Hypothermia and chloropent anesthesia differentially affect the flash evoked potentials of hooded rats

Development and Experimental Validation of a Dry Non-Invasive Multi-Channel Mouse Scalp EEG Sensor through Visual Evoked Potential Recordings

In this paper, we introduce a dry non-invasive multi-channel sensor for measuring brainwaves on the scalps of mice. The research on laboratory animals provide insights to various practical applications involving human beings and other animals such as working animals, pets, and livestock. An experimental framework targeting the laboratory animals has the potential to lead to successful translational research when it closely resembles the environment of real applications. To serve scalp electroencephalography (EEG) research environments for the laboratory mice, the dry non-invasive scalp EEG sensor with sixteen electrodes is proposed to measure brainwaves over the entire brain area without any surgical procedures. We validated the proposed sensor system with visual evoked potential (VEP) experiments elicited by flash stimulations. The VEP responses obtained from experiments are compared with the existing literature, and analyzed in temporal and spatial perspectives. We further interpret the experimental results using time-frequency distribution (TFD) and distance measurements. The developed sensor guarantees stable operations for in vivo experiments in a non-invasive manner without surgical procedures, therefore exhibiting a high potential to strengthen longitudinal experimental studies and reliable translational research exploiting non-invasive paradigms.

Inhalational Exposure to Carbonyl Sulfide Produces Altered Brainstem Auditory and Somatosensory-Evoked Potentials in Fischer 344N Rats

Carbonyl sulfide (COS), a chemical listed by the original Clean Air Act, was tested for neurotoxicity by a National Institute of Environmental Health Sciences/National Toxicology Program and U.S. Environmental Protection Agency collaborative investigation. Previous studies demonstrated that COS produced cortical and brainstem lesions and altered auditory neurophysiological responses to click stimuli. This paper reports the results of expanded neurophysiological examinations that were an integral part of the previously published experiments (Morgan et al., 2004, Toxicol. Appl. Pharmacol. 200, 131-145; Sills et al., 2004, Toxicol. Pathol. 32, 1-10). Fisher 334N rats were exposed to 0, 200, 300, or 400 ppm COS for 6 h/day, 5 days/week for 12 weeks, or to 0, 300, or 400 ppm COS for 2 weeks using whole-body inhalation chambers. After treatment, the animals were studied using neurophysiological tests to examine: peripheral nerve function, somatosensory-evoked potentials (SEPs) (tail/hindlimb and facial cortical regions), brainstem auditory-evoked responses (BAERs), and visual flash-evoked potentials (2-week study). Additionally, the animals exposed for 2 weeks were examined using a functional observational battery (FOB) and response modification audiometry (RMA). Peripheral nerve function was not altered for any exposure scenario. Likewise, amplitudes of SEPs recorded from the cerebellum were not altered by treatment with COS. In contrast, amplitudes and latencies of SEPs recorded from cortical areas were altered after 12-week exposure to 400 ppm COS. The SEP waveforms were changed to a greater extent after forelimb stimulation than tail stimulation in the 2-week study. The most consistent findings were decreased amplitudes of BAER peaks associated with brainstem regions after exposure to 400 ppm COS. Additional BAER peaks were affected after 12 weeks, compared to 2 weeks of treatment, indicating that additional regions of the brainstem were damaged with longer exposures. The changes in BAERs were observed in the absence of altered auditory responsiveness in FOB or RMA. This series of experiments demonstrates that COS produces changes in brainstem auditory and cortical somatosensory neurophysiological responses that correlate with previously described histopathological damage.

Temperature dependence and independence of effects of pentobarbital on visual evoked potentials of rats

Visual cortex flash evoked potentials (FEPs), pattern reversal evoked potentials (PREPs), and body temperature were measured in hooded rats following IP injections on separate days of saline, and of 15 and 30 mg pentobarbital/kg body weight. Two experiments were performed, differentiated by standard (23 degrees C) and warm (31 degrees C) room temperatures. The 30 mg/kg dose produced hypothermia of 2.6 degrees C in the standard environment, but not in the warm environment. Early components of FEPs were generally increased in amplitude by the 15 mg/kg dose, and decreased by the 30 mg/kg dose at 23 degrees C. At 31 degrees C, the 30 mg/kg dose did not decrease early component amplitude, suggesting that hypothermia can potentiate some effects of pentobarbital. Amplitudes of late FEP components were depressed at both ambient temperatures. The main PREP components N1P1 and P1N3 were increased in amplitude by the 15 mg/kg dose, but returned to near baseline levels at 30 mg/kg, at both temperatures. PREP component N2P2 was reduced in amplitude by the 30 mg/kg dose only at 23 degrees C. Treatment with 30 mg/kg pentobarbital increased FEP and PREP latencies at both ambient temperatures, but the magnitudes of the increases at 31 degrees C were typically less than half those observed at 23 degrees C. These results indicate that hypothermia contributes to some pentobarbital-induced changes in both FEPs and PREPs, but that pentobarbital also produces effects independent of hypothermia.

Two weeks inhalation exposure to 4-tert-butyltoluene causes persistent changes in visually evoked potentials in rats

The effects of repeated exposure to 20 p.p.m. 4-tert-butyltoluene (CAS No. [98-51-1]) 6 hr/day for 14 days on the function of the intact nervous system were examined by measurements of flash evoked potentials in Wistar rats. The exposure to 4-tert-butyltoluene induced changes in the amplitudes of the flash evoked potentials. The changes were significantly different from controls on day 2, 19 and 26 after cessation of the exposure, but not on day 5 and 12. No significant difference in body weight gain between groups was found during the experiment. These results indicate that repeated exposure to 20 p.p.m. 4-tert-butyltoluene causes persistent changes in the function of the central nervous system measured as changes in the flash evoked potential. A reevaluation of the present TLV value of 10 p.p.m. for 4-tert-butyltoluene is suggested.

Visual and somatosensory evoked potentials are mediated by excitatory amino acid receptors in the thalamus

In pentobarbital-anaesthetized rats early somatosensory evoked potentials (SEPs) were recorded from the sensory cortex in response to electrical stimulation of the contralateral forepaw and visual evoked potentials (VEPs) from the primary visual cortex in response to single light flashes. Microapplication of the specific non-NMDA antagonist 6,7-dinitroquinoxaline-2,3-dione (DNQX) into the ventro-basal thalamus (VB) resulted in a pronounced decrease in amplitude and an increase in latency of SEPs, whereas injection of DNQX into the dorsal lateral geniculate nucleus (DGL) induced a pronounced decrease in amplitude and an increase in latency of VEPs. These changes were: (1) dose-dependent (DNQX 0.01-1.0 nmol), (2) receptor-specific, and (3) site-specific. In contrast, the specific NMDA antagonist 2-amino-7-phosphonoheptanoate (AP7; 0.5-5 nmol) did not affect SEPs after microapplication into the BV and less potently reduced the amplitude and increased the latency of VEPs after microapplication into the DGL. The present findings are consistent with the assumption that an excitatory amino acid serves as transmitter at synapses in the rat thalamus mediating the nervous impulses responsible for the generation of SEPs and of VEPs. In addition the results suggest that this transmitter preferentially interacts with non-NMDA receptors.

Differential effects of transient occlusion of common carotid arteries in normotensive rats on the somatosensory and visual system

The effect of transient occlusion of both carotid arteries in normotensive rats (BCCA) on the electrical function of the central nervous system was monitored by recording somatosensory evoked potentials (SEPs), visual evoked potentials (VEPs) and electroretinogram (ERG). The amplitude and latency of cortical SEPs were not affected by BCCA. In contrast, the latency of P1 and N1 of VEPs were increased and the peak-to-peak amplitude (P1-N1) decreased. The amplitude of the b-wave of the ERG was reduced and its latency increased during BCCA. These changes in VEPs and ERG were limited to the period of BCCA. During the first hour of reperfusion VEPs and the b-wave of the ERG revealed no differences between former occluded animals and sham-operated controls. The present results suggest that both sensory pathways display a different susceptibility to BCCA.

Flash and pattern reversal visual evoked potentials in C57BL/6J and B6CBAF1/J mice

Visual system responses (visual evoked potentials) to flash (FVEP) and pattern reversal (PRVEP) stimuli were recorded in mice. Two strains were used: black C57BL/6J mice and agouti B6CBAF1/J mice (first generation offspring of C57BL/6J females and CBA/J males.) Subjects were sedated with ketamine and xylazine. Flash rate (FVEP) and stimulus spatial frequency and pattern reversal rate (PRVEP) were varied to determine optimum stimulus parameters. Normative FVEP and PRVEP data were collected from mice of both strains after determination of optimum parameters. Five positive and four negative alternating peaks were routinely observed in the FVEP, while three positive and three negative alternating peaks were seen with the PRVEP. Varying the flash rate, the pattern reversal rate, and spatial frequency significantly affected nearly all amplitude and latency measures in the responses. Significant differences between strains were seen on some, but not all, latency and amplitude measures when the stimulus parameters were varied.

Acute effects of ethanol on pattern reversal and flash-evoked potentials in rats and the relationship to body temperature

The effects of acute ethanol treatment on flash and pattern reversal visual evoked potentials (FEPs and PREPs, respectively) were examined in three experiments using Long-Evans rats. The relationships of evoked potential parameters with blood ethanol concentration and body temperature were examined. In Experiment 1, rats were treated i.p. with vehicle or 0.5, 1.0 or 2.0 g ethanol/kg body weight, and tested 30 min later. The 2.0 g/kg group had prolonged latencies of PREP peaks, no changes in PREP peak-to-peak amplitudes, and lower body temperatures than saline-treated controls. The peak latency shifts were significantly correlated with both blood ethanol concentration and body temperature, and were of a magnitude to be expected from similar changes in body temperature alone. Experiment 2 measured both PREPs and paired-flash FEPs in rats 30 min after injection of either 0, 0.5 or 2.0 g/kg ethanol. PREP changes were found following treatment with the high dose which were similar to those of Experiment 1. Some FEP peak latencies were prolonged and peak-to-peak amplitudes were reduced by both doses of ethanol, despite the fact that body temperatures were reduced at only the high dose. At 2.0 g/kg ethanol, the FEP changes in latency, but not amplitude, were in accordance with what would be expected from body temperature changes alone. The third study attempted to investigate the role of reduced body temperature in producing the visual evoked potential changes by testing at room temperatures of 22 or 30 degrees C. Contrary to expectations, the rats receiving 2 g/kg ethanol were approx. 1 degree C cooler than controls at both room temperatures. Evoked potential latencies were greater in ethanol-treated rats than controls at both room temperatures. There were no significant effects of ethanol on FEP amplitudes. Overall, the effects of low doses of ethanol were independent of temperature changes, but the effects of higher doses of ethanol (2.0 g/kg) could not be distinguished from those produced by differences in body temperature alone.

Sensory-evoked potentials as indices of neurotoxicity in the rat: effect of 4-tert-butyltoluene

The use of evoked potentials to measure neurotoxicity was evaluated using 4-tert-butyltoluene (TBT) as a test compound. Male Wistar rats were habituated to the recordings of auditory- and flash-evoked potentials until the combined waveform of the evoked potentials reached a steady state. The rats were then divided into three groups and exposed to 0, 50 and 150 ppm TBT for 6 h, and the auditory- and flash-evoked potentials were measured for up to 288 h after exposure. Event-related potentials specifically associated with the temporal pairing of auditory and visual stimuli were not apparent in the recordings. The peak-to-peak values of selected components, integrated amplitude and power spectra of the waveforms in exposed rats were significantly different from control values for at least 288 h in the group exposed to 150 ppm TBT and for 120 h in the group exposed to 50 ppm TBT. It is concluded that evoked potentials may be used for detection and characterization of minor neurofunctional changes due to low-dose exposure to chemicals.

Thermal influences on nervous system function

The various effects of temperature change are only partially predictable. Temporal measures relevant to membrane activity, action potentials, synaptic transmission, and evoked potentials are all consistently increased with cooling and decreased by warming. However, the various measures of amplitude at different levels, and even within similar preparations, are contradictory: Some laboratories report increased amplitudes with cooling and others report decreased amplitudes under similar conditions. Emphasis is given to identifying factors that may resolve the differences. These include: (a) the rate of temperature change, (b) sites of cooling, stimulation and recording, (c) stimulus characteristics, and (d) fundamental differences in temperature sensitivities of different neural tissue. Other factors that may affect the ability to predict thermal influences on neural function from existing formulations are: relative ion permeabilities, metabolic ion pumps, the resting potential at the onset of cooling, and an animal's acclimated temperature at sacrifice.

Effects of ketamine, naloxone, and physostigmine on flash evoked potentials in rat superior colliculus

Flash evoked potentials were recorded from the superior colliculus of chronically implanted hooded rats at 5 and 20 min following IP injections of saline, ketamine (75 mg/kg), naloxone (10 mg/kg), or physostigmine (0.4 mg/kg) on separate days. Components in an early positive complex were unaffected by ketamine and naloxone, but were reduced in amplitude by physostigmine. A positive spike emerged from the middle of a later negative wave following ketamine administration, but the amplitude of the negative wave was unaltered by naloxone or physostigmine. A succeeding positive component was enhanced by both ketamine and physostigmine. Physostigmine produced the most consistent alterations in latency, with most components increasing in latency. Naloxone pretreatment did not alter ketamine's influence on evoked potential amplitudes. Pretreatment with physostigmine briefly decreased the amplitude of the ketamine-induced positive spike, augmented the amplitude of the succeeding positive component, and also increased most peak latencies. Ketamine, naloxone and physostigmine all produced approximately equivalent hypothermia. Physostigmine, but not naloxone, pretreatment augmented the ketamine-induced hypothermia. The body temperature data suggest that some of the observed latency alterations are secondary to hypothermia. The amplitude data indicate that ketamine and physostigmine produce a combination of similar, distinct, and antagonistic effects on evoked potentials.

Temperature-dependent changes in visual evoked potentials of rats

The effects of alterations in body temperature on flash and pattern reversal evoked potentials (FEPs and PREPs) were examined in hooded rats whose thermoregulatory capacity was compromised with lesions of the preoptic/anterior hypothalamic area and/or cold restraint. Body temperature, measured with a rectal thermometer, was manipulated via exposure to different ambient temperatures. To describe the data, a model was used in which both linear and quadratic relationships could be estimated. PREP amplitudes were not significantly influenced by body temperature over the range of 27-42 degrees C, although in one experiment FEP amplitudes did show a linear decline as temperatures fell below approximately 30 degrees C. Both FEP and PREP latencies were strongly influenced by temperature and became progressively longer as body temperature was lowered. The non-linear component affecting latencies became more prominent as body temperature decreased. These data demonstrate the temperature dependence of FEP and PREP latencies independent of anesthetic or other drugs.

Ketamine alters rat flash evoked potentials

Discovering the neurotransmitters involved in the generation of flash evoked potentials (FEPs) would enhance the use of FEPs in screening for and assessment of neurological damage. Recent evidence suggests that the excitatory amino acids, glutamate and aspartate, may be transmitters in the visual system. Ketamine selectively antagonizes the actions of excitatory amino acids on n-methyl-d-aspartate receptors and may be administered systemically. Two experiments were designed to test the effects of ketamine on rat FEPs. First, the effects of ketamine (37, 75, 150 mg/kg) on FEPs recorded in light and dark backgrounds were investigated at a single (10 min) posttreatment interval. Ketamine administration resulted in dose-dependent alterations in FEP peak amplitudes and latencies. Peak P1 amplitude increased by a factor of 4, in a dose-dependent manner. Peak N1 virtually disappeared at 150 mg/kg. Peak P2 amplitude increased by 50%, but only in the light background, and only at 150 mg/kg. Second, ketamine (150 mg/kg) effects on FEPs were investigated 5 min and 30 min following administration. The decrease in peak N1 amplitude was maximal 5 min after administration and the amplitude was recovering at 30 min. The effects on peak P1 and peak N3 amplitudes were maximal 5 min after ketamine administration, but were not recovering 30 min postinjection. The various peak latencies were also affected differently. The possible role of glutamate or aspartate in the generation of rat FEPs is discussed.

Effects of LSD on classical conditioning as a function of CS-UCS interval: relationship to reflex facilitation

Classical conditioning of the rabbit nictitating membrane response was accomplished by presenting a 100-msec tone CS at intervals 0, 100, 200, 400 and 800 msec before the presentation of a 100-msec shock UCS. In addition, tone-alone trials were used to monitor CR acquisition and shock-alone trials to measure facilitation of the nictitating membrane reflex by the tone CS at the various CS-UCS intervals. LSD at a dose of 13 micrograms/kg (30 nmol/kg) increased the excitatory effects of the shock UCS as measured by a greater frequency and amplitude of UCRs elicited across a wide range of UCS intensities and by the ability of a low intensity shock to produce reflex facilitation. Consequently, LSD produced a higher amplitude of UCRs on UCS-alone trials and on paired trials across all CS-UCS intervals during measurement of tone-induced reflex facilitation. LSD also enhanced CR acquisition across all CS-UCS intervals. Because LSD produced larger amplitude reference UCRs on the UCS-alone trials as compared with controls, calculations of reflex facilitation as a percentage change from these reference amplitudes led to an artifactually smaller effect for the LSD group as compared with controls. Nevertheless, both reflex facilitation as measured prior to CR acquisition on the first day of conditioning and CR acquisition across 10 conditioning sessions were a function of CS-UCS intervals and these two measures were highly correlated in the LSD (+0.94) and vehicle control (+0.85) groups. It was concluded that LSD enhances CR acquisition by enhancing the excitatory effects of both the CS and UCS and thus increasing their ability to enter into associative learning.

Focal lesions of visual cortex--effects on visual evoked potentials in rats

Focal lesions were placed in the visual cortex of Long-Evans hooded rats, immediately below skull screw recording electrodes. Lesions were produced by heat, and extended an average depth of about 0.9 mm below the cortical surface. Evoked potentials recorded from the electrode overlying the cortical lesion were compared with simultaneously recorded potentials from a contralateral homotopic site. The effects of the lesion were selective. Flash-evoked potential peaks P1, P2, and N2 were depressed by the lesion, and peaks N1 and P3 were augmented; peak N3 was unaffected. Pattern reversal evoked potential peak N3 was depressed by the lesion, and peaks N1 and P2 were made more distinct. The results emphasized that different peaks have different generators, and suggest in particular that flash-evoked potential peaks P1 and N2, and peak N3 of the pattern reversal-evoked potential require the superficial layers of the cortex.

Ontogeny of flash-evoked potentials in unanesthetized rats

The effects of age and stimulation frequency (0.2/sec, 1.0/sec, 2.0/sec, or 4.0/sec) on flash-evoked potentials (FEPs) were investigated in awake, unsedated, unrestrained rats. Animals were tested daily from postnatal day (PND) 8 to PND 20, and every 3 or 4 days thereafter until PND 41. On PND 9, a single negative wave (N1a) was observed following 0.2/sec flash presentation. Animals tested on PND 10 exhibited a positive wave (P2) following the return of peak N1a to baseline. On PND 13 another negative wave (N1) appeared on the leading shoulder of peak N1a. Peak N1 became the dominant negative wave on PND 14. Peak N1a merged into N1 and had disappeared by PND 19. Peak N3 was first observed as a negative shift following peak P2 on PND 15. Peaks N2 and P3 were not observed in the group average waveforms until PND 34. Peak latencies decreased through the fifth postnatal week. Peak amplitudes increased with age until after eye opening (PND 15), but were variable thereafter. No FEPs were observed following higher than 0.2/sec flash presentation until PND 13. Increasing stimulation frequency decreased N1 and P2 peak amplitudes, but had no effect on peak latencies.

Urethane affects the rat visual system at subanesthetic doses

Urethane is an anesthetic which is commonly used in neurophysiological studies because it is presumed to have minimal effects upon neuronal activity. This study investigated the influence of urethane anesthesia upon flash evoked potentials (FEPs) recorded from hooded rats. Subanesthetic dosages (25 g/kg and 0.5 g/kg) and an anesthetic dosage (1.0 g/kg) were administered, and subsequently recorded FEPs were compared to vehicle-injected controls. Urethane produced profound qualitative and quantitative effects upon the FEP. At 0.5 g/kg, the P1 (normal latency = 20 msec) and N1 (normal latency = 30 msec) peaks became unrecognizable. Peak N1 disappeared and peak P1 merged with P2 (normal latency = 45 msec). Peak P2 increased in amplitude by about 100%. The results indicate that in the visual system, urethane has a significant influence upon neuronal activity. Caution should be used in interpreting data obtained from urethane-anesthetized rats.

Visual and auditory evoked potentials in different areas of rat cerebral cortex

Visual and auditory evoked potentials were studied in the occipital, temporal, prefrontal and cingulate areas of the rat cerebral cortex. We found that both prefrontal and cingulate areas can respond to more than one sensory modality. The latencies of the response to light and sound, though slightly longer in these associative areas than in the two primary cortical regions, were still within the range of early sensory evoked responses (i.e. less than 50 ms).

Body temperature-dependent and independent actions of chlordimeform on visual evoked potentials and axonal transport in optic system of rat

Pattern-reversal-evoked potentials (PREPs), flash-evoked potentials (FEPs), rapid axonal transport in the optic system and body temperature were measured in hooded rats, treated with either saline or the formamidine insecticide/acaricide, chlordimeform (CDM). Rats receiving chlordimeform had low body temperatures when housed at standard laboratory room temperature, 22 degrees C, but not at 30 degrees C. Peak latencies of flash-evoked potentials were prolonged by chlordimeform at 22 degrees C, but not at 30 degrees C. The rate of axonal transport was slowed in chlordimeform-treated hypothermic rats, but not in chlordimeform-treated warmed rats. These findings suggest that the flash-evoked potential and axonal transport changes produced by chlordimeform were an indirect consequence of hypothermia. In contrast, chlordimeform increased pattern-reversal evoked potential peak latencies and peak-to-peak amplitudes independent of body temperature. These findings confirm and extend previous reports of chlordimeform-induced hypothermia, emphasize the importance of changes in body temperature as a possible confounding factor in studies of neuroactive agents and demonstrate that chlordimeform has both body-temperature-dependent and independent actions in the visual system in the rat.

Chlordimeform produces contrast-dependent changes in visual evoked potentials of hooded rats

Previous experiments found that acute exposure to the insecticide/acaricide, chlordimeform (CDM), produced large increases in the amplitude of pattern reversal evoked potentials (PREPs) without changing the amplitude of flash evoked potentials (FEPs) in the same rats (W. K. Boyes and R. S. Dyer, Exp. Neurol. 86: 434-447, 1984). Current work investigated the influence of physical characteristics of the evoking stimuli on the action of CDM. Adult male Long-Evans rats with epidural visual cortex electrodes were used. In experiment 1, PREPs were elicited with alternating gratings having equal contrast (99%) and a square wave spatial luminance profile at several spatial frequencies. Rats treated 1 h previously with 40 mg/kg CDM had increased PREP amplitudes at 0.1, 0.2, and 0.4 cycles per degree (cpd), but not at 0.8 cpd. No changes were found after 5 mg/kg CDM. In experiment 2, PREPs were elicited with gratings oriented at 0 degrees (horizontal), 45 degrees, 90 degrees, or 135 degrees. Treatment with 40 mg/kg CDM increased PREP amplitudes and latencies regardless of orientation. In experiment 3, FEPs elicited with strobe flashes spanning four log units of intensity showed a small but significant CDM dose X intensity interaction on P2N2 peak-to-peak amplitude. In experiment 4, PREPs were elicited with alternating gratings having a sinusoidal spatial luminance profile, spatial frequency of 0.2 or 0.8 cpd, and contrast ranging from noise levels to 65%. Rats treated with 40 mg/kg CDM showed increased peak-to-peak amplitudes only at 0.2 cpd and only at contrast values above 10%. The failure of CDM to alter PREPs at 0.8 cpd was attributed to low contrast sensitivity at that spatial frequency. The results demonstrated that the action of CDM on visual evoked potentials was dependent on the amount of contrast in the stimulus pattern, and suggested that CDM alters the encoding of visual contrast.

Chlordimeform produces profound, selective, and transient changes in visual evoked potentials of hooded rats

Rat visual function was tested after acute exposure to chlordimeform (CDM), a formamidine insecticide/acaricide. Adult male Long-Evans rats were surgically implanted with epidural recording electrodes overlying visual cortex and tested 1 week later. Pattern reversal-evoked potentials (PREPs), flash-evoked potentials (FEPs), and FEP recovery ratios were measured after acute CDM administration. Averaged recordings obtained during 200 reversals of a black-and-white square wave grating comprised the PREPs, and those obtained during 128 paired strobe lamp flashes comprised the FEPs. In the first study, which examined dose-response relationships, i.p. injections of 0 (saline), 5, 15, or 40 mg/kg CDM-HCl were administered 30 min prior to testing. The PREP amplitudes showed large dose-related changes in the CDM-treated rats. PREP N1P1 and P1N3 peak-to-peak amplitudes increased more than 200% in the 40 mg/kg group. In contrast, FEP amplitudes and FEP recovery ratios were unchanged by CDM. Both PREP and FEP peak latencies were increased by CDM in dose-related fashions. In the second study, which examined the time course of CDM action, PREPs and paired-pulse FEPs were recorded 3, 6, and 24 h after dosage with either 0 or 40 mg/kg CDM. All evoked potential changes were large at 3 and 6 h, but had returned to control values by 24 h. In summary, acute exposure to CDM temporarily increased both the amplitude and latency of PREPs, but only the latency of FEPs.

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.