Loránd Eross

Downregulation of the CB1 Cannabinoid Receptor and Related Molecular Elements of the Endocannabinoid System in Epileptic Human Hippocampus

Endocannabinoid signaling is a key regulator of synaptic neurotransmission throughout the brain. Compelling evidence shows that its perturbation leads to development of epileptic seizures, thus indicating that endocannabinoids play an intrinsic protective role in suppressing pathologic neuronal excitability. To elucidate whether long-term reorganization of endocannabinoid signaling occurs in epileptic patients, we performed comparative expression profiling along with quantitative electron microscopic analysis in control (postmortem samples from subjects with no signs of neurological disorders) and epileptic (surgically removed from patients with intractable temporal lobe epilepsy) hippocampal tissue. Quantitative PCR measurements revealed that CB1 cannabinoid receptor mRNA was downregulated to one-third of its control value in epileptic hippocampus. Likewise, the cannabinoid receptor-interacting protein-1a mRNA was decreased, whereas 1b isoform levels were unaltered. Expression of diacylglycerol lipase-α, an enzyme responsible for 2-arachidonoylglycerol synthesis, was also reduced by ∼60%, whereas its related β isoform levels were unchanged. Expression level of N-acyl-phosphatidylethanolamine-hydrolyzing phospholipase D and fatty acid amide hydrolase, metabolic enzymes of anandamide, and 2-arachidonoylglycerols degrading enzyme monoacylglycerol lipase did not change. The density of CB1 immunolabeling was also decreased in epileptic hippocampus, predominantly in the dentate gyrus, where quantitative electron microscopic analysis did not reveal changes in the ratio of CB1-positive GABAergic boutons, but uncovered robust reduction in the fraction of CB1-positive glutamatergic axon terminals. These findings show that a neuroprotective machinery involving endocannabinoids is impaired in epileptic human hippocampus and imply that downregulation of CB1 receptors and related molecular components of the endocannabinoid system may facilitate the deleterious effects of increased network excitability.

Central Neurocytoma with Malignant Course: Neuronal and Glial Differentiation and Craniospinal Dissemination

Central neurocytoma is a benign neuronal tumor of young adults in the lateral cerebral ventricles with characteristic X ray and light microscopic findings. In many respects typical central neurocytoma is reported below, with recurrence in the third month requiring reoperation. Death ensued in the fifth postoperative month. Subsequent histology proved progressive vascular proliferation and increasing, unusual glial differentiation of the neuronal tumor. At autopsy tumorous seeding blocked the liquor circulation. A thin tumorous layer covered the surface of all ventricles, the cerebellum and medulla oblongata. The GFAP positive cells out-numbered the synaptophysin positive ones. Increase of GFAP positivity and vascular proliferation of the central neurocytoma may be alarming signs suggesting a malignant course in addition to the other atypical features.

Loss and reorganization of calretinin-containing interneurons in the epileptic human hippocampus

Calretinin is expressed mainly in interneurons that specialize to innervate either principal cell dendrites or other interneurons in the human hippocampus. Calretinin-containing cells were shown to be vulnerable in animal models of ischaemia and epilepsy. In the human hippocampus, controversial data were published regarding their sensitivity in epilepsy. Therefore we aimed to reveal the fate of this cell type in human epileptic hippocampi. Surgically removed hippocampi of patients with drug-resistant temporal lobe epileptic (n = 44) were examined and compared to control (n = 8) samples with different post-mortem delays. The samples were immunostained for calretinin and the changes in the distribution, density and synaptic target selectivity of calretinin-positive cells were analysed. Control samples with post-mortem delays longer than 8 h resulted in a reduced number of immunolabelled cells compared to controls with short post-mortem delay. The number of calretinin-positive cells in the epileptic tissue was considerably decreased in correlation with the severity of principal cell loss. Preserved cells had segmented and shortened dendrites. Electron microscopic examination revealed that in controls, 23% of the calretinin-positive interneuronal terminals targeted calretinin-positive dendrites, whereas in the epileptic samples it was reduced to 3-5%. The number of contacts between calretinin-positive dendrites also dropped. The present quantitative data suggest that calretinin-containing cells in the human hippocampus are highly vulnerable, thus inhibition mediated by dendritic inhibitory cells and their synchronization by interneuron-specific interneurons may be impaired in epilepsy. We hypothesize that reorganization of the interneuron-selective cells may be implicated in the occurrence of seizures in non-sclerotic patients, where the majority of principal and non-principal cells are preserved.

In vivo laminar electrophysiology co-registered with histology in the hippocampus of patients with temporal lobe epilepsy.

Laminar multiple microelectrodes have been developed to sample cortical and hippocampal activity in animals. If these measurements are adequately co-registered with the anatomy of the region, they can yield important information about its function and structure. In vivo laminar electrophysiological recordings from the human epileptic hippocampus are rare. However, histological and immunohistochemical analyses are widely used to determine the structural changes associated with temporal lobe epilepsy (TLE). Here we present data obtained by a combined approach: intraoperative recording of laminar field potentials, single and multiple unit activity under anesthesia, accompanied by histology and immunohistochemistry from the same hippocampal region of epileptic patients undergoing temporal lobectomy for drug-resistant TLE. The stability of the electrophysiology and the accuracy of its co-registration with histology were tested successfully. We have found large field potential spikes associated with bursting single units in CA1. Intracortical and subdural strip recordings from the lateral temporal cortex showed similar field potential activation patterns. A prominent oscillatory activity was present in the dentate gyrus with highly localized field potential gradient and multiple unit activity. This pattern could be used as a landmark defining the position of the electrode in the hippocampus. Our findings indicate that some aspects of the local and network epileptiform activity in the hippocampal formation are likely preserved under anesthesia. Electrophysiological identification of the functional state of the hippocampus together with its local structural correlates could further enhance our understanding of this disease.

Complex Propagation Patterns Characterize Human Cortical Activity during Slow-Wave Sleep

Cortical electrical activity during nonrapid eye movement (non-REM) sleep is dominated by slow-wave activity (SWA). At larger spatial scales (∼2–30 cm), investigated by scalp EEG recordings, SWA has been shown to propagate globally over wide cortical regions as traveling waves, which has been proposed to serve as a temporal framework for neural plasticity. However, whether SWA dynamics at finer spatial scales also reflects the orderly propagation has not previously been investigated in humans. To reveal the local, finer spatial scale (∼1–6 cm) patterns of SWA propagation during non-REM sleep, electrocorticographic (ECoG) recordings were conducted from subdurally implanted electrode grids and a nonlinear correlation technique [mutual information (MI)] was implemented. MI analysis revealed spatial maps of correlations between cortical areas demonstrating SWA propagation directions, speed, and association strength. Highest correlations, indicating significant coupling, were detected during the initial positive-going deflection of slow waves. SWA propagated predominantly between adjacent cortical areas, albeit spatial noncontinuities were also frequently observed. MI analysis further uncovered significant convergence and divergence patterns. Areas receiving the most convergent activity were similar to those with high divergence rate, while reciprocal and circular propagation of SWA was also frequent. We hypothesize that SWA is characterized by distinct attributes depending on the spatial scale observed. At larger spatial scales, the orderly SWA propagation dominates; at the finer scale of the ECoG recordings, non-REM sleep is characterized by complex SWA propagation patterns.

Outcome of vagus nerve stimulation for epilepsy in Budapest.

Vagus nerve stimulation (VNS) is a nonpharmacologic therapeutic option for patients with intractable epilepsy. Better clinical outcomes were recorded in nonfocal and Lennox‐Gastaut syndrome (LGS). We conducted a 2‐year, open label, prospective study to measure the seizure outcome of 26 VNS patients. The seizure numbers were assessed using clinician’s global impression scale (CGI) and patient diaries. The average seizure reduction was 23% at the first year and 22% at the second year. Seizure reduction was more pronounced among patients with nonfocal than with focal epilepsy. The response rate was 50% at first year and 30% at the second year. The best CGI record for clinically significant improvement was 15% in the LGS group. The only statistically significant result was the reduction of the generalized tonic–clonic seizures (GTCS). The side‐effect profile was good; however, the large number of mild and reversible effects influenced the stimulation parameters and thus probably the effectiveness of the therapy. We suggest that VNS is an optional treatment mostly in cases of therapy‐resistant Lennox‐Gastaut syndrome. Patients with GTCS may experience improvement such as reduction of seizure severity. We conclude that VNS is a safe neuromodulatory treatment, but future developments of neuromodulatory approaches are needed.

Case report of a woman with anti amphiphysin positive stiff person syndrome

Stiff person syndrome is a rare neuroimmunological disease, characterized by severe, involuntary stiffness with superimposed painful muscle spasms, which are worsened by external stimuli. The classical form is associated with high levels of antibodies against glutamic acid decarboxylase. One of the variant forms is associated with antibodies against amphiphysin. This entity is a paraneoplastic syndrome, caused primarily by breast cancer, secondarily by lung cancer. Symptomatic therapy of anti amphiphysin positive stiff person syndrome includes treatment with benzodiazepines and baclofen (including intrathecal baclofen therapy). The effect of immunological therapies is controversial. Treatment of the underlying cancer may be very effective. In this report, we describe a 68 year old female presenting with an unusally rapidly developing anti amphiphysin positive stiff person syndrome, which was associated with breast cancer. Her painful spasms abolished after intrathecal baclofen treatment was initiated. Her condition improved spontaneously and significantly after cancer treatment, which enabled to start her complex rehabilitation and the simultaneous dose reduction of the intrathecal baclofen. The bedridden patient improved to using a rollator walker and the baclofen pump could be removed 18 monthes after breast surgery. This highlights the importance of cancer screening and treatment in anti amphiphysin positive stiff person syndrome cases.

P385 Analysis of EEG correlates during n-back working memory test in epilepsy patients investigated with surface and invasive electrodes

Introduction The brain process of short term storage of multimodal information is called generally as working memory. This is thought to be located in the frontal and parietal lobes, however recent evidences show that the temporal lobe has important function in maintaining short-term and spatial information. Among multiple neuropsychological tests used for short term memory, the N-back test (NBT) has the advantage, that higher values of memory load can be set by increasing the recall distance (value n ). Methods We involved therapy resistant epilepsy patients undergoing video-EEG with scalp and invasive intracranial electrodes for visual and verbal NBT. The stimuli were presented gradually from 0 to 2 backs. The EEG graphs were filtered and averaged, and time-frequency analysis was performed (EEGLAB). Results Verbal NBT showed significant left-sided increase in gamma power, while during visual NBT right-sided gamma power increase was observed. The power correlated with the elevation of memory load. Intracranial data showed less increase in frontal regions compared to temporal. Conclusions Increase of gamma power seemed to be a good psychoneural correlate of memory processes during verbal and visual NBT. It showed appropriate lateralization and correlation with memory load. Based on our preliminary data the role of temporal lobe in short term memory can be hypothesized. We plan to include more patients.

Fractal properties of epileptic local field potentials recorded from different layers of the frontal cortex using a chronically implanted laminar microelectrode in humans

In this study we analyzed monofractal and multifractal properties of epileptic local field potentials recorded from different layers of the frontal cortex. Seven seizures of two patients suffering from drug resistant frontal lobe epilepsy were assessed. We found drastic changes of fractal properties during the seizures. Distinct gradual changes of these properties were present before and after the ictal states. Moreover, laminar characteristics of the estimated measures were observed. Our results might be used to reveal the mechanisms related to the dynamics of epileptic seizures and perhaps to develop a seizure detection/prediction algorithm.