The ictal bradycardia syndrome: localization and lateralization

PURPOSE: Previous studies have established the importance of the insular cortex and temporal lobe in cardiovascular autonomic modulation. Some investigators, based on the results of cortical stimulation response, functional imaging, EEG recordings of seizures, and lesional studies, have suggested that cardiac sympathetic and parasympathetic function may be lateralized, with sympathetic representation lateralized to the right insula, and parasympathetic, to the left. These studies have suggested that ictal bradycardia is most commonly a manifestation of activation of the left temporal and insular cortex. However, the evidence for this is inconsistent. We sought to assess critically the predictable value of ictal bradycardia for seizure localization and lateralization. METHODS: In this study, we reviewed the localization of seizure activity in 13 consecutive patients with ictal bradycardia diagnosed during prolonged video-EEG monitoring at Mayo Clinic Rochester. The localization of electrographic seizure activity at seizure onset and bradycardia onset was identified in all patients. In addition, we performed a comprehensive review of the ictal bradycardia literature focusing on localization of seizure activity in ictal bradycardia cases. RESULTS: All occurrences of ictal bradycardia in the 13 identified patients were associated with temporal lobe-onset seizures. However, no consistent lateralization of seizure activity was found at onset of seizure activity or at onset of bradycardia in this population. Seizure activity was bilateral at bradycardia onset in nine of 13 patients. The results from the literature review also showed that a predominance of patients had bilateral activity at bradycardia onset; however, more of the ictal bradycardia cases from the literature had left hemispheric localization of seizure onset. CONCLUSIONS: Ictal bradycardia most often occurs in association with bilateral hemispheric seizure activity and is not a consistent lateralizing sign in localizing seizure onset. Our data do not support the existence of a strictly unilateral parasympathetic cardiomotor representation in the left hemisphere, as has been suggested.     

Clinical cues for detecting ictal asystole

Objective The occurrence of asystole during an epileptic seizure is the most dramatic manifestation of ictal bradycardia. Recognition of ictal asystole is important as treatment with both antiepileptic drugs and cardiac pacing may be necessary. The purpose of this study was to identify clinical cues to aid in the detection of ictal asystole. Methods We analyzed the clinical and electrophysiologic features of all recorded seizures in consecutive patients diagnosed with ictal bradycardia and asystole on prolonged video-EEG/ECG monitoring over a 14 year period. Results Twenty-nine seizures with ictal bradycardia were identified in 13 patients. Of these, 11 seizures in seven patients were associated with asystole. Bilateral transient limb movements consisting of asymmetric posturing or jerking occurred during eight episodes of ictal asystole, and loss of muscle tone occurred during four. In contrast, neither bilateral limb movement nor loss of muscle tone was observed in any of the non-asystolic seizures, whether ictal bradycardia was present or not. All patients with ictal asystole reported a history of seizure-related falls and brief body and limb jerking. Conclusions The presence of loss of muscle tone or bilateral asymmetric jerky limb movements during a seizure suggests the possibility of ictal asystole. Video-EEG/ECG monitoring should be considered in patients with epilepsy demonstrating these clinical features to determine if ictal asystole is present.     

Cardiac asystole during a temporal lobe seizure

The association between temporal lobe seizures and cardiac arrhythmias has been anecdotally reported in the literature. Ictal bradycardia and cardiac asystole are rare, and maybe underestimated. The physiological mechanism is poorly understood. We report a patient with left temporal lobe seizures who developed ictal bradycardia and cardiac asystole during a complex partial seizure and required a subsequent placement of a pacemaker.     

Cardiac asystole during right frontal lobe seizures: a case report

Abstract The association between partial seizures and cardiac asystole has rarely been reported in the literature. This potentially life-threatening symptom has been observed principally in left-sided epilepsies, in particular during seizures originating in temporal lobe. We describe a case with ictal bradycardia followed by cardiac asystole during right frontal lobe seizures. Video-EEG monitoring recorded two partial seizures with electro-clinical findings suggestive of a right frontal lobe origin, associated with ictal bradycardia followed by prolonged asystole. The brain MRI showed a lesion located in the cingulate gyrus of the right frontal lobe. The patient required a subsequent placement of a pacemaker. In conclusion, cardiac asystole may be a potentially life-threatening symptom during seizures of frontal lobe origin. The right fronto-mesial structures may play a role in autonomic regulation of cardiovascular responses.     

Ictal asystole in temporal lobe epilepsy before and after pacemaker implantation.

Events of ictal bradycardia or asystole may be of relevance in epilepsy patients presenting with ictal falls, and are a potential contributor to SUDEP. The literature on ictal bradycardia or asystole is anecdotal and consists of case reports and small case series. There are no guidelines for the care of patients with ictal arrhythmias. Insertion of cardiac pacemakers may prevent life-threatening cardiac arrest, syncope and trauma.We report the case of a 41-year-old man who presented with refractory partial seizures resulting in syncope leading to severe head trauma, as the only ictal semiology. During presurgical video-EEG monitoring, two episodes of ictal bradycardia followed by asystole and syncope were recorded. A cardiac pacemaker was implanted. At the nine-month follow-up, the patient reported no overt seizures, syncopes or traumatic falls. Our case demonstrates that implantation of a cardiac pacemaker while continuing AEDs may render a patient free from ictal symptoms and prevent ictal syncope and subsequent trauma. [Published with video sequences].     

The ictal bradycardia syndrome

The ictal bradycardia syndrome is an uncommon diagnosis in which bradycardia is accompanied by simultaneous epileptic discharges in the EEG. We describe a patient who was referred to the emergency ward because of syncope. Ictal semeiology and EEG-EG findings are discussed and compared with those published in the literature. Therapeutic options are discussed in relation with those published in the literature. The ictal bradycardia syndrome is probably underdiagnosed, while its recognition is of utmost importance because of potential life threatening complications such as asystole. Up to now, its aetiology is poorly understood, its ictal semeiology is often described insufficiently and its therapy is still discussed.     

The Ictal Bradycardia Syndrome

: Purpose: Episodic loss of consciousness presents a diagnostic challenge to the neurologist. A perhaps under-recognized cause of episodic loss of consciousness, which we call the ictal bradycardia syndrome, occurs when epileptic discharges profoundly disrupt normal cardiac rhythm, resulting in cardiogenic syncope during the ictal event. We attempt to determine whether the presence of the ictal bradycardia syndrome provides localizing information regarding the site of seizure onset and to describe the demographics of patients with this syndrome. We also discuss difficulties in diagnosis and treatment. Methods: We review 23 cases of the ictal bradycardia syndrome from the literature and present four additional cases. Brief histories are provided for the four previously unreported cases. Where data are available, cases are analyzed with respect to age, sex, and site of seizure onset. Results: Patients with the ictal bradycardia syndrome ranged from 4 months to 72 years (mean 39 years). There was an approximately 5:1 ratio of males to females. Twenty of the 23 patients (87%) whose site of ictal onset could be localized had temporal lobe epilepsy, although no clear lateralizing predominance was apparent. Conclusions: The ictal bradycardia syndrome should be considered in patients with unusual or refractory episodes of syncope, or in patients with a history suggestive of both epilepsy and syncope. It suggests seizure onset in temporal lobe, and is more commonly diagnosed in males. Diagnosis may be aided by ambulatory EEGECG monitoring. Cardiac pacemaker implantation along with antiepileptic drug therapy may be necessary to minimize the possibility of death.     

How common is ictal hypoxemia and bradycardia in children with partial complex and generalized convulsive seizures?

Purpose: Autonomic effects of seizures, including cardiorespiratory abnormalities, may be involved in sudden unexpected death in epilepsy (SUDEP). The purpose of this study was to determine the prevalence and risk factors for ictal hypoxemia (oxygen saturation <90%) and ictal bradycardia (heart rate < second percentile for age) in children during recorded seizures. Methods: The medical records of children admitted to our Epilepsy Monitoring Unit (EMU) between November 1, 2007 and March 13, 2009 were reviewed. Children selected for this study had at least one partial complex or generalized convulsive seizure with recorded oximetry and/or heart rate data. Results: Forty‐nine children were identified and 225 seizures were analyzed. Ictal hypoxemia was observed in 48.9% of children and 26.8% of seizures. Ictal hypoxemia was significantly more likely to occur during generalized versus nongeneralized seizures (43.9% vs. 18.9%) and when tapering antiepileptic drugs (AEDs) (75% vs. 35.5%). For partial complex seizures, there was an association between ictal hypoxemia and prolonged seizure duration. There was no correlation between ictal hypoxemia and partial seizure onset localization or lateralization. Ictal bradycardia occurred in 8.2% of children and 3.7% of seizures. Ictal bradycardia was observed solely with partial complex seizures of extratemporal onset. Due to the low prevalence of ictal bradycardia, these findings were not statistically significant. Discussion: Ictal hypoxemia is common, particularly in the setting of generalized tonic–clonic seizures, prolonged partial complex seizures, and when AEDs are tapered. In contrast to previous ictal bradycardia studies, ictal bradycardia occurred exclusively in extratemporal partial complex seizures in this cohort.     

Early seizure termination in ictal asystole

To evaluate the association between cerebral hypoperfusion and seizure termination, we compared seizure duration in seven patients with syncopal ictal asystole (IA), seven with non-syncopal ictal bradycardia, and ten with non-bradycardic seizures. Mean seizure duration was 34.4±13 s in IA, 67±28.9 s in ictal bradycardia, and 82.1±31.1 in non-bradycardic seizures. These were significantly different (ANOVA, p<0.02). This suggests cerebral hypoxia-ischemia favors seizure termination.     

Autonomic alterations and cardiac changes in epilepsy

Studies with heart rate variability have revealed interictal autonomic alterations in patients with epilepsy. In addition, epilepsy is frequently associated with ictal tachycardia or bradycardia, which sometimes precedes the onset of seizures. Ictal tachycardia is sometimes associated with electrocardiography (ECG) morphologic changes and ictal bradycardia often progresses to asystole. Such cardiac manifestations of seizures have been hypothesized as possible causes for sudden unexplained death in epilepsy (SUPEP). The present review relates to interictal and ictal cardiac manifestations of epilepsy with focus on heart rate, heart rate variability, and ECG changes. Aspects of the supporting mechanisms are discussed and attention is drawn to the interaction between central and peripheral effects, interictal autonomic conditions, ictal autonomic discharges, and administration of antiepileptic drugs in shaping the ictal cardiac changes. Because these interactions are complex and not totally understood, closer surveillance of patients and more experimental work is necessary to elucidate the mechanistic support of autonomic and cardiac changes in epilepsy, and to design better strategies to avoid their undesirable effects. It is also suggested that some of these changes could be used as predictors or markers for the onset of seizures.     

Peri-ictal atrioventricular conduction block in a patient with a lesion in the left insula: Case report and review of the literature

Seizure-induced syncope is uncommon and is usually due to peri-ictal bradycardia and asystole. In contrast, peri-ictal atrioventricular conduction block (AV block) has been reported only rarely. Here, we review the literature on peri-ictal AV block and describe a patient with recurrent episodes of epigastric auras that were occasionally followed by a sensation of dizziness and syncope because of transient third-degree AV block. After installation of a cardiac pacemaker, epigastric auras persisted, whereas the sensation of dizziness and syncope stopped. MRI revealed a lesion in the left insula, leading to the notion that recurrent syncope was most likely due to ictal activity in central autonomic networks.     

Electrocardiographic changes during electrographic seizures

The occurrence of high-risk cardiac arrhythmias during electrographic seizures has been proposed as a possible cause for sudden unexpected death in patients with epilepsy. Several anecdotal case reports have documented various cardiac irregularities during seizures. We reviewed simultaneous 24-hour electroencephalographic - electrocardiographic studies obtained by ambulatory cassette electroencephalography in 45 patients who experienced 106 electrographic seizures. An increase in heart rate was seen in 96% of seizures, while in four seizures, the rate was unchanged. Heart rate increase measured from 1 minute preictally to intraictal peak ranged from 0% to 160% (mean, 60%). The onset of tachycardia was usually within several seconds (before or after) of the seizure onset, and often persisted for several minutes after termination of the discharge. No difference was found in patients with lateralized vs generalized seizures. Neither ventricular ectopia, conduction defects, or bradycardia were observed during the ictal episodes. We conclude that ictal tachycardia is the rule during electrographic seizures, and that high-risk cardiac arrhythmias are uncommon.     

SCN8A-related developmental and epileptic encephalopathy with ictal asystole requiring cardiac pacemaker implantation

IntroductionSCN8A-related epilepsy has various phenotypes. In particular, patients with developmental and epileptic encephalopathy (DEE) are resistant to antiepileptic drugs and may present with autonomic symptoms, such as marked bradycardia and apnea during seizures, and thus have an increased risk of sudden death. Herein, we report a case of very severe SCN8A-related epilepsy necessitating cardiac pacemaker implantation because of repetitive ictal asystole.Case reportThe patient was a 14-month-old girl. Tremor and generalized tonic seizure occurred after birth. During seizures, bradycardia and perioral cyanosis occurred, and then, after developing tachycardia and apnea, marked bradycardia and generalized cyanosis occurred, which sometimes resulted in ictal asystole requiring cardiopulmonary resuscitation. Her seizures were refractory to antiepileptic drugs. As the seizures requiring resuscitation did not decrease, cardiac pacemaker implantation was performed four months after birth. Exome sequencing revealed a heterozygous de novo variant in SCN8A (NM_014191.3:c.4934T>C,p.(Met1645Thr)). Even though phenytoin was effective, seizures with bradycardia remained approximately once a month, and pacemaker activity was observed.ConclusionsThis is, to our knowledge, the first reported case of SCN8A-related DEE in whom pacemaker implantation was performed. Pacemaker implantation should be considered as a treatment option for critical patients with SCN8A-related DEE as in the present case, because the incidence of sudden unexpected death in epilepsy is reported to be approximately 10% in patients with SCN8A-related DEE.     

Interictal change in cardiac autonomic function associated with EEG abnormalities and clinical symptoms: a longitudinal study following acute deterioration in two patients with temporal lobe epilepsy

The purpose of the present study was to investigate the ictal and interictal changes in cardiac autonomic function (CAF), and the relationship between the interictal change in CAF to the electroencephalogram (EEG) and clinical findings. In two patients with temporal lobe epilepsy (TLE) showing acute deterioration, a quantitative evaluation of their interictal CAF based on heart rate variability and their EEG using spectral analysis was conducted, and the findings compared with repeated clinical evaluations during the recovery period. The ictal heart rate changes and their temporal relationship to ictal discharge were investigated using simultaneous EEG/electrocardiogram (ECG) monitoring in one of the patients. Interictal parasympathetic function was decreased during the period of acute deterioration, but was increased in association with improvements in the EEG and clinical findings. In contrast, the sympathetic function showed no specific changes. The ictal discharges were preceded by a brief bradycardia, with a long delay of up to 40s. The results demonstrated that this decrease in parasympathetic function was closely related to the interictal changes in central nervous system function. On the other hand, the ictal discharges in one of the patients were thought to have caused a transient elevation of parasympathetic function. It is strongly suggested that patients with TLE have interictal as well as ictal changes in CAF that are mediated mainly through the parasympathetic nervous system.     

Ictal bradycardia in a patient with a hypothalamic hamartoma: a stereo-EEG study

Little is known about bradycardia and cardiac asystole which occur during partial epileptic seizures, especially whether they relate to ictal involvement of well-defined cortical areas. Several reports based on simultaneous electrocardiographic and intracranial depth electroencephalographic monitoring have shown that either the fronto-orbital cortex or the amygdalohippocampal complex could be responsible for such cardiac variations. We performed stereo-EEG recordings in a patient with refractory localization-related epilepsy associated with a hypothalamic hamartoma. We found that other cortical areas, such as the frontocentral region and the temporal neocortex, can contribute to the genesis of ictal bradyarrhythmia. Second, the lesion per se, although located within the hypothalamus, is not involved with this phenomenon.     

Electrocardiographic and oximetric changes during partial complex and generalized seizures

Significant autonomic changes occur during seizures and may be related to sudden unexplained death in epilepsy (SUDEP). Accordingly, we performed a study to determine the prevalence of heart rate, QTc, and oximetric changes during seizures and analyzed their association with SUDEP risk factors. We analyzed 218 seizures from 76 patients. Ictal sinus tachycardia occurred in 57% of seizures and was associated with ≥3 failed AEDs (p=0.001), generalized seizures (p<0.001), and normal brain MRI (p=0.04). Ictal sinus bradycardia was rare, occurring in 2% of seizures. Ictal bradycardia was associated with seizure clustering (p=0.028) and reported history of ≥50 seizures/month (p=0.01). Depending on the correction formula utilized for calculating QTc, clinically significant ictal QTc prolongation (≥460ms for children ≤13 years, ≥470ms for males age >13, and ≥480ms for females age >13) occurred in 4.8-16.2% of seizures, while ictal QTc prolongation ≥500ms occurred in 2.9-16.2%. Ictal QTc shortening ≤340ms was observed in 3.8-4.8% of seizures. Ictal hypoxemia occurred in 25% of seizures and was associated with normal MRI (p=0.01), longer seizure duration (p=0.049), and ictal tachycardia (p=0.003). Such findings may have implications for understanding the pathogenesis of SUDEP.     

The association of cardiac asystole with partial seizures: does it result from ictal or interictal activity?

Bradycardia or asystole that occur during some seizures may be life threatening as a leading cause of SUDEP. A patient with right and left temporal lobe onset seizures and preceding bardycardia or asystole is presented. He had bilateral hippocampal atrophy on MRI. The unreliability of ictal bradycardia or asystole as a lateralizing sign in patients with partial epilepsy and the role of interictal autonomic activity in heart rate changes during seizures are discussed.     

Hemifacial motor and crying seizures of temporal lobe onset: case report and review of electro-clinical localisation

OBJECTIVE: To report a case of temporal lobe epilepsy with clinical presentation of paroxysmal episodes of "tightness" over the right hemiface, and ictal crying, and review electroclinical localisation of this phenomenon. METHODS: Clinical semiology, neurophysiological localising tests, and epilepsy surgery outcome are reported in a subject presenting with paroxysmal right hemifacial movements and ictal crying. Pertinent past reports of somato-motor signs and ictal crying in temporal lobe epilepsy are reviewed and the findings correlated with proposed human facial cortical representation. RESULTS: Simple partial seizures caused by temporal lobe epilepsy presented with right sided tonic facial movements and ictal crying. Intracranial EEG monitoring documented a left medial temporal onset of seizures that remained asymptomatic until they propagated to the left cingulate region. Anterior temporal lobectomy with resection of the amygdala and anterior hippocampus resulted in cessation of seizures. CONCLUSIONS: This is a rare example of epileptic seizures of medial temporal onset presenting with isolated somato-motor manifestations and ictal crying. Anatomical-electrical-clinical correlations with cortical regions controlling facial movements were highly suggestive that this case represents secondary activation of "emotional" motor cortex M3 and M4 (rostral and caudal cingulate motor cortex), giving rise to focal hemifacial movements and ictal crying.     

Clustering syncope in a young male with temporal lobe seizures

We report the case of a male aged 2 years 6 months with left temporal lobe epilepsy who presented with ictal bradycardia syndrome leading to asystole. The clinical presentation was remarkable for the occurrence of clustering syncope. A seizure was recorded on a video electroencephalogram- electrocardiogram and analyzed. A cardiac pacemaker was implanted and antiepileptic drug treatment was initiated. We suggest that clustering of syncope is an important feature in the presentation of epilepsy in a young child.     

Asymptomatic bradycardia associated with amisulpride.

Well-known adverse effects of amisulpride include nausea, insomnia or tiredness, gastrointestinal, extrapyramidal and endocrine symptoms. Cardiac disorders, however, appear to be an extremely rare complication of the drug. Only a few case reports on this complication have been published so far, which deal with QT prolongation, hypotension, hypertension and palpitations. Bradycardia has not yet been mentioned. Here, we will report on a case of asymptomatic bradycardia that developed subsequent to therapeutic doses of amisulpride in a 25-year-old male patient with chronic paranoid-hallucinatory schizophrenia. The patient had been rehospitalized for an acute exacerbation of the psychosis. When the patient failed to respond at the beginning of hospitalization, the treatment was changed from clozapine to amisulpride. After a complete switchover to amisulpride, the patient's ECG showed sinus bradycardia and QT prolongation. When the daily dose of amisulpride was reduced from 800 mg/d to 600 mg/d, the patient's ECG quickly normalized (including blood pressure and pulse rate) within a few days. The patient did not report any cardiovascular-related complaints. Since the cardiovascular-specific diagnostics did not yield any indicative results, bradycardia may be a rare complication of amisulpride treatment.