Do distance-delivery group interventions improve depression in people with epilepsy?

About one-third of people with epilepsy experience comorbid depression. The present study examined outcomes of a distance-delivery group intervention program designed to improve emotional well-being. Participants were 55 adults with epilepsy and self-reported depressive symptoms who were randomly assigned to take part in either a mindfulness-based cognitive behavioral therapy (CBT) program (UPLIFT, n = 20), an epilepsy information and self-management program (EpINFO, n = 24) that served as an active control group, or a wait-list control (WLC) group (n = 11). The Quick Inventory of Depressive Symptomatology (QIDS), Neurological Disorders Depression Inventory for Epilepsy (NDDIE), and the psychological health subscale of the World Health Organization Quality of Life (WHOQOL-BREF) scale were used to assess depression and psychological quality of life before and after treatment, and at short-term (six months) and long-term follow-up (one year) upon program completion. From pre- to posttreatment, a main effect of time was found, with participants in both the UPLIFT and EpINFO groups having reported to a similar degree a significant decrease in depressive symptoms and improved psychological health, improvements that were not seen in the WLC group. The time by group interaction effect was not significant. The effects seen at posttreatment in the UPLIFT and EpINFO groups remained at six months and one year after treatment. These data suggest that distance-delivery group intervention programs are effective at improving depression and psychological quality of life, with the EpINFO program offering benefits similar to the UPLIFT program.

Regulating hippocampal hyperexcitability through GABAB Receptors.

Abstract Disturbances of GABAergic inhibition are a major cause of epileptic seizures. GABA exerts its actions via ionotropic GABAA receptors and metabotropic G protein-coupled GABAB receptors. Malfunction of GABAA inhibition has long been recognized in seizure genesis but the role of GABAB receptors in controlling seizure activity is still not well understood. Here, we examined the anticonvulsive, or inhibitory effects, of GABAB receptors in a mouse model of hippocampal kindling as well as mouse hippocampal slices through the use of GS 39783, a positive allosteric GABAB receptor modulator, and CGP 55845, a selective GABAB receptor antagonist. When administered via intraperitoneal injections in kindled mice, GS 39783 (5 mg/kg) did not attenuate hippocampal EEG discharges, but did reduce aberrant hippocampal spikes, whereas CGP 55845 (10 mg/kg) prolonged hippocampal discharges and increased spike incidences. When examined in hippocampal slices, neither GS 39783 at 5 µmol/L nor the GABAB receptor agonist baclofen at 0.1 µmol/L alone significantly altered repetitive excitatory field potentials, but GS 39783 and baclofen together reversibly abolished these field potentials. In contrast, CGP 55845 at 1 µmol/L facilitated induction and incidence of these field potentials. In addition, CGP 55845 attenuated the paired pulse depression of CA3 population spikes and increased the frequency of EPSCs in individual CA3 pyramidal neurons. Collectively, these data suggest that GABABB receptors regulate hippocampal hyperexcitability by inhibiting CA3 glutamatergic synapses. We postulate that positive allosteric modulation of GABAB receptors may be effective in reducing seizure-related hyperexcitability.

A reliable method for intracranial electrode implantation and chronic electrical stimulation in the mouse brain.

BACKGROUND: Electrical stimulation of brain structures has been widely used in rodent models for kindling or modeling deep brain stimulation used clinically. This requires surgical implantation of intracranial electrodes and subsequent chronic stimulation in individual animals for several weeks. Anchoring screws and dental acrylic have long been used to secure implanted intracranial electrodes in rats. However, such an approach is limited when carried out in mouse models as the thin mouse skull may not be strong enough to accommodate the anchoring screws. We describe here a screw-free, glue-based method for implanting bipolar stimulating electrodes in the mouse brain and validate this method in a mouse model of hippocampal electrical kindling. METHODS: Male C57 black mice (initial ages of 6-8 months) were used in the present experiments. Bipolar electrodes were implanted bilaterally in the hippocampal CA3 area for electrical stimulation and electroencephalographic recordings. The electrodes were secured onto the skull via glue and dental acrylic but without anchoring screws. A daily stimulation protocol was used to induce electrographic discharges and motor seizures. The locations of implanted electrodes were verified by hippocampal electrographic activities and later histological assessments. RESULTS: Using the glue-based implantation method, we implanted bilateral bipolar electrodes in 25 mice. Electrographic discharges and motor seizures were successfully induced via hippocampal electrical kindling. Importantly, no animal encountered infection in the implanted area or a loss of implanted electrodes after 4-6 months of repetitive stimulation/recording. CONCLUSION: We suggest that the glue-based, screw-free method is reliable for chronic brain stimulation and high-quality electroencephalographic recordings in mice. The technical aspects described this study may help future studies in mouse models.