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Electroencephalography Attenuations in Adults: Clinical Correlates

Published online by Cambridge University Press:  13 November 2020

Gary Hunter  and
Ryan Verity
Gary Hunter
Affiliation:
Division of Neurology, College of Medicine, University of Saskatchewan, Saskatoon, SaskatchewanCanada
Ryan Verity*
Affiliation:
Division of Neurology, College of Medicine, University of Saskatchewan, Saskatoon, SaskatchewanCanada
*
Correspondence to: Dr. Ryan Verity, Department of Neurology, University of Saskatchewan, 103 Hospital Drive, Saskatoon, SK S7N OW8, Canada. Email: Ryan.verity@usask.ca
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Abstract:

Spontaneous intermittent generalized attenuations (SIGAs) are defined as a transient decrease in amplitude of electroencephalography (EEG) activity in response to a physiologic process, external stimuli, or as a result of a pathologic condition. We seek to investigate their relationship to clinical outcomes. Demographic information, modified Rankin Scale (mRS), and clinical information were noted on 22 consecutive patients with SIGAs on their EEG. 12 of the 22 patients (54.5%) died, and 12 patients (54.5%) were admitted to the intensive care unit or coronary care unit. Future studies should attempt to prospectively compare outcomes among patients with SIGAs against a control group.

Résumé :

RÉSUMÉ :

Atténuations de l’activité électrique du cerveau chez l’adulte : des corrélats cliniques. On peut définir les « atténuations spontanées intermittentes généralisées » (dites « SIGA ») comme une diminution transitoire de l’amplitude de l’activité électrique du cerveau en réponse à un processus physiologique ou à des stimulus externes ou bien encore en lien avec un état pathologique. Notre objectif est ici d’étudier la relation existante entre ce phénomène d’atténuation et l’évolution de l’état clinique d’un certain nombre de patients. Pour ce faire, nous avons colligé, dans le cas de 22 patients vus consécutivement et donnant à voir de telles atténuations lors d’un électroencéphalogramme (EEG), leurs caractéristiques démographiques, leurs scores à la Modified Rankin Scale et des renseignements de nature clinique. Au total, 12 patients sur ces 22 sont décédés (54,5 %) ; de plus, 12 patients sur ces mêmes 22 (54,5 %) avaient été admis à une unité de soins intensifs (USI). À ce sujet, de futures études devraient tenter de comparer de manière prospective les résultats obtenus chez des patients manifestant de telles atténuations aux résultats d’un groupe formé de témoins.

Keywords

EEGNeurocritical careBrain functionCerebral metabolismClinical neurophysiologyCOMAElectroencephalographyIon channels
Type
Brief Communication
Information
Canadian Journal of Neurological Sciences , Volume 48 , Issue 4 , July 2021 , pp. 570 - 574
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press on behalf of The Canadian Journal of Neurological Sciences Inc.

Spontaneous intermittent generalized attenuations (SIGAs) are defined as a transient decrease in amplitude of electroencephalography (EEG) activity in response to a physiologic process, external stimuli, or as a result of a pathologic conditionReference Noachtar, Binnie, Ebersole, Mauguiere, Sakamoto and Westmoreland1. However, these are infrequently described and are not included in standard EEG terminologyReference Hirsch, LaRoche and Gaspard2. These EEG attenuations have been previously described in children, mainly as an epileptic phenomenon in syndromic epilepsies (e.g. Lennox–Gastaut syndrome, West syndrome) also known as electrodecremental events (EDE)Reference Wong-Kisiel and Nickels3. However, the significance of SIGAs has not been identified in adultsReference Stern4. Diffuse EEG attenuations in adults have been noted by electroencephalographers without definite clinical associations or formal study. Anecdotal evidence suggests there may be an association with the triphasic waves, generally seen in the setting of metabolic encephalopathyReference Kaplan5.

We have observed that severe metabolic encephalopathies appear to be associated with SIGAs in hospitalized patients. We, therefore, hypothesize that EEG attenuations in adults may be of prognostic value in the assessment of metabolic encephalopathies. We seek to further investigate their relationship to triphasic waves and other markers of metabolic encephalopathy, and to characterize underlying etiologies.

This is a prospective case series. We reviewed EEG and clinical features from 22 consecutive adult patients who underwent EEG as part of their diagnostic evaluation and demonstrated SIGAs. SIGAs were defined as transient, infrequent, and intermittently generalized decreases in EEG voltages lasting at least 500 msec, with at least 50% decrease from baseline amplitude, and were felt to clearly be discrepant from background activity. Patients taking anesthetic agents and those with preexisting epilepsy were excluded. All pertinent medications are listed in Table 1. Demographic information, baseline and discharge modified Rankin Scale (mRS), diagnosis at discharge, EEG altering medications, intensive care unit (ICU) admissions, relevant imaging, mental status, discharge destination, pertinent lab values, and metabolic abnormalities were noted. Each patient’s EEG was then re-evaluated by an EEG-certified neurologist. The neurologist began by identifying if attenuations were indeed present, duration of the attenuation (msec), background amplitude and frequency, presence of spikes and/or triphasic waves, and temporal relationship to these discharges. Ethics approval was obtained from our local biomedical research ethics board.

Table 1: Relevant clinical information

The assessment includes 22 patients, 7 males, and 15 females. Examples of EEG attenuations from Patient 16 and Patient 18 (with triphasic waves) are shown in Figures 1 and 2, respectively. Mean patient age was 73.7 (SD = 11.0) at admission. Mean mRS score at baseline was 1.4 (SD = 1.4), and was 4.8 (SD = 1.5) at discharge (Table 1). Twelve of the 21 patients (54.5%) died during their course in hospital as a result of their illness. Four patients (18.2%) did not have a change in mRS score from baseline to discharge. The mean discharge mRS was 4.8 (SD = 1.5). Eighteen patients were drowsy at the time of their EEG, 2 were in a coma, and the other 2 were described as nonspecifically encephalopathic. Twelve patients (54.5%) were admitted to the ICU or coronary care unit during their time in hospital. Only three patients were discharged home. Other clinical information is further described in Table 1. Mean SIGA duration was 1300 msec (SD = 403 msec). Fourteen of the 22 (63.6%) patients showed IGAs immediately following a triphasic wave. All patients except one showed a slowing of background activity. Epileptiform activity was seen in four patients. Other EEG findings are detailed in Table 2. Underlying diagnoses were variable and included both primary brain pathologies (stroke, hemorrhage, seizures; n = 14) and systemic illness (metabolic encephalopathies n = 8). The primary brain pathology group had a mean discharge mRS of 5.1 (SD = 1.5) and the systemic illness group had a mean discharge mRS of 4.4 (SD = 1.8).

Figure 1: EEG with attenuations and tiphasic waves from Patient 16 post-cardiac arrest.

Figure 2: EEG with attenuations and triphasic waves from Patient 18, who had an intracerebral hemorrhage.

Table 2: EEG data

As EEG attenuations have previously not been well described in adults, we sought to understand their clinical associations and prognostic significance. The most striking finding from this review is the strong association with mortality and persistent disability at discharge, with a majority of survivors discharged to some form of supportive care rather than home. While these outcomes are difficult to distinguish from the underlying disease prognosis, the association appears to support this EEG finding as a marker of severe brain dysfunction.

The underlying pathophysiology of SIGAs remains unclear. Generalized attenuation is likely associated with transitory dysfunction in the setting of reduced cortical synchronicityReference Andraus and Alves-Leon6. The duration of the attenuations may support potassium channel dysfunction, secondary to a burst release of calciumReference Amzica7. The length of the attenuations was mostly around the 1300 msec mark, with variance as short as 600 msec and as long as 2200 msec. Length of attenuation did not seem to correlate to the prognostic outcome. In children, it is hypothesized that diffuse attenuations are triggered by the activation of the arousal circuit in the setting of diffuse brain dysfunctionReference Losey and Ng8. SIGAs often followed a triphasic waveform, and most patients showed triphasic waves at some point during the recording. The apparent association with triphasic waveforms supports the idea of an underlying metabolic encephalopathy, and triphasics with attenuations may represent a more advanced stage of encephalopathy.

Limitations of this study include a lack of control group and small sample size. The aim of the current study was to describe this EEG finding and the associated clinical and electrographic features, as well as outcomes. Causation and independent prognostic value cannot yet be determined from this study.

From this data, it seems probable that SIGAs is a meaningful EEG finding that should be noted and reported by electroencephalographers, and that they are likely associated with encephalopathies and poor outcomes.

Statement of Authorship

GH: responsible for literature review, patient enrollment, ethics approval, EEG review and interpretation, and manuscript writing/editing.

RV: responsible for literature review, data collection, and manuscript writing/editing.

Disclosures

The authors have no conflicts of interest to declare.

References

Noachtar, S, Binnie, C, Ebersole, J, Mauguiere, F, Sakamoto, A, Westmoreland, B. A glossary of terms most commonly used by clinical electroencephalographers and proposal for the report form for the EEG findings. The International Federation of Clinical Neurophysiology. Electroencephalogr Clin Neurophysiol. Supplement. 1999;52:21.Google ScholarPubMed
Hirsch, LJ, LaRoche, SM, Gaspard, N, et al. American clinical neurophysiology society’s standardized critical care EEG terminology: 2012 version. Clin Neurophysiol. 2013;30(1):127.10.1097/WNP.0b013e3182784729CrossRefGoogle ScholarPubMed
Wong-Kisiel, LC, Nickels, K. Electroencephalogram of age-dependent epileptic encephalopathies in infancy and early childhood. Epilepsy Res Treat. 2013;2013:743203.Google ScholarPubMed
Stern, JM. Atlas of EEG patterns. Lippincott Williams & Wilkins; 2005. p. 67, 154.Google Scholar
Kaplan, PW. The EEG in metabolic encephalopathy and coma. Clin Neurophysiol. 2004;21(5):307–18.Google ScholarPubMed
Andraus, ME, Alves-Leon, SV. Non-epileptiform EEG abnormalities: an overview. Arquivos de Neuro-Psiquiatria. 2011;69(5):829–35.10.1590/S0004-282X2011000600020CrossRefGoogle ScholarPubMed
Amzica, F. Basic physiology of burst-suppression. Epilepsia. 2009;50:38–9.10.1111/j.1528-1167.2009.02345.xCrossRefGoogle ScholarPubMed
Losey, TE, Ng, YT. Stimulus-Induced Diffuse Voltage Attenuation (SIDVA): a previously undescribed EEG pattern in a critically ill child. J Child Neurol. 2009;24(4):500–2.10.1177/0883073808324532CrossRefGoogle Scholar
Figure 0

Table 1: Relevant clinical information

Figure 1

Figure 1: EEG with attenuations and tiphasic waves from Patient 16 post-cardiac arrest.

Figure 2

Figure 2: EEG with attenuations and triphasic waves from Patient 18, who had an intracerebral hemorrhage.

Figure 3

Table 2: EEG data