Sensory gating in a computer model of the CA3 neural network of the hippocampus

Differential modulation of the auditory steady state response and inhibitory gating by chloral hydrate anesthesia

Auditory steady state response (ASSR) and inhibitory gating (IG) are electrophysiological examinations commonly used to evaluate the sensory and cognitive functions of the brain. In some clinic examinations and animal experiments, general anesthesia is necessary to conduct electrophysiological recordings. However, the effects of anesthesia on ASSR and IG remain unclear. For this reason, we recorded local field potentials though electrodes implanted in different brain areas of rats: the auditory cortex (AC), hippocampus (HC), amygdala (AMY), and prefrontal cortex (PFC), and compared the characteristics of ASSR and IG under anesthetized and conscious conditions. We found that ASSR signals were the strongest in the AC, and decreased sequentially in the HP, AMY, and PFC. Chloral hydrate anesthesia significantly reduced the power and phase-locking of ASSR in the AC, HP, and AMY. In contrast, the extent of IG in the AC was weakest and it increased sequentially in the HP, AMY, and PFC. Anesthesia had less effect on the extent of IG. Our results suggest that ASSR and IG may originate from different neural circuits and that IG is more resistant to general anesthesia and therefore better suited to examining the functioning of non-auditory brain regions.

Histological correlates of N40 auditory evoked potentials in adult rats after neonatal ventral hippocampal lesion: animal model of schizophrenia

The neonatal ventral hippocampal lesion (NVHL) is an established neurodevelopmental rat model of schizophrenia. Rats with NVHL exhibit several behavioral, molecular and physiological abnormalities that are similar to those found in schizophrenics. Schizophrenia is a severe psychiatric illness characterized by profound disturbances of mental functions including neurophysiological deficits in brain information processing. These deficits can be assessed by auditory evoked potentials (AEPs), where schizophrenics exhibit abnormalities in amplitude, duration and latency of such AEPs. The aim of the present study was to compare the density of cells in the temporal cerebral cortex and the N40-AEP of adult NVHL rats versus adult sham rats. We found that rats with NVHL exhibit significant lower amplitude of the N40-AEP and a significant lower number of cells in bilateral regions of the temporal cerebral cortex compared to sham rats. Because the AEP recordings were obtained from anesthetized rats, we suggest that NVHL leads to inappropriate innervation in thalamic-cortical pathways in the adult rat, leading to altered function of cortical networks involved in processing of primary auditory information.

Auditory evoked potential P50 as a predictor of neurologic outcome in resuscitated cardiac arrest patients

In general, a prediction of neurologic outcome with respect to the resuscitated cardiac arrest patients has been performed by the auditory brainstem response and somatic evoked potential. The auditory brainstem response and somatic evoked potential are known as the predictors that correspond to neurologically poor outcome. None of the methods have been established to access neurologically good outcome. Because the hippocampal CA3 pyramidal cells have been widely used for pathophysiologic analyses concerning the hypoxic-ischemic encephalopathy and also the source of P50 components of the auditory evoked potential has been considered to be the hippocampal CA3 pyramidal cells, the authors assume that it might be possible that neurologic outcome in resuscitated cardiac arrest patients would be predicted by evaluating the P50 components. The purpose was to examine the P50 as a predictor of neurologic outcome in resuscitated cardiac arrest patients at the early stage from the onset. The P50 components of the auditory evoked potential are recorded in a conditioning-testing paradigm, that is, EEG responses to a pair of auditory stimuli with 500-millisecond interclick interval. In this study, subjects are 10 out-of-hospital cardiac arrest patients, 8 men and 2 women with a mean age of 54.8 years, who were admitted to the intensive care unit after the return of spontaneous circulation, with the presence of both the auditory brainstem response wave V and the somatic evoked potential wave N20 between the period from June 2008 to July 2009. It was found that the presence of the P50 at the early stage from the onset (days 5 ± 1.20) indicates good neurologic outcome, while the absence of the P50 implies poor prognosis. As to the auditory sensory gating of the P50, almost no reduction response to the second stimulus was observed. As a consequence, the evaluation of the P50 in resuscitated cardiac arrest patients would have a possibility to predict neurologically good outcome.

A neural network model of normal and abnormal auditory information processing

The ability of the brain to attenuate the response to irrelevant sensory stimulation is referred to as sensory gating. A gating deficiency has been reported in schizophrenia. To study the neural mechanisms underlying sensory gating, a neuroanatomically inspired model of auditory information processing has been developed. The mathematical model consists of lumped parameter modules representing the thalamus (TH), the thalamic reticular nucleus (TRN), auditory cortex (AC), and prefrontal cortex (PC). It was found that the membrane potential of the pyramidal cells in the PC module replicated auditory evoked potentials, recorded from the scalp of healthy individuals, in response to pure tones. Also, the model produced substantial attenuation of the response to the second of a pair of identical stimuli, just as seen in actual human experiments. We also tested the viewpoint that schizophrenia is associated with a deficit in prefrontal dopamine (DA) activity, which would lower the excitatory and inhibitory feedback gains in the AC and PC modules. Lowering these gains by less than 10% resulted in model behavior resembling the brain activity seen in schizophrenia patients, and replicated the reported gating deficits. The model suggests that the TRN plays a critical role in sensory gating, with the smaller response to a second tone arising from a reduction in inhibition of TH by the TRN.

Probing the relative contribution of the first and second responses to sensory gating indices: a meta-analysis

Sensory gating deficit in schizophrenia patients has been well-documented. However, a central conceptual issue, regarding whether the gating deficit results from an abnormal initial response (S1) or difficulty in attenuating the response to the repeating stimulus (S2), raise doubts about the validity and utility of the S2/S1 ratio as a measure of sensory gating. This meta-analysis study, therefore, sought to determine the consistency and relative magnitude of the effect of the two essential components (S1 and S2) and the ratio. The results of weighted random effects meta-analysis revealed that the overall effect sizes for the S1 amplitude, S2 amplitude, and P50 S2/S1 ratio were -0.19 (small), 0.65 (medium to large), and 0.93 (large), respectively. These results confirm that the S2/S1 ratio and the repeating (S2) stimulus differ robustly between schizophrenia patients and healthy controls in contrast to the consistent but smaller effect size for the S1 amplitude. These findings are more likely to reflect defective inhibition of repeating redundant input rather than an abnormal response to novel stimuli.

Auditory gating in rat hippocampus and medial prefrontal cortex: effect of the cannabinoid agonist WIN55,212-2

Sensory gating can be assessed in rodents and humans using an auditory conditioning (C)-test (T) paradigm, with schizophrenic patients exhibiting a loss of gating. Dysregulation of the endocannabinoid system has been proposed to be involved in the pathogenesis of schizophrenia. We studied auditory gating and the effects of the cannabinoid agonist WIN55,212-22 on gating in CA3 and dentate gyrus (DG) of the hippocampus and medial prefrontal cortex (mPFC) in male Lister hooded rats using in vivo electrophysiology. The effects of a single dose of WIN55,212-2 on the N2 local field potential (LFP) test/conditioning amplitude ratios (T/C ratio) and response latencies were examined. In rats that demonstrated gating of N2, mPFC showed higher T/C ratios and shorter conditioning response latencies compared to DG and CA3. WIN55,212-2 disrupted auditory gating in all three areas with a significant increase in test amplitudes in the gating rats. A group of non-gating rats demonstrated higher test amplitudes and higher T/C ratios compared to gating rats. WIN55,212-2 had no effect on T/C ratios in the non-gating rats. The cannabinoid receptor (CB1) antagonist SR141716A prevented WIN55,212-2 induced disruption of gating. This study demonstrates gated auditory-evoked responses in CA3, DG and mPFC. The mPFC showed an early phase of gating which may later be modulated by CA3 and DG activity. Furthermore, cannabinoid receptor activation disrupted auditory gating in CA3, DG and mPFC, an effect which was prevented by CB1 receptor antagonism. The results further demonstrate the presence of a non-gating rat population which responded differently to cannabinoid agonists.

Sensory gating and its modulation by cannabinoids: electrophysiological, computational and mathematical analysis

Gating of sensory information can be assessed using an auditory conditioning-test paradigm which measures the reduction in the auditory evoked response to a test stimulus following an initial conditioning stimulus. Recording brainwaves from specific areas of the brain using multiple electrodes is helpful in the study of the neurobiology of sensory gating. In this paper, we use such technology to investigate the role of cannabinoids in sensory gating in the CA3 region of the rat hippocampus. Our experimental results show that application of the exogenous cannabinoid agonist WIN55,212-2 can abolish sensory gating. We have developed a phenomenological model of cannabinoid dynamics incorporated within a spiking neural network model of CA3 with synaptically interacting pyramidal and basket cells. Direct numerical simulations of this model suggest that the basic mechanism for this effect can be traced to the suppression of inhibition of slow GABA(B) synapses. Furthermore, by working with a simpler mathematical firing rate model we are able to show the robustness of this mechanism for the abolition of sensory gating.

Development and gender in the P50 paradigm

OBJECTIVE

The relative change in amplitude of the P50 component in response to the second click compared to the first one is commonly thought to index sensory gating. Despite numerous P50 gating studies, reports about its development are scarce. The present study examined the development and gender differences of P50 sensory gating.

METHODS

A standard P50 paradigm was used to study sensory gating in adults (N=31) and in children aged 10-12 years (N=29), 8-9 years (N=26) and 5-7 years (N=26).

RESULTS

The speed of processing and the frontocentral scalp distribution in P50 sensory gating are already mature at the age of 5 years. However, children of 5-7 years of age had smaller amplitudes to the first response and showed less sensory gating compared to the older age groups. No gender differences were found.

CONCLUSIONS

Sensory gating matures around the age of 8 years.

SIGNIFICANCE

The current data help in evaluating whether abnormal P50 sensory gating is due to maturational delay. There is no need to take into account gender differences.

Effects of acute and chronic clozapine on D-amphetamine-induced disruption of auditory gating in the rat

RATIONALE

Auditory gating deficits observed in patients with schizophrenia have been modeled in animals administered the indirect-acting monoaminergic agonist, D-amphetamine (AMPH). The atypical antipsychotic drug clozapine (CLOZ) reverses the disruption of auditory gating in schizophrenic patients. However, its effects on psychostimulant-induced deficits in animals have yet to be assessed.

OBJECTIVES

In the present series of experiments, an auditory evoked potential paradigm was used to: (a) confirm the ability of AMPH to alter auditory gating in the anesthetized rat, (b) specify the nature of the accompanying change(s) in evoked potential waveforms and (c) determine the effects of CLOZ administration on AMPH-induced alterations in auditory gating.

METHODS

We compared the effects of acute (5 mg/kg, i.p.) and chronic (28 days, 0.5 mg/ml in drinking water) CLOZ on AMPH-induced (1.8 mg/kg, i.p.) alterations in evoked potentials recorded in the hippocampus of anesthetized rats during presentation of a pair of identical tones. Gating was assessed by comparing the amplitude of conditioning and test responses in CLOZ and AMPH-treated rats.

RESULTS

The ratio of test to conditioning response amplitude (T/C ratio) was not altered by vehicle or CLOZ alone. However, T/C ratio was significantly increased following AMPH due to suppression of the conditioning response. Acute but not chronic CLOZ attenuated but did not prevent the increase in T/C ratio.

CONCLUSIONS

Qualitative differences between the idiopathic gating deficits observed in schizophrenic patients and AMPH-induced increases in T/C ratio in animals limit this models utility as a means of evaluating the ability of atypical antipsychotic drugs to restore normal sensory gating.

The role of hippocampal theta activity in sensory gating in the rat

Sensory gating is defined as a decreased reaction on the second click, measured as evoked potentials (EP) within a double click paradigm. Recently, it was established that gating in rats was decreased during REM sleep compared to wakefulness and non-REM sleep. REM sleep in the rat is characterized by hippocampal theta rhythm. Therefore, it was investigated whether sensory gating would also be diminished during other states with hippocampal theta. Twelve Wistar rats were implanted with hippocampal electrodes and exposed to double clicks during passive wakefulness, REM sleep, and activity (voluntary movements and walking on a moving belt). Gating was examined by use of the amplitudes of the EPs in reaction to the first conditioned amplitude (CAMP) and second click test amplitude (TAMP), as well as two gating parameters (C-T score and T/C ratio). Except passive wakefulness all behavioral conditions were accompanied by hippocampal theta. Normal gating was always found, except during REM sleep. The CAMP was than lower than during passive wakefulness. Gating was less disturbed during behavioral activity. Negative correlations were found between the percentage theta power on the one side and the CAMP, respectively, the C-T score, on the other. The correlation between the percentage theta power and the T/C ratio was also significant. It is concluded that the presence of hippocampal theta is not a sufficient condition to cause disturbances in auditory sensory gating. Behavioral states that accompany theta activity, however, tend to affect the CAMP. The decrease in gating found during REM sleep cannot be easily related to well-known neurochemical and pharmacological data.

Associations of P50 suppression and desensitization with perceptual and cognitive features of "unreality" in schizotypy

BACKGROUND

P50 suppression is an electrophysiologic index of early sensory gating and has consistently been found deficient in schizophrenic patients. This gating deficit is thought to lead to sensory overload and cognitive fragmentation, and correspondingly many symptoms of the disorder. However, the link between P50 suppression deficits and symptomatology is yet to be established, and so this study was designed to determine whether such a relation is present within a nonclinical population.

METHODS

P50 suppression and schizotypy measures were obtained from 36 healthy volunteers, and correlation analyses determined whether measures of schizotypy were related to P50 suppression.

RESULTS

Consistent with the view that P50 gating deficits are related to schizophrenic symptoms, subjects with poorer P50 suppression reported more perceptual anomalies and magical ideation--an unreality syndrome--in contrast to other positive symptoms and to withdrawal. This study also found a trend to P50 suppression desensitization, and that whereas subjects low on "unreality" demonstrated desensitization to the second of the paired clicks, subjects high on "unreality" demonstrated sensitization.

CONCLUSIONS

It is concluded that early sensory gating deficits, in the form of poor P50 suppression, are related to unreality aspects of schizotypy. This supports the view that poor P50 suppression in schizophrenia is related to symptomatology.