glutamate receptors. Effects of midazolam and isoflurane on time course, amplitude, and frequency of sIPSCs were measured.

RESULTS

The authors detected no effect of midazolam at 0.01 microM on sIPSCs, whereas midazolam at 0.1 and 1 microM prolonged the decay of sIPSCs by approximately 25 and 70%, respectively. Isoflurane at 0.1, 0.25, and 0.5 mm prolonged sIPSCs by approximately 45, 150, and 240%, respectively. No drug-specific effects were observed on rise time or frequency of sIPSCs. Isoflurane at 0.5 mm caused a significant decrease in sIPSC amplitude.

CONCLUSIONS

The dose dependence of isoflurane effects on GABA(A) sIPSCs in pyramidal cells is consistent with effects on auditory evoked response in vivo. By contrast, comparable effects of midazolam on GABA(A) sIPSCs arise at concentrations exceeding those currently thought to be achieved in vivo, suggesting that the cellular targets of midazolam reside elsewhere in the thalamocortical circuit or that the concentration of midazolam reached in the brain is higher than currently believed.

Excitatory effects of fentanyl upon the rat electroencephalogram and auditory-evoked potential responses during anaesthesia

BACKGROUND AND OBJECTIVE

Previous studies have shown existence of inconsistent data concerning the use of auditory-evoked potential (AEP) and electroencephalogram (EEG) changes to measure the depth of anaesthesia in regimens involving the use of opioids. The present studies characterize the effects of fentanyl on those responses in rats.

METHODS

The effects of a bolus of fentanyl (6-10 microg kg(-1) intravenously) alone or following naloxone (100 microg kg(-1) intravenously) were examined using brain responses in rats during light anaesthesia with either propofol (20-30 mg kg(-1) h(-1)) or isoflurane (0.8%). Electrophysiological data were recorded using silver ball electrodes. The rats' tracheas were intubated and a femoral artery cannula was inserted to monitor blood pressure. Body temperature, respiratory and pulse rate, and pedal withdrawal data were also collected. Parameters measured before and following administration of naloxone and fentanyl or of fentanyl alone were compared using repeated-measures ANOVA.

RESULTS

Fentanyl significantly increased the latency of the major peak from the AEP during propofol and isoflurane anaesthesia (F = 13.2 and 13.5, respectively; P < 0.05) and the amplitude differential between two waveform complexes, and the second differential index (F = 28.3 and 57.2, respectively; P < 0.01). The spectral edge frequency and median frequency from the EEG tended to increase. These effects were abolished by the prior administration of naloxone.

CONCLUSIONS

These excitatory effects were inconsistent with the classical concept of brain activity depression indicating a deepening of anaesthesia.

Long-term consolidation and retention of learning-induced tuning plasticity in the auditory cortex of the guinea pig

The major goal of this study was to determine whether classical conditioning produces long-term neural consolidation of frequency tuning plasticity in the auditory cortex. Local field potentials (LFPs) were obtained from chronically implanted adult male Hartley guinea pigs that were divided into conditioning (n = 4) and sensitization control (n = 3) groups. Tuning functions were determined in awake subjects for average LFPs (approximately 0.4 to 36.0 kHz, -20 to 80 dB) immediately before training as well as 1 h and 1, 3, 7, and 10 days after training; sensitization subjects did not have a 10-day retention test. Conditioning consisted of a single session of 30 to 45 trials of a 6-s tone (CS, 70 dB) that was not the best frequency (BF, peak of a tuning curve), followed by a brief leg shock (US) at CS offset. Sensitization control animals received the same density of CS and US presentations unpaired. Heart rate recordings showed that the conditioning group developed conditioned bradycardia, whereas the sensitization control group did not. Local field potentials in the conditioning group, but not in the sensitization group, developed tuning plasticity. The ratio of responses to the CS frequency versus the BF were increased 1 h after training, and this increase was retained for the 10-day period of the study. Both tuning plasticity and retention were observed across stimulus levels (10-80 dB). Most noteworthy, tuning plasticity exhibited consolidation (i.e., developed greater CS-specific effects across retention periods), attaining asymptote at 3 days. The findings indicate that LFPs in the auditory cortex have three cardinal features of behavioral memory: associative tuning plasticity, long-term retention, and long-term consolidation. Potential cellular and subcellular mechanisms of LFP tuning plasticity and long-term consolidation are discussed.

The rat vertex-middle latency auditory-evoked potential as indicator of anaesthetic depth: a comparison with evoked-reflex testing

We investigated whether components from the rat Vx-MLAEP could be used to assess depth of anaesthesia induced by propofol. Propofol decreased MLAEP amplitudes and increased latencies. We propose that the P(16)-N(22) wave in the rat MLAEP is similar to the human P1, and that recovery of this wave during propofol anaesthesia correlates with behavioural measures of the regaining of consciousness.

Topographic analysis of epidural pure-tone-evoked potentials in gerbil auditory cortex

This study investigated the tonotopic organization of pure-tone-evoked middle latency auditory evoked potentials (MAEPs) recorded at the auditory cortical surface in unanesthetized gerbils. Multielectrode array recording and multiple linear regression analysis of the MAEP demonstrated different degrees of tonotopic organization of early and late MAEP components. The early MAEP components P1 and N1 showed focal topography and clear dependence in location and size of cortical area covered on pure-tone frequency. The later components P2 and N2 showed a widespread topography which was largely unaffected in location and size of cortical area covered by pure-tone frequency. These results allow delimitation of the neural generators of the early and late MAEP components in terms of the spectral properties of functionally defined neural populations.

Midlatency auditory-evoked potentials in the rat: effects of interventions that modulate arousal

The vertex-recorded P13 midlatency auditory-evoked potential in the rat shows the same characteristics as the P1 potential in the human, namely, sleep-state dependence, rapid habituation and blockade by the cholinergic antagonist scopolamine. The P13 potential appears to be generated, at least in part, by projections of the pedunculopontine nucleus, the cholinergic arm of the reticular activating system. On the other hand, the auditory cortex-recorded P7 potential appears to be of primary cortical origin. Simultaneous recordings from the vertex and the auditory cortex showed that (1) the P13 potential was suppressed by administration of the anesthetics ketamine, pentobarbital or halothane in a dose-dependent manner, but the P7 potential was not; (2) the P13 potential was suppressed by intragastric injections of ethanol in a dose-dependent manner, but the P7 potential was not; (3) the amplitude of the P13 potential was negatively correlated with blood ethanol levels; (4) both the P13 and P7 potentials were still present following injections of the neuromuscular blocker pancuronium bromide; and (5) both the P13 and P7 potentials were decreased by diffuse brain injury induced by a weight-drop device in a weight-dependent manner. These findings suggest that the P13 potential is more sensitive than the P7 potential to changes in arousal and that the P13 and P7 potentials are not of myogenic but of neural origin.

The effects of low-pass filtering on the primary cortical auditory potential of the rat

The effects of low-pass filtering on the primary cortical auditory evoked potential (CAEP) were studied using the rat as subject. The CAEP is the potential which is generated by the arrival of the afferent volley in the primary auditory projection area. Recordings were made from animals which were totally awake and those which were anaesthetised with pentobarbital. A total of 9 recordings were obtained from each subject. The high-pass (low-frequency) filter remained fixed at 3.2 Hz while the low-pass (high-frequency) filter was set at 32, 80, 160, 320, 800 Hz and 1.6, 3.2, 8 and 16 kHz. The CAEP recorded from the awake animal consisted of a primary positivity (P1) followed by a later secondary positivity (P2). In the anaesthetised subjects, only the P1 potential was present. As the bandpass was progressively opened, there was at first a quite steep decline in latency associated with a gradual increase in amplitude. After the low-pass filter setting had been raised to 320 Hz, the amplitude of components P1 and P2 when awake and of P1 when anaesthetised had stabilized and thereafter there was no additional increase. Likewise, the latency of P2 for the awake subjects subsequently remained constant. In contrast, the latency of P1 recorded from both awake and anaesthetised subjects showed a continuing small decline as the bandpass was extended to 3.2-16 kHz. It is probable that this phenomenon did not represent a further genuine decrease in the latency of P1 but was more likely an artefact caused by the distorting effects of a cluster of late high-frequency components of the brainstem auditory evoked potential generated temporally contiguous to P1. It was concluded that a bandpass of 3.2-320 Hz is optimal for recording both early and late components of the CAEP and that low-pass filtering had an essentially uniform effect on the waveform irrespective of the subject's state of arousal.

A horseradish peroxidase study of parallel thalamocortical projections responsible for the generation of mid-latency auditory-evoked potentials

Mid-latency auditory-evoked potentials (MAEP) were recorded from the parietotemporal region of the rat using a high spatial resolution epicortical multielectrode array. Horseradish peroxidase was injected into regions of primary and secondary auditory cortex which generate spatially and temporally distinct components of the MAEP complex to retrogradely label their thalamocortical projections. These data provide anatomical evidence for three parallel thalamocortical projection systems, originating in the ventral, dorsal and medial subdivisions of the medial geniculate nucleus, which may be responsible for the asynchronous activation of three distinct subpopulations of cortical neurons giving rise to components of the MAEP complex. Specific and non-specific characteristics of the thalamocortical projections are discussed.

Binaural vs. monaural auditory evoked potentials in rat neocortex

High spatial resolution epicortical recording techniques and numerical modeling were used to investigate laterality effects on the middle latency auditory evoked potential (MAEP) complex. Our data confirm previous reports that auditory stimulus laterality has a consistent effect on the amplitude, timing, and spatial distribution of the MAEP complex. The earliest temporal components (P1a, P1b and N1) show the greatest sensitivity, and are absent during ipsilateral stimulation. The later positive slow wave (P2) is present at the same amplitude during all stimulation conditions. Generation of the P2 appears to be independent of prior activation of areas 36 and 41 reflected in the early components, suggesting its generation by a more diffuse thalamocortical pathway, possibly from the medial division of the medial geniculate. Serial vs. parallel activation of rodent auditory cortex is discussed in the context of laterality-sensitive MAEP components.

Multiple brain systems generating the rat auditory evoked potential. II. Dissociation of auditory cortex and non-lemniscal generator systems

This study addressed the issue of multiple parallel auditory processing systems and their relationship to the skull-recorded auditory evoked potentials (AEPs) in the unanesthetized, unrestrained rat. In the preceding paper (Brain Res., 602 (1993) 240-250) it has been shown that auditory cortex activity does not contribute significantly to the vertex maximal AEPs recorded from the dorsal skull of the rat. In the present study, mapping of the AEP skull distribution revealed two sets of components: one set maximal at the dorsal skull vertex, and another set at the lateral skull), but not the early (P7-P11, N15) lateral skull components generated in auditory cortex. Bilateral auditory cortex ablation eliminated the lateral skull maximal AEP components, but not the dorsal skull maximal components. These findings support extensive parallel processing of auditory inputs (reflected by the dorsal AEPs) in the absence of primary auditory cortex. Ablation of primary auditory cortex did result in a modulation of the dorsal skull AEPs, indicative of an interaction between the geniculocortical system and the parallel system which generates the dorsal AEPs.

Multiple brain systems generating the rat auditory evoked potential. I. Characterization of the auditory cortex response

The objectives of this study were to characterize the auditory cortex response in the rat and to examine its contributions to the auditory evoked potentials (AEPs) recorded from the dorsal and lateral skull. This was accomplished by simultaneously recording AEPs from the cortical surface and from skull screw electrodes in anesthetized animals. The initial positive-negative response (P17-N32) was largely restricted to the cortical region corresponding to area 41. More detailed examination of the AEP mapping revealed multiple subcomponents (P9, P14, P17, P19) underlying the initial positivity, with differing topographies. Stimulus-response properties further dissociated the multiple positive subcomponents. Reversible local neurochemical suppression confirmed the auditory cortical origin of these AEPs. The auditory cortex-generated AEPs were refractory to barbiturate anesthesia which eliminated all dorsal skull AEPs, indicating that primary auditory cortical AEPs do not make a significant contribution to the dorsal skull-recorded ('vertex') AEPs. The findings raise issues regarding multiple parallel auditory processing systems and their associated AEPs.

The functional anatomy of middle latency auditory evoked potentials

The neural origins of middle latency auditory evoked potentials (MAEP) were studied in rat cortex. MAEP were mapped from the cortical surface with a high spatial resolution electrode array. Spatiotemporal analysis, based on multivariate statistical methods, was then used to relate putative neural generators of the MAEP complex to established cytoarchitectural anatomy. These data indicate that the MAEP waveform reflects systematic asynchronous activation of both primary and secondary auditory cortex during the processing of simple click stimuli.

The effect of upper pontine transections on normal cochlear responses and on the protective effects of contralateral acoustic stimulation in barbiturate-anaesthetized normal-hearing guinea pigs

In barbiturate-anaesthetized guinea pigs with normal cochlear neural sensitivities, upper pontine transections were made to totally isolate the cell bodies of the olivocochlear neurons in the lower brainstem from all higher centres. The effects of this procedure were examined at the cochlea on normal compound action potential (CAP) thresholds and amplitudes, on the temporary threshold shifts (TTS) in CAP sensitivity caused by monaural loud sound exposures, and on the protective effects of low-level contralateral acoustic stimulation (Cody and Johnstone, 1982; Rajan and Johnstone, 1983a, 1988). The transection had no effects on any of these responses. These results suggest that centres above the metencephalon do not exert any tonic effects on the cell bodies of the olivocochlear pathways that result in tonic effects at the cochlea. Further, these results also suggest that the protective effects of contralateral acoustic stimulation are exercised solely through lower brainstem pathways.

Dose effects of halothane on sensory evoked responses obtained from the cortex, reticular formation and central gray

Sensory evoked field potentials were recorded from the mesencephalic reticular formation (MRF), central gray (CG) and somatosensory cortex (SCX), following incremental doses of halothane in freely-moving rats. Halothane concentrations of 0.25%, 0.5% 1.0% and 2.0% were used. In general, the responses from each structure were affected in dose response manner. The averaged acoustic evoked responses (AAER) exhibit more sensitivity to halothane than the averaged visual evoked responses (AVER). The evoked response and its components obtained from each structure were affected differently by halothane mainly following the initial two halothane doses, (0.25% and 0.5%); mainly increase in amplitude was observed in the recording obtained from the MRF, decrease in the CG, and mixed (increase and/or decrease) in SCX. The degree of the depression of the sensory evoked responses was directly correlated to the level of anesthesia as assessed by sural nerve stimulation.

Contribution of hypothermia to effects of chloral hydrate on flash evoked potentials of hooded rats

This study examined the contribution of hypothermia to the effects of chloral hydrate on the flash evoked potential (FEP) of hooded rats. Three experiments were performed, all employing intraperitoneal injections of saline, and of 75, 150 and 300 mg chloral hydrate/kg body weight. In the first experiment, body temperature was measured in a standard (23 degrees C) environment for 6 hr following injection. Rats were hypothermic following administration of the 150 and 300 mg/kg dosages for up to 1 and 2 hr, respectively. In the second experiment, FEPs were recorded from the visual cortex of chronically implanted rats 30 min after injection (22 degrees C environment). P1N1, N1P2 and P2N2 amplitudes and P1, N1, P2, N2 and P3 peak latencies were significantly increased by the 300 mg/kg dosage. Increased latencies were also noted for the primary components with the 150 mg/kg dosage. The final experiment replicated the second experiment, but at an ambient temperature of 30 degrees C, which prevented hypothermia. Amplitudes were unaffected by chloral hydrate. Significantly increased peak latencies were observed, even with the 75 mg/kg dose for some components. However, the magnitude of the latency increases of the primary components was less than half of that found with a standard environment. These results indicate that depending upon ambient temperature, hypothermia may contribute to chloral hydrate-induced alterations in FEPs.

Brain-stem auditory evoked potentials in rats with high-dose pentobarbital

Brain-stem auditory evoked potentials (BAEPs) are relatively resistant to alteration by barbiturate drugs, but the effects of the high doses that are used clinically to produce deep barbiturate coma for the treatment of intracranial hypertension and postischemic anoxic encephalopathy on BAEPs are unknown. We gave high-dose pentobarbital infusions to mechanically ventilated rats while recording serial BAEPs from the scalp. Pentobarbital progressively suppressed and then abolished all peaks. First the later waves, then all but the first wave, and finally all waves were abolished at intravenous doses of 120, 220, and 260 mg/kg, respectively, in addition to the initial anesthetic dose of 60 mg/kg i.p. The changes were at least partially reversible; peaks returned in reverse order of their disappearance. Peak latencies increased with dose. The results show a significant effect of pentobarbital on BAEPs in the rat, suggesting that BAEPs may be useful in assessing the depth of and recovery from barbiturate coma.