Faculty Bibliography

There is no consensus for the type(s) of treatment(s) that may be effective or ineffective for psychological nonepileptic seizures (PNES). We provided an open-ended group psychotherapy program to 10 patients with PNES, including a disorder-specific psychoeducation treatment component in the first 10 weeks. Seizure frequency and questionnaire responses were examined pre- and posttreatment in all 7 of 10 individuals who completed the majority of the psychoeducational sessions. Four individuals experienced no change in seizure frequency; in three of these this was due to a cessation of events at treatment initiation. Two individuals experienced a decline; and one, an increase, in seizure frequency. Significant decreases were reported in posttraumatic (P=0.003) and dissociative (P=0.04) symptoms and emotionally based coping mechanisms (P=0.03). There was also a trend toward improved quality of life (P=0.07). Experience/expression of anger remained stable. Psychoeducation may be an effective method of treating PNES and may improve coping strategies and reduce PNES-associated psychopathology in some patients. Additional controlled studies on larger samples are needed

Idiopathic generalized epilepsy (IGE) is a common, complex disease with an almost exclusively genetic etiology but with variable phenotypes. Clinically, IGE can be divided into different syndromes. Varying lines of evidence point to the involvement of several interacting genes in the etiology of IGE. We performed a genome scan in 91 families ascertained through a proband with adolescent-onset IGE. The IGEs included juvenile myoclonic epilepsy (JME), juvenile absence epilepsy (JAE), and epilepsy with generalized tonic clonic seizures (EGTCS). Our linkage results support an oligogenic model for IGE, with strong evidence for a locus common to most IGEs on chromosome 18 (lod score 4.4/5.2 multipoint/two-point) and other loci that may influence specific seizure phenotypes for different IGEs: a previously identified locus on chromosome 6 for JME (lod score 2.5/4.2), a locus on chromosome 8 influencing non-JME forms of IGE (lod score 3.8/2.5), and, more tentatively, two newly discovered loci for absence seizures on chromosome 5 (lod scores 3.8/2.8 and 3.4/1.9). Our data also suggest that the genetic classification of different forms of IGE is likely to cut across the clinical classification of these subforms of IGE. We hypothesize that interactions of different combinations of these loci produce the related heterogeneous phenotypes seen in IGE families

Postictal psychosis (PIP) is a common and clinically significant sequela of inpatient epilepsy monitoring. A series of 622 patients with complex partial epilepsy undergoing video-EEG evaluations as candidates for epilepsy surgery were evaluated, by structured psychiatric interview, for individual and family psychiatric histories, depression, anxiety, and features of personality disorders. No patient had psychotic symptoms at baseline. Twenty-nine developed a PIP episode during monitoring. The a priori hypotheses were that patients with PIP would have higher baseline schizotypal and paranoid personality ratings and a greater prevalence of histories of psychiatric treatment and family history of psychotic illness. However, only a higher prevalence of mood disorder among first- and second-degree relatives distinguished the patients who developed PIP on logistic regression analyses (odds ratio=3.49, P=0.001). Possible mechanisms linking vulnerability toward mood disorders and the development of psychotic symptoms in epilepsy are discussed

Juvenile myoclonic epilepsy (JME) is a distinct epileptic syndrome with a complex mode of inheritance. Several studies found evidence for a locus involved in JME on chromosome 6 near the HLA region. Recently, Elmslie et al. [1997] reported evidence of linkage in JME to chromosome 15q14 assuming a recessive mode of inheritance with 50% penetrance and 65% linked families. The area on chromosome 15q14 encompasses the location of the gene for the alpha-7 subunit of the nicotinic acetylcholine receptor. This could fit the hypothesis that there are two interacting loci, one on chromosome 6 and on chromosome 15 or that there is genetic heterogeneity in JME. In an independent dataset of JME families, we tested for linkage to chromosome 15 but found little evidence for linkage. Moreover, families with more than one family member affected with JME provide a lodscore of 3.4 for the HLA-DR/DQ haplotype on chromosome 6. The lodscore for these same families on chromosome 15q14 is <-2 assuming homogeneity and the maximum lodscore is 0.2 assuming alpha =.25. Only one of these families has a negative lodscore on chromosome 6 and a positive lodscore of 0.5 on chromosome 15q14. Our results indicate that this possible gene on chromosome 15 plays at most a minor role in our JME families. Am. J. Med. Genet. (Neuropsychiatr. Genet.) 96:49-52, 2000

Evidence for genetic influences in epilepsy is strong, but reports identifying specific chromosomal origins of those influences conflict. One early study reported that human leukocyte antigen (HLA) markers were genetically linked to juvenile myoclonic epilepsy (JME); this was confirmed in a later study. Other reports did not find linkage to HLA markers. One found evidence of linkage to markers on chromosome 15, another to markers on chromosome 6, centromeric to HLA. We identified families through a patient with JME and genotyped markers throughout chromosome 6. Linkage analysis assuming equal male-female recombination probabilities showed evidence for linkage (LOD score 2.5), but at a high recombination fraction (theta), suggesting heterogeneity. When linkage analysis was redone to allow independent male-female thetas, the LOD score was significantly higher (4.2) at a male-female theta of.5,.01. Although the overall pattern of LOD scores with respect to male-female theta could not be explained solely by heterogeneity, the presence of heterogeneity and predominantly maternal inheritance of JME might explain it. By analyzing loci between HLA-DP and HLA-DR and stratifying the families on the basis of evidence for or against linkage, we were able to show evidence of heterogeneity within JME and to propose a marker associated with the linked form. These data also suggest that JME may be predominantly maternally inherited and that the HLA-linked form is more likely to occur in families of European origin

Several loci and candidate genes for epilepsies or epileptic syndromes map or have been suggested to map to chromosome 8. We investigated families with adolescent-onset idiopathic generalized epilepsy (IGE), for linkage to markers spanning chromosome 8. The IGEs that we studied included juvenile myoclonic epilepsy (JME), epilepsy with only generalized tonic-clonic seizures occurring either randomly during the day (random grand mal) or on awakening (awakening grand mal), and juvenile absence epilepsy (JAE). We looked for a gene common to all these IGEs, but we also investigated linkage to specific subforms of IGE. We found evidence for linkage to chromosome 8 in adolescent-onset IGE families in which JME was not present. The maximum multipoint LOD score was 3.24 when family members with IGE or generalized spike-and-waves (SW) were considered affected. The LOD score remained very similar (3.18) when clinically normal family members with SW were not considered to be affected. Families with either pure grand mal epilepsy or absence epilepsy contributed equally to the positive LOD score. The area where the LOD score reaches the maximum encompasses the location of the gene for the beta3-subunit of the nicotinic acetylcholine receptor (CHRNB3), thus making this gene a possible candidate for these specific forms of adolescent-onset IGE. The data excluded linkage of JME to this region. These results indicate genetic heterogeneity within IGE and provide no evidence, on chromosome 8, for a gene common to all IGEs