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Active Search for Epileptiform Electroencephalogram Activity by External Stimulation in Critically Ill Patients

Published online by Cambridge University Press:  18 July 2016

Fábio A. Nascimento*
Affiliation:
Division of Neurology, Toronto Western Hospital, University of Toronto, Toronto, Ontario, Canada
Felippe Borlot
Affiliation:
Division of Neurology, Toronto Western Hospital, University of Toronto, Toronto, Ontario, Canada
Danah Aljaafari
Affiliation:
Division of Neurology, Toronto Western Hospital, University of Toronto, Toronto, Ontario, Canada Department of Neurology, King Fahad Hospital of University, University of Dammam, Saudi Arabia.
Martin del Campo
Affiliation:
Division of Neurology, Toronto Western Hospital, University of Toronto, Toronto, Ontario, Canada
*
Correspondence to: Fábio Augusto Nascimento e Silva, Toronto Western Hospital (TWH), 5W. 399, Bathurst Street, M5T 2S8. Toronto, Ontario, Canada. Email: nascimento.fabio.a@gmail.com
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Abstract

Type
Neuroimaging Highlights
Copyright
Copyright © The Canadian Journal of Neurological Sciences Inc. 2016 

A 68-year-old woman presented with a 2-day history of fluctuating level of consciousness. She underwent an electroencephalogram (EEG) to rule out nonconvulsive status epilepticus. Nail bed pressure applied to the extremities triggered paroxysms of brain activity consistent with stimulus-induced rhythmic, periodic, or ictal discharges (SIRPIDs) (Fig. 1) not accompanied by clinical manifestations. The SIRPIDs pattern consisted of 10- to 15-second runs of paroxysmal, medium- to high-amplitude polymorphic 1 to 2 Hz delta (mixed with 4-5 Hz theta), alternating with nonrhythmic high-amplitude waveforms, appearing diffusely throughout the brain (but frontally accentuated). At certain times, it was triphasically configured; at other times, it was clearly epileptiform. Magnetic resonance imaging scan of the brain showed multiple areas of diffuse restriction of varying ages involving the right periventricular white matter (Fig. 2A) and extending into the posterior right lentiform nucleus (Fig. 2B) as well as encephalomalacia in the left centrum semiovale (Fig. 2C). These radiological abnormalities were considered secondary to primary central nervous system vasculitis to which she succumbed. The SIRPIDs observed in this patient were likely a sign of cortical irritability; nonetheless, there was not strong evidence suggesting that it contributed to her demise.

Figure 1 EEG. The patient was comatose throughout the recording. During periods of quiescence, the background activity was 7 Hz low-amplitude rhythm, mixed with theta and delta frequency waveforms of low amplitude, 1 to 5 Hz, and fairly symmetrical. When the patient was stimulated by applying pain to the extremities, the brain rhythms changed and a pattern of SIRPIDs was noted. The figure shows one of the most typical spells, in which the SIRPIDs pattern was triggered by external painful stimulus to the right hallux. The same pattern was consistently seen in response to different stimuli—auditory as well as painful stimuli—to different sites in the extremities.

Figure 2 Brain magnetic resonance imaging scan. Axial T2-fluid attenuation inversion recovery weighted (top images) and diffusion-weighted (bottom images). Multiple areas of diffusion restriction with interval evolution involving the right periventricular white matter (A) and extending into the posterior right lentiform nucleus (B). Tiny foci of diffusion restriction were also noted more anteriorly in the right putamen, right frontal operculum, and left parietal lobe (not shown). A previous infarct in the left centrum semiovale has now become associated with encephalomalacia in this area (C).

SIRPIDs were first described by Hirsch et al as periodic, rhythmic, or ictal-appearing discharges consistently induced by alerting stimuli.Reference Hirsch, Claassen, Mayer and Emerson 1 Although being underrecognized and underreported, SIRPIDs seem to be relatively common. According to the original report, this EEG pattern may be found in roughly one-fifth of critically ill patients undergoing continuous EEG monitoring.Reference Hirsch, Claassen, Mayer and Emerson 1 This EEG phenomenon is believed to be epileptogenic when associated with clinical manifestations that are stereotyped and temporally linked with the discharges. Etiologically, SIRPIDs are associated with a wide variety of conditions, including intracranial hemorrhages, cerebral infarctions, hypoxic-ischemic brain injury, traumatic brain injury, and neurodegenerative diseases such as Creutzfeldt-Jakob disease.Reference Hirsch, Claassen, Mayer and Emerson 1 - Reference Rossetti and Dunand 4 In terms of pathophysiology, the mechanisms underlying SIRPIDs are still unknown.Reference Hirsch, Claassen, Mayer and Emerson 1 , Reference Andraus, Andraus and Alves-Leon 5 Similarly, their overall prognostic significance is not fully understood.Reference Hirsch, Claassen, Mayer and Emerson 1 , Reference Van Straten, Fesler, Hakimi, Sheng, Thompson and Hakimi 6 However, in comatose survivors of cardiac arrest who underwent therapeutic hypothermia, SIRPIDs appear to be associated with poor outcome—especially when occurring during hypothermia.Reference Alvarez, Oddo and Rossetti 2

In regards to management, pursuing or not treatment of SIRPIDs is still a matter of debate. The rationale behind this dissensus relies on the fact that there is a lack of evidence on how to care for patients with SIRPIDsReference Van Straten, Fesler, Hakimi, Sheng, Thompson and Hakimi 6 ; therefore, to improve care, accurate diagnostic and prognostic data should be consistently obtained and, ideally, reported.

In this context, we strongly recommend the routine performance of different noxious stimuli during EEG in comatose patients. Regarding the various possible stimulus types in particular, there has not been a definite agreement on the most efficient method to test nociceptive EEG reactivity. Thus, we highlight the importance of standardizing stimulation parameters in comatose patients, as suggested by Tsetsou et al.Reference Tsetsou, Novy, Oddo and Rossetti 7 Furthermore, by presenting our patient’s EEG, which is fairly typical of SIRPIDs, we intend to remind neurologists of this specific EEG pattern, hoping to encourage collaborative studies that will be able to determine the prognostic and therapeutic implications of SIRPIDs.

Disclosures

None of the authors have anything to disclose.

References

1. Hirsch, LJ, Claassen, J, Mayer, SA, Emerson, RG. Stimulus-induced rhythmic, periodic, or ictal discharges (SIRPIDs): a common EEG phenomenon in the critically ill. Epilepsia. 2004;45:109-123.CrossRefGoogle ScholarPubMed
2. Alvarez, V, Oddo, M, Rossetti, AO. Stimulus-induced rhythmic, periodic or ictal discharges (SIRPIDs) in comatose survivors of cardiac arrest: characteristics and prognostic value. Clin Neurophysiol. 2013;124:204-208.CrossRefGoogle ScholarPubMed
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5. Andraus, ME, Andraus, CF, Alves-Leon, SV. Periodic EEG patterns: importance of their recognition and clinical significance. Arq Neuropsiquiatr. 2012;70:145-151.Google Scholar
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7. Tsetsou, S, Novy, J, Oddo, M, Rossetti, AO. EEG reactivity to pain in comatose patients: Importance of the stimulus type. Resuscitation. 2015;97:34-37.Google Scholar
Figure 0

Figure 1 EEG. The patient was comatose throughout the recording. During periods of quiescence, the background activity was 7 Hz low-amplitude rhythm, mixed with theta and delta frequency waveforms of low amplitude, 1 to 5 Hz, and fairly symmetrical. When the patient was stimulated by applying pain to the extremities, the brain rhythms changed and a pattern of SIRPIDs was noted. The figure shows one of the most typical spells, in which the SIRPIDs pattern was triggered by external painful stimulus to the right hallux. The same pattern was consistently seen in response to different stimuli—auditory as well as painful stimuli—to different sites in the extremities.

Figure 1

Figure 2 Brain magnetic resonance imaging scan. Axial T2-fluid attenuation inversion recovery weighted (top images) and diffusion-weighted (bottom images). Multiple areas of diffusion restriction with interval evolution involving the right periventricular white matter (A) and extending into the posterior right lentiform nucleus (B). Tiny foci of diffusion restriction were also noted more anteriorly in the right putamen, right frontal operculum, and left parietal lobe (not shown). A previous infarct in the left centrum semiovale has now become associated with encephalomalacia in this area (C).