Epileptiform discharges in the anterior thalamus of epilepsy patients.

Anterior thalamus (ANT) deep-brain stimulation (DBS) is an approved therapy for drug resistant epilepsy. We aimed to identify interictal epileptiform discharges (IED) in the ANT and to investigate their relationship with surface IEDs. Fifteen patients were monitored for two consecutive nights with externalized thalamic leads to analyze the intrathalamic epileptiform activities (TIED). Forty-six % of all contacts were located within the ANT. We found that all the responders had TIEDs within the ANT, while this held true only for 44% of the non-responders. The overall response rate (RR) at 1-year follow-up was 40%, while it was 44% in bilateral ANT hit patients and 45% in epileptic focus side hit. However, in case of TIEDs present in the focus side the RR reached as high as 71%. TIED activity may prove the pathophysiological connection to the seizure focus, and stimulation of this area might have a better suppressing effect on seizures.

Role of anterior thalamic circuitry during sleep.

Increased attention has been paid to the structure and function of anterior nucleus of the thalamus (ANT), since deep brain stimulation (DBS) treatment for epilepsy launched a decade ago. The efficacy of the treatment on seizure count varies patient from patient and we have limited information on the predictors of better outcomes. While the thalamus is considered the key brain region responsible for maintaining sleep, ANT was traditionally not involved in this function. Recent experimental and human data point to a possible role of ANT in sleep processes, although the underlying mechanisms are still ambiguous. Beside evaluating the current knowledge on sleep disturbances experienced during ANT-DBS treatment, the search for valid biomarkers primarily resides on a better understanding of sleep circuits implicating ANT and its subnuclei. Hypothetically better selectivity within the target may increase seizure outcomes and reduce psychiatric and cognitive side effects. Hence, the main scope of this review is to summarize the evidence on the activity measured in the ANT during non-REM and REM sleep. Furthermore, we aim to find shared properties of sleep processes and ANT-related functions examined more thoroughly during wakefulness, such as selective attention and memory.

Prolongation of cortical sleep spindles during hippocampal interictal epileptiform discharges in epilepsy patients.

OBJECTIVE: Memory deficits are frequent among patients with epilepsies affecting the temporal lobe. Hippocampal interictal epileptic discharges (hIEDs), the presumed epileptic exaggeration of sharp wave-ripples (SWRs), are known to contribute to memory dysfunction, but the potential underlying mechanism is unknown. The precise temporal coordination between hippocampal SWRs and corticothalamic spindles during sleep is critical for memory consolidation. Moreover, previous investigation indicated that hIEDs induce neocortical spindlelike oscillation. In the present study, we aimed to assess the influence of hIEDs on neocortical spindles. METHODS: We analyzed the spindle characteristics (duration, amplitude, frequency) of 21 epilepsy patients implanted with foramen ovale (FO) electrodes during a whole night sleep. Scalp sleep spindles were categorized based on their temporal relationship to hIEDs detected on the FO electrodes. Three groups were created: (1) spindles coinciding with hIEDs, (2) spindles "induced" by hIEDs, and (3) spindles without hIED co-occurrence. RESULTS: We found that spindles co-occurring with hIEDs had altered characteristics in all measured properties, lasted longer by 126 ± 48 ms (mean ± SD), and had higher amplitude by 3.4 ± 3.2 µV, and their frequency range shifted toward the higher frequencies within the 13-15-Hz range. Also, hIED-induced spindles had identical oscillatory properties to spindles without any temporal relationships with hIEDs. In more than half of our subjects, clear temporal coherence was revealed between hIEDs and spindles, but the direction of the coupling was patient-specific. SIGNIFICANCE: We investigated the effect of hippocampal IEDs on neocortical spindle activity and found spindle alterations in cases of spindle-hIED co-occurrence, but not in cases of hIED-initiated spindles. We propose that this is a marker of a pathologic process, where IEDs may have direct effect on spindle generation. It could mark a potential mechanism whereby IEDs disrupt memory processes, and also provide a potential therapeutic target to treat memory disturbances in epilepsy.

EEG and ERP biomarkers of Alzheimer's disease: a critical review.

Here we critically review studies that used electroencephalography (EEG) or event-related potential (ERP) indices as a biomarker of Alzheimer's disease. In the first part we overview studies that relied on visual inspection of EEG traces and spectral characteristics of EEG. Second, we survey analysis methods motivated by dynamical systems theory (DST) as well as more recent network connectivity approaches. In the third part we review studies of sleep.  Next, we compare the utility of early and late ERP components in dementia research. In the section on mismatch negativity (MMN) studies we summarize their results and limitations and outline the emerging field of computational neurology. In the following we overview the use of EEG in the differential diagnosis of the most common neurocognitive disorders. Finally, we provide a summary of the state of the field and conclude that several promising EEG/ERP indices of synaptic neurotransmission are worth considering as potential biomarkers. Furthermore, we highlight some practical issues and discuss future challenges as well.

What can DTI tell about early cognitive impairment? - Differentiation between MCI subtypes and healthy controls by diffusion tensor imaging.

Mild cognitive impairment (MCI) gained a lot of interest recently, especially that the conversion rate to Alzheimer Disease (AD) in the amnestic subtype (aMCI) is higher than in the non-amnestic subtype (naMCI). We aimed to determine whether and how diffusion-weighted MRI (DWI) using the diffusion tensor model (DTI) can differentiate MCI subtypes from healthy subjects. High resolution 3D T1W and DWI images of patients (aMCI, n = 18; naMCI, n = 20; according to Petersen criteria) and controls (n = 27) were acquired at 3T and processed using ExploreDTI and SPM. Voxel-wise and region of interest (ROI) analyses of fractional anisotropy (FA) and mean diffusivity (MD) were performed with ANCOVA; MD was higher in aMCI compared to controls or naMCI in several grey and white matter (GM, WM) regions (especially in the temporal pole and the inferior temporal lobes), while FA was lower in WM ROI-s (e.g. left Cingulum). Moreover, significant correlations were identified between verbal fluency, visual and verbal memory performance and DTI metrics. Logistic regression showed that measuring FA of the crus of fornix along GM volumetry improves the discrimination of aMCI from naMCI. Additional information from DWI/DTI aids preclinical detection of AD and may help detecting early non-Alzheimer type dementia, too.

Ictal analgesia in temporal lobe epilepsy - The mechanism of seizure-related burns.

Seizure-related injuries have major impact in the excess mortality and morbidity of epilepsy patients. Experimental data suggest that analgesia may develop during seizures contributing to the severity of seizure-related accidents, especially burns. We aimed to identify those seizure-types that may lead to burn-injuries by seizure-related analgesia. In our tertiary epilepsy centre, we asked 100 epilepsy patients having a history of seizure-related injury, to complete our burn-and-pain questionnaire. Fifty-one patients completed the survey; their epileptology data were collected and those with a seizure-related burn were interviewed. Forty-two out of the 51 patients (82%) had partial epilepsy and 9 (18%) had idiopathic generalised epilepsy. Twenty-six persons (51%) reported decreased pain perception during or after seizures in general. Twelve patients (23%) had suffered one or more seizure-related burn. Five of them fell onto a hot surface or fire accidentally, during generalized tonic-clonic seizures. Seven out of the 12 burnt patients (58%) grasped a hot object or reached into boiling fluid during complex partial seizures; without experiencing-, or reacting in response to pain. These patients had temporal lobe epilepsy, 5 of them had left temporal seizure onset. Our hypothesis based on the circumstantial analysis of our patients' burn-injuries; is that temporal lobe seizures may cause ictal/postictal analgesia. It may be caused by the seizure-related epileptic facilitation of the periaqueductal gray matter; the central pain-inhibiting structure of the brain. Seizure-related endogenous opioid-release my have a contributory role in inhibiting pain-perception. Ictal analgesia warrants better burn-prevention in temporal lobe epilepsy patients. Understanding the mechanism of ictal analgesia and specifying those seizures-types prone to cause it; may help indentifying human pain-inhibiting pathways.