NMDA-dependent phase synchronization between septal and temporal CA3 hippocampal networks.

Increasing evidence suggests that synchronization between brain regions is essential for information exchange and memory processes. However, it remains incompletely known which synaptic mechanisms contribute to the process of synchronization. Here, we investigated whether NMDA receptor-mediated synaptic plasticity was an important player in synchronization between septal and temporal CA3 areas of the rat hippocampus. We found that both the septal and temporal CA3 regions intrinsically generate weakly synchronized δ frequency oscillations in the complete hippocampus in vitro. Septal and temporal oscillators differed in frequency, power, and rhythmicity, but both required GABAA and AMPA receptors. NMDA receptor activation, and most particularly the NR2B subunit, contributed considerably more to rhythm generation at the temporal than the septal region. Brief activation of NMDA receptors by application of extracellular calcium dramatically potentiated the septal-temporal coherence for long durations (>40 min), an effect blocked by the NMDA antagonist AP-5. This long-lasting NMDA-receptor-dependent increase in coherence was also associated with an elevated phase locking of spikes locally and across regions. Changes in coherence between oscillators were associated with increases in phase locking between oscillators independent of oscillator amplitude. Finally, although the septal CA3 rhythm preceded the oscillations in temporal regions in control conditions, this was reversed during the NMDA-dependent enhancement in coherence, suggesting that NMDA receptor activation can change the direction of information flow along the septotemporal CA3 axis. These data demonstrate that plastic changes in communication between septal and temporal hippocampal regions can arise from the NMDA-dependent phase locking of neural oscillators.

Early alterations in hippocampal circuitry and theta rhythm generation in a mouse model of prenatal infection: implications for schizophrenia.

Post-mortem studies suggest that GABAergic neurotransmission is impaired in schizophrenia. However, it remains unclear if these changes occur early during development and how they impact overall network activity. To investigate this, we used a mouse model of prenatal infection with the viral mimic, polyriboinosinic-polyribocytidilic acid (poly I:C), a model based on epidemiological evidence that an immune challenge during pregnancy increases the prevalence of schizophrenia in the offspring. We found that prenatal infection reduced the density of parvalbumin- but not somatostatin-positive interneurons in the CA1 area of the hippocampus and strongly reduced the strength of inhibition early during postnatal development. Furthermore, using an intact hippocampal preparation in vitro, we found reduced theta oscillation generated in the CA1 area. Taken together, these results suggest that redistribution in excitatory and inhibitory transmission locally in the CA1 is associated with a significant alteration in network function. Furthermore, given the role of theta rhythm in memory, our results demonstrate how a risk factor for schizophrenia can affect network function early in development that could contribute to cognitive deficits observed later in the disease.

Maternal infection and fever during late gestation are associated with altered synaptic transmission in the hippocampus of juvenile offspring rats.

Prenatal exposure to infection is known to affect brain development and has been linked to increased risk for schizophrenia. The goal of this study was to investigate whether maternal infection and associated fever near term disrupts synaptic transmission in the hippocampus of the offspring. We used LPS to mimic bacterial infection and trigger the maternal inflammatory response in near-term rats. LPS was administered to rats on embryonic days 15 and 16 and hippocampal synaptic transmission was evaluated in the offspring on postnatal days 20-25. Only offspring from rats that showed a fever in response to LPS were tested. Schaffer collateral-evoked field excitatory postsynaptic potentials (fEPSPs) and fiber volleys in CA1 of hippocampal slices appeared smaller in offspring from the LPS group compared with controls, but, when the fEPSPs were normalized to the amplitude of fiber volleys, they were larger in the LPS group. In addition, intrinsic excitability of CA1 pyramidal neurons was heightened, as antidromic field responses in the LPS group were greater than those from control. Short-, but not long-term plasticity was impaired since paired-pulse facilitation of the fEPSP was attenuated in the LPS group, whereas no differences in long-term potentiation were noted. These results suggest that LPS-induced inflammation during pregnancy produces in the offspring a reduction in presynaptic input to CA1 with compensatory enhancements in postsynaptic glutamatergic response and pyramidal cell excitability. Neurodevelopmental disruption triggered by prenatal infection can have profound effects on hippocampal synaptic transmission, likely contributing to the memory and cognitive deficits observed in schizophrenia.

Effects of flecainide on atrial and ventricular refractoriness in rabbits in vitro and in vivo.

This study compared the in vitro versus in vivo effects of flecainide on effective refractory period (ERP) in atrial and ventricular tissue in rabbits. Flecainide (a class 1c agent) was chosen, on the basis of its known pharmacological profile and antiarrhythmic actions, to provide a reference compound for investigating models that suitably predict the clinical effects of antiarrhythmics. The rabbit models used were those previously described by Lowe et al. (2002) and Leung et al. (2003). ERP was measured as the shortest S1-S2 interval that elicited a second contraction (in vitro) or electrogram (in vivo). Flecainide (1-10 microM) in vitro produced a concentration-dependent increase in ERP. The greatest drug-induced change from pre-drug values in vitro occurred with the highest concentration in atria and ventricles at 4 Hz. The change was 30+/-4 msec (33+/-7%) in atria versus 53+/-8 msec (46+/-10%) in ventricles. In vivo, flecainide (1 - 4 micromol/kg) dose-dependently increased atrial ERP at 2 and 6 Hz. The biggest change was 28+/-17 msec (29+/-16%). However, there was no effect at 4 Hz. In the ventricles, a dose-related increase in ERP was only seen at 4 Hz (26+/-6 msec). Flecainide showed no frequency dependence of action on ERP in any preparation. Flecainide produced adverse effects both in vitro and in vivo. A concentration and frequency-dependent negative inotropic effect was seen in vitro, and dose-related hypotension in vivo. The highest dose (8 micromol/kg i.v.) of flecainide was lethal. Flecainide produced the expected electrophysiological and toxicity profile, both in vitro and in vivo. Despite such findings, the drug is used to terminate and prevent atrial arrhythmias clinically. In conclusion our rabbit models for determining ERP may not be useful in predicting the clinical usefulness of a drug like flecainide.