Andrew D. Powell

Sensitivity of coherent oscillations in rat hippocampus to AC electric fields

The sensitivity of brain tissue to weak extracellular electric fields is important in assessing potential public health risks of extremely low frequency (ELF) fields, and potential roles of endogenous fields in brain function. Here we determine the effect of applied electric fields on membrane potentials and coherent network oscillations. Applied DC electric fields change transmembrane potentials in CA3 pyramidal cell somata by 0.18 mV per V m−1 applied. AC sinusoidal electric fields have smaller effects on transmembrane potentials: sensitivity drops as an exponential decay function of frequency. At 50 and 60 Hz it is ∼0.4 that for DC fields. Effects of fields of ≤ 16 V m−1 peak‐to‐peak (p‐p) did not outlast application. Kainic acid (100 nm) induced coherent network oscillations in the beta and gamma bands (15–100 Hz). Applied fields of ≥ 6 V m−1 p‐p (2.1 V m−1 r.m.s.) shifted the gamma peak in the power spectrum to centre on the applied field frequency or a subharmonic. Statistically significant effects on the timing of pyramidal cell firing within the oscillation appeared at distinct thresholds: at 50 Hz, 1 V m−1 p‐p (354 mV m−1 r.m.s.) had statistically significant effects in 71% of slices, and 0.5 V m−1 p‐p (177 mV m−1 r.m.s.) in 20%. These threshold fields are consistent with current environmental guidelines. They correspond to changes in somatic potential of ∼70 μV, below membrane potential noise levels for neurons, demonstrating the emergent properties of neuronal networks can be more sensitive than measurable effects in single neurons.

High-Frequency Network Activity, Global Increase in Neuronal Activity, and Synchrony Expansion Precede Epileptic Seizures In Vitro

How seizures start is a major question in epilepsy research. Preictal EEG changes occur in both human patients and animal models, but their underlying mechanisms and relationship with seizure initiation remain unknown. Here we demonstrate the existence, in the hippocampal CA1 region, of a preictal state characterized by the progressive and global increase in neuronal activity associated with a widespread buildup of low-amplitude high-frequency activity (HFA) (>100 Hz) and reduction in system complexity. HFA is generated by the firing of neurons, mainly pyramidal cells, at much lower frequencies. Individual cycles of HFA are generated by the near-synchronous (within ∼5 ms) firing of small numbers of pyramidal cells. The presence of HFA in the low-calcium model implicates nonsynaptic synchronization; the presence of very similar HFA in the high-potassium model shows that it does not depend on an absence of synaptic transmission. Immediately before seizure onset, CA1 is in a state of high sensitivity in which weak depolarizing or synchronizing perturbations can trigger seizures. Transition to seizure is characterized by a rapid expansion and fusion of the neuronal populations responsible for HFA, associated with a progressive slowing of HFA, leading to a single, massive, hypersynchronous cluster generating the high-amplitude low-frequency activity of the seizure.

Epileptic high-frequency network activity in a model of non-lesional temporal lobe epilepsy

High-frequency cortical activity, particularly in the 250–600 Hz (fast ripple) band, has been implicated in playing a crucial role in epileptogenesis and seizure generation. Fast ripples are highly specific for the seizure initiation zone. However, evidence for the association of fast ripples with epileptic foci depends on animal models and human cases with substantial lesions in the form of hippocampal sclerosis, which suggests that neuronal loss may be required for fast ripples. In the present work, we tested whether cell loss is a necessary prerequisite for the generation of fast ripples, using a non-lesional model of temporal lobe epilepsy that lacks hippocampal sclerosis. The model is induced by unilateral intrahippocampal injection of tetanus toxin. Recordings from the hippocampi of freely-moving epileptic rats revealed high-frequency activity (>100 Hz), including fast ripples. High-frequency activity was present both during interictal discharges and seizure onset. Interictal fast ripples proved a significantly more reliable marker of the primary epileptogenic zone than the presence of either interictal discharges or ripples (100–250 Hz). These results suggest that fast ripple activity should be considered for its potential value in the pre-surgical workup of non-lesional temporal lobe epilepsy.

Alterations in Ca2+-buffering in prion-null mice: association with reduced afterhyperpolarizations in CA1 hippocampal neurons.

Prion protein (PrP) is a normal component of neurons, which confers susceptibility to prion diseases. Despite its evolutionary conservation, its normal function remains controversial. PrP-deficient (Prnp0/0 ) mice have weaker afterhyperpolarizations (AHPs) in cerebellar and hippocampal neurons. Here we show that the AHP impairment in hippocampal CA1 pyramidal cells is selective for the slow AHP, and is not caused by an impairment of either voltage-gated Ca2+ channels or Ca2+-activated K+ channels. Instead, Prnp0/0 neurons have twofold to threefold stronger Ca2+ buffering and double the Ca2+ extrusion rate. In Prnp0/0 neurons thapsigargin abolished the stronger Ca2+ buffering and extrusion, and thapsigargin or cyclopiazonic acid abolished the weakening of the slow AHPs. These data implicate sarcoplasmic/endoplasmic reticulum calcium ATPase in the enhanced Ca2+ buffering, and extrusion into the endoplasmic reticulum, which contains substantial amounts of PrP in wild-type mice. Altered Ca2+ homeostasis can explain several phenotypes identified in Prnp0/0 mice.

Rapid reversal of impaired inhibitory and excitatory transmission but not spine dysgenesis in a mouse model of mental retardation

Non‐technical summary  Intellectual disability has long been attributed at the cellular level to abnormalities in the structures that receive incoming connections to the major classes of neurons in the brain. These misshaped ‘dendrites’ and especially misshaped ‘dendritic spines’ have been found in many types of intellectual disability. We have used a mouse model of one of the human intellectual disability mutations on a gene on the X‐chromosome called Ophn‐1. We show that, in addition to the misshaped dendritic spines, these mice have abnormal physiology in the inability of both excitatory and inhibitory inputs (‘synapses’) to operate repetitively as they need to in many aspects of normal brain function. A drug known as a Rho‐GAP inhibitor was able to reverse the physiological impairment within 20 min, without changing the structure of dendrites or dendritic spines. This class of drug may have a role in limiting disability in this condition.

Effect of ageing on CA3 interneuron sAHP and gamma oscillations is activity-dependent

Normal ageing-associated spatial memory impairment has been linked to subtle changes in the hippocampal network. Here we test whether the age-dependent reduction in gamma oscillations can be explained by the changes in intrinsic properties of hippocampal interneurons. Kainate-induced gamma oscillations, but not spontaneous gamma oscillations, were reduced in slices from aged mice. CA3 interneurons were recorded in slices from young and aged mice using Fura-2-filled pipettes. Passive membrane properties, firing properties, medium- and slow-afterhyperpolarisation amplitudes, basal [Ca(2+)](i) and firing-induced [Ca(2+)](i) transients were not different with ageing. Kainate caused a larger depolarisation and increase in [Ca(2+)](i) signal in aged interneurons than in young ones. In contrast to young interneurons, kainate increased the medium- and slow-afterhyperpolarisation and underlying [Ca(2+)](i) transient in aged interneurons. Modulating the slow-afterhyperpolarisation by modulating L-type calcium channels with BAY K 8644 and nimodipine suppressed and potentiated, respectively, kainate-induced gamma oscillations in young slices. The age-dependent and stimulation-dependent increase in basal [Ca(2+)](i), firing-induced [Ca(2+)](i) transient and associated afterhyperpolarisation may reduce interneuron excitability and contribute to an age-dependent impairment of hippocampal gamma oscillations.

Effects of direct brain stimulation depend on seizure dynamics.

Brain stimulation is currently used as an experimental treatment for patients with medically refractory epilepsy. However, the results of such stimulation are still less than optimal. A major factor is the lack of understanding of the mechanisms of applied stimuli. Herein we review evidence on the effects of stimulation in models of epileptic seizures. We show that the effects of stimulation during epileptic seizures can differ from those observed under normal conditions. Several studies suggest a potentially greater beneficial therapeutic effect of strong depolarizing and overactivating stimulations than hyperpolarizing ones in the treatment of seizures. The potential relevance of these results to other therapeutic stimulation protocols is discussed.

Electrographic high-frequency activity and epilepsy.

High-frequency electrographic activity (HFA) has a frequency of 80-600Hz. It can be observed interictally in epileptic foci and also at the onset of epileptic seizures. There are several hypotheses about how HFA is generated, and it has been suggested that the underlying mechanisms may play an important role in epileptogenesis and ictogenesis. The high specificity of HFA for epileptic foci is now used during presurgical evaluation to help localize epileptic focus. In this article we review the current state of knowledge regarding this phenomenon and challenges for the future studies focusing on HFA.

A New Approach of Modified Submerged Patch Clamp Recording Reveals Interneuronal Dynamics during Epileptiform Oscillations

Highlights Simultaneous epileptiform LFPs and single-cell activity can be recorded in the membrane chamber. Interneuron firing can be linked to epileptiform high frequency activity. Fast ripples, unique to chronic epilepsy, can be modeled in ex vivo tissue from TeNT-treated rats. Traditionally, visually-guided patch clamp in brain slices using submerged recording conditions has been required to characterize the activity of individual neurons. However, due to limited oxygen availability, submerged conditions truncate fast network oscillations including epileptiform activity. Thus, it is technically challenging to study the contribution of individual identified neurons to fast network activity. The membrane chamber is a submerged-style recording chamber, modified to enhance oxygen supply to the slice, which we use to demonstrate the ability to record single-cell activity during in vitro epilepsy. We elicited epileptiform activity using 9 mM potassium and simultaneously recorded from fluorescently labeled interneurons. Epileptiform discharges were more reliable than in standard submerged conditions. During these synchronous discharges interneuron firing frequency increased and action potential amplitude progressively decreased. The firing of 15 interneurons was significantly correlated with epileptiform high frequency activity (HFA; ~100–500 Hz) cycles. We also recorded epileptiform activity in tissue prepared from chronically epileptic rats, treated with intrahippocampal tetanus neurotoxin. Four of these slices generated fast ripple activity, unique to chronic epilepsy. We showed the membrane chamber is a promising new in vitro environment facilitating patch clamp recordings in acute epilepsy models. Further, we showed that chronic epilepsy can be better modeled using ex vivo brain slices. These findings demonstrate that the membrane chamber facilitates previously challenging investigations into the neuronal correlates of epileptiform activity in vitro.

Reduced Gamma Oscillations in a Mouse Model of Intellectual Disability: A Role for Impaired Repetitive Neurotransmission?

Intellectual disability affects 2–3% of the population; mutations of the X-chromosome are a major cause of moderate to severe cases. The link between the molecular consequences of the mutation and impaired cognitive function remains unclear. Loss of function mutations of oligophrenin-1 (OPHN1) disrupt Rho-GTPase signalling. Here we demonstrate abnormal neurotransmission at CA3 synapses in hippocampal slices from Ophn1 -/y mice, resulting from a substantial decrease in the readily releasable pool of vesicles. As a result, synaptic transmission fails at high frequencies required for oscillations associated with cognitive functions. Both spontaneous and KA-induced gamma oscillations were reduced in Ophn1 -/y hippocampal slices. Spontaneous oscillations were rapidly rescued by inhibition of the downstream signalling pathway of oligophrenin-1. These findings suggest that the intellectual disability due to mutations of oligophrenin-1 results from a synaptopathy and consequent network malfunction, providing a plausible mechanism for the learning disabilities. Furthermore, they raise the prospect of drug treatments for affected individuals.