Psychogenic nonepileptic seizures (PNES) is a neuropsychiatric condition that causes a transient alteration of consciousness and loss of self-control. PNES, which occur in vulnerable individuals who often have experienced trauma and are precipitated by overwhelming circumstances, are a body’s expression of a distressed mind, a cry for help. PNES are misunderstood, mistreated, under-recognized, and underdiagnosed. The mindbody dichotomy, an artificial divide between physical and mental health and brain disorders into neurology and psychiatry, contributes to undue delays in the diagnosis and treatment of PNES. One of the major barriers in the effective diagnosis and treatment of PNES is the dissonance caused by different illness perceptions between patients and providers. While patients are bewildered by their experiences of disabling attacks beyond their control or comprehension, providers consider PNES trivial because they are not epileptic seizures and are caused by psychological stress. The belief that patients with PNES are feigning or controlling their symptoms leads to negative attitudes of healthcare providers, which in turn lead to a failure to provide the support and respect that patients with PNES so desperately need and deserve. A biopsychosocial perspective and better understanding of the neurobiology of PNES may help bridge this great divide between brain and behavior and improve our interaction with patients, thereby improving prognosis. Knowledge of dysregulated stress hormones, autonomic nervous system dysfunction, and altered brain connectivity in PNES will better prepare providers to communicate with patients how intangible emotional stressors could cause tangible involuntary movements and altered awareness.
• Psychogenic non-epileptic seizures (PNES) are events that look like epileptic seizures but are not caused by abnormal electrical discharges.
• PNES are a manifestation of psychological and emotional distress.
• Treatment for PNES does not begin with the psychological intervention but starts with the diagnosis and how the diagnosis is delivered.
• A multifactorial biopsychosocial process and a neurobiological review are both essential components when treating PNES
Psychogenic nonepileptic seizures (PNES) are paroxysmal attacks that may resemble epileptic seizures but are not caused by abnormal brain electrical discharges. At least 15 different labels have been used to describe PNES, including dissociative attacks, hysterical epilepsy, psychogenic seizures, nonepileptic spells, nonphysiologic or functional seizures, and pseudoseizures (a term now widely considered pejorative) [
Providers may feel that PNES is a stress-related mental phenomenon, whereas patients hold markedly different beliefs and views about PNES [
PNES are a relatively common condition encountered by pediatricians and neurologists and among the most important differential diagnoses of pediatric epilepsy. This entity constitutes the most common nonepileptic event in school-aged children and adolescents, accounting for 3.5%–15% of pediatric patients referred for video electroencephalography (vEEG) [
Pediatric patients with PNES and their families report receiving inadequate treatment and supportive care compared with patients with epilepsy [
How to deliver the diagnosis of PNES: a barrier to communication because of a dualistic conceptualization.
The essential step in initiating the treatment of PNES is delivering the confirmed diagnosis in an understanding and nonjudgmental manner [
In a study investigating who delivered the diagnosis of PNES to patients, over 70% were neurologists [
The etiology of PNES is complex. Any single etiology or even contributing factor fails to fully explain the heterogeneous PNES patient population [
This review focuses on the 2 key findings of the neurobiology of PNES: (1) an increased arousal index; and (2) alterations in the cognitive-emotional-executive control circuitry in the brain’s connectivity network.
The hypothalamic-pituitary-adrenal (HPA) axis is a primary mechanism in the allostatic process through which early life stress contributes to disease [
Studies on the relationship of PNES to these neurobiological stress systems have shown dysregulation of the stress hormone homeostasis (
How is cortisol involved in the PNES manifestation? Some studies used cortisol as a stress marker and found no difference in prestress basal cortisol levels between patients with PNES and others [
Autonomic nervous system (ANS) dysfunction has been increasingly recognized to play a role in numerous neuropsychiatric disorders, including PNES. However, most research on PNES compared small heterogeneous cohorts of patients with PNES or epilepsy [
Studies focusing on ANS function at rest (interictal period) or its preictal changes of PNES have been more revealing. HR variability (HRV) was low in patients with PNES at rest versus normal controls [
Alterations in the intrinsic connectivity of the brain in patients with PNES have been explored using functional MRI (fMRI), which analyzes fluctuations in the blood oxygenation level-dependent (BOLD) signal, which is indirectly correlated with neuronal activity. Resting-state fMRI (rsfMRI) measures synchronous activations of the BOLD signal between brain regions to investigate the functional intrinsic connectivity of the brain [
Ding et al. [
Van der Kruijs et al. [
Similar findings were replicated by other researchers. Li et al. [
Only 3 studies to date have analyzed task- or event-related fMRI and rsfMRI findings in patients with PNES. Differences in cortical responses to facial emotional processing between patients with PNES and temporal lobe epilepsy were noted; specifically, patients with PNES exhibited increased fMRI responses to happy, neutral, and fearful faces in the visual, temporal, or parietal regions and decreased fMRI responses to sad faces in the bilateral putamen [
Psychogenic PNES superficially resemble seizures, although unlike epileptic seizures, they are not induced by abnormal electrical activity in the brain. PNES are a physical manifestation of psychological distress, a dissociative state, and a common cause of transient loss of awareness and consciousness. Patients with PNES are often blamed for their symptoms as if they are making them up when, in fact, they are frightened, unaware of their emotional stress, and unable to find the mind-body link. PNES are as costly and disabling as epileptic seizures, although the health-related quality of life of patients with PNES is worse than that of patients with epilepsy. The diagnosis and treatment of PNES are often delayed because of barriers to care. It is important to recognize and communicate to patients that PNES is indeed a brain disorder, life experiences can change the brain to make one vulnerable to PNES, and the condition will improve with intervention. PNES may be considered a normal reaction to an overwhelming experience that exceeds and overloads a person’s nervous system and coping ability. Evidence shows that patients with PNES have heightened reactions to external or internal stress in the HPA axis and a dysregulated ANS. Functional connectivity is altered in patients with PNES, particularly in brain networks involving the cognitive-emotional-executive control circuitry. These changes may reflect an adaptation to long-term hypervigilance and an increased response to stressful stimuli. The truth about PNES lies beyond the dualistic framework of psychologic versus biologic. Rather, an integrative and inclusive biopsychosocial perspective is more suitable for addressing PNES, a condition that lies at the interface of neurology and psychiatry. One needs to break down the artificial divide between physical health and mental health and recognize the inseparability of the mind and body.
No potential conflict of interest relevant to this article was reported.
This work was supported by the Gyeongsang National University Fund for Professors on Sabbatical Leave, 2019.
How to deliver the diagnosis of PNES
| Do | Do not |
|---|---|
| You have PNES (dissociative attacks). | Your events are not "real seizures" |
| These events are real and serious. | These are just pseudoseizures caused by stress. |
| They are relatively common cause of temporary loss of self-control. | |
| Do you ever get sad? | You need to see a psychiatrist (you have mental illness). “I’m sorry, I can’t help you. This isn’t neurological” |
| How bad does that sadness get? | |
| Do you get anxious? | |
| Development of PNES may be linked to trauma (if history known) | Obstinately dig for a trauma history. |
| Sit down, listen actively. This is what I heard you say…. Is that correct? | Type into a computer during interview. |
| This must have been hard for you. | |
| What have you had to give up? | |
| Avoid eye contact | |
| Hold hands. | Sternal rub, deep nailbed pressure. |
| Take deep breaths together. | Antiepileptic drug infusion. |
PNES, psychogenic nonepileptic seizures.
Hypothalamic-pituitary-adrena axis studies in psychogenic nonepileptic seizures
| Study | Measurements | No. | PNES | ES | HC | Sampling timing | Findings based on HPA axis |
|---|---|---|---|---|---|---|---|
| Tunca et al. [ |
Plasma cortisol | 33 | 20 of 25 patients with conversion disorder | 0 | 8 | Baseline: 8 AM; post DST: next 8 AM and 4 PM | Baseline conversion disorders (mainly PNES) = HC; decreased dexamethasone suppression in conversion disorders |
| Tunca et al. [ |
Serum cortisol | 26 | 18 | 0 | 8 | PNES patients: during seizures (n=18) and next day 8 AM as baseline (n=8); HC: 8 AM as baseline | Baseline PNES = HC; during seizures in afternoon and evening >baseline HC |
| Zhang and Liu [ |
ACTH and cortisol | 47 | 11 | 36 | 0 | Baseline: 8 AM (awake), 12 AM (sleep); peri-ictal: before, during, after nocturnal eizures | Baseline ACTH and cortisol PNES=ES; ES patients: significant peri-ictal changes of ACTH and cortisol; PNES patients: a level similar to that of awake is maintained during peri-ictal periods |
| Bakvis et al. [ |
Cortisol (saliva) and HRV | 56 | 19 | 17 | 20 | Eleven assessment points over a 200 min: rest, stress, and recovery with reference to the start of stressor | Group differences were present in only in HRV (baseline and recovery phase), not in cortisol |
| Bakvis et al. [ |
Cortisol (saliva) | 56 | 19 | 17 | 20 | Baseline cortisol: 40 min before attention bias task (angry face) | Baseline cortisol PNES = HC; positive correlation between basal cortisol levels and attention bias scores for threat stimuli only in PNES group (r=0.49, |
| Bakvis et al. [ |
Cortisol (saliva) | 37 | 18 | 0 | 19 | Awakening cortisol: 0, 15, 30, 45, 60 min; basal diurnal: every 2 hours from 10 AM to 22 PM; post DST | Basal diurnal cortisol: PNES > HC (with statistically significance); awakening cortisol and post DST: PNES = HC |
| Bakvis et al. [ |
Cortisol (saliva) | 39 | 19 | 20 | Nine assessment points over a 145-min period, divided in a rest, stress and a recovery phase | PNES=HS throughout time points; high cortisol stress responses correlated with larger stress-induced working memory impairments in the no- distracter condition in PNES patients | |
| Bakvis et al. [ |
Cortisol (saliva) | 12 | 20 | Nine assessment points over a 145-min period, divided in a rest, stress and a recovery phase | PNES > HC throughout time points; Increased social threat avoidance behavior at baseline in PNES patients, which was correlated with basal pretask cortisol | ||
| Novakova et al. [ |
Cortisol (saliva) and HRV | 44 | 22 | 22 | Morning (9 AM) and evening (10 PM) | PNES=ES diurnal cortisol and HRV changes were similar between the groups; no close relationship was found between self-reported stress and physiologic stress markers (cortisol and HRV) |
HPA, hypothalamic-pituitary-adrenal; HRV, heart rate variability PNES, psychogenic nonepileptic seizures; HC, healthy control; DST, dexamethasone suppression test; ACTH, adrenocorticotropic hormone; ES, epileptic seizures.
Autonomic function studies of psychogenic nonepileptic seizures
| Study | Measurements | No. | PNES | ES | HC | Data acquisition | Findings based on autonomic functions |
|---|---|---|---|---|---|---|---|
| Opherk and Hirsch [ |
HR | 105 | 38 | 67 | 0 | Baseline, ictal onset (first 10 sec prior to ictus), ictal (maximal HR during ictus), and postictal (first 1–2 min postictally) | Baseline HR: PNES > ES ( |
| Relative HR (% of baseline HR): nonconvulsive ES > nonconvulsive PNES in all time points with |
|||||||
| Oliveira et al. [ |
HR | 59 | 20 | 39 | Baseline (from -50 to -40 min), preictal (from -40 to 0.5 min), ictal (one 10 sec epoch every 30 sec), and postictal (from +10 to +60 min) | Baseline HR CPS > SPS and PNES ( |
|
| Ictal HR > baseline HR in SPS ( |
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| Ictal and postictal HR were not changed in CPS and PNES | |||||||
| Oliveira et al. [ |
HR | 143 | 50 | 93 | 0 | Same with Oliveira et al. [ |
Ictal HR increased in mild to severe ES, and severe PNES than their baseline ( |
| Baseline HR aura (ES) > other groups of ES and all of PNES | |||||||
| Reinsberger et al. [ |
HR | 88 | 42 | 46 | 0 | Baseline (at the beginning of the recording), preictal (30 sec prior to seizure onset), ictal (maximal frequency during the seizure), postictal (60 sec after the seizure) | Baseline HR PNES=CPS ( |
| HR (in % from baseline): PNES > CPS in preictal ( |
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| Bakvis et al. [ |
HRV (as one of physiologic markers of stress) | 30 | 19 | 20 | -60, -40, -20, 0, (rest) +20, +40, (stress) +60, +80, +100, +120, and +140 (recovery) min with reference to the start of the stressor | HRV PNES <HC throughout the experiments (baseline and recovery phase from stress, |
|
| Mungen et al. [ |
DB-RRIV (for parasympathetic) and SSR (for sympathetic) | 75 | 25 | 30 | 20 | Interictal: at least one week or longer since the last seizure | DB-RRIV interictal and postictal ES > HC ( |
| SSR interictal and postictal ES > HS ( |
|||||||
| PNES patients had normal autonomic functions | |||||||
| Ponnusamy et al. [ |
HRV | 129 | 52 | 42 | 35 | Postictal period: 2 hr after seizures | HRV HC > PNES and ES (all measures |
| HRV PNES = ES | |||||||
| PNES patients have a lower resting vagal tone and higher sympathetic tone than healthy controls. | |||||||
| Ponnusamy et al. [ |
HRV | 50 | 24 | 26 | 0 | A 3 minute, resting supine ECG | ES had higher ictal HRV changes than those of PNES: high sympathetic and reduced vagal tone during epileptic seizures |
| Reinsberger et al. [ |
EDA | 20 | 9 | 11 | 0 | Ictal HRV: at least 1 min of artifact-free ictal ECG | GTCS are associated with a more profound sympathetic arousal than PNES (EDR ES >PNES, |
| Interictal HRV: 3 min of artifactfree resting ECG | |||||||
| Jeppesen et al. [ |
HRV | 24 (73) |
7 (24) |
17 (49) |
0 | A moving window model that analyzes the previous 100 R-R intervals for each new R-peak during the immediate preictal, ictal, and immediate postictal period of each seizure | Maximum ictal sympathetic index for ES was higher than PNES (ictal ES >PNES, |
| van der Kruijs et al. [ |
HRV | 20 (118) |
20 (118) |
12 Intervals (of 5 min each) preceded and followed episodes, and 2 intervals during episodes | PNES episodes are preceded by increased sympathetic functioning, which is followed by an increase in parasympathetic functioning during and after PNES | ||
| Novakova et al. [ |
Cortisol (saliva) and HRV | 44 | 22 | 22 | Morning (9 AM) and evening (10PM) | PNES=ES diurnal cortisol and HRV changes were similar between the groups; no close relationship was found between self-reported stress and physiologic stress markers (cortisol and HRV) | |
| Indranada et al. [ |
HR and RR | 146 | 101 | 45 | At baseline, 5 min, 4 min, 3 min, 2 min, 1 min, before the seizure event, and immediately prior to onset | Baseline HR and RR PNES = ES | |
| Increasing autonomic arousal prior to seizure events in PNES (rising HR and RR from baseline to the onset of their seizures, |
|||||||
| Zsom et al. [ |
EDA, HR, BVP, and BT via wearable-sensors | 18 (35) |
8 (12) |
10 (23) |
1-min segments with no temporal overlap: 104 interictal data points vs. 276 ictal data points | A higher ictal HR ( |
|
| Badry [ |
SaO2, HR, RR, BT, SBP, and DBP | 94 | 49 | 45 | At baseline (a single point measurement during relax) and maximal values during the attacks | Baseline vital signs PNES = ES | |
| Ictal HR ES > PNES ( |
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| Ictal RR ( |
PNES, psychogenic nonepileptic seizures; HR, heart rate; ES, epileptic seizures; CPS, complex partial seizures; SPS, simple partial seizures; ECG, electrocardiogram; EDA, electrodermal activity; GTCS, generalized tonic-clonic seizures; BVP, blood volume pulse; BT, body temperature; CSI, cardiac vagal index; DB-RRIV, deep breath RR intervals; DBP, diastolic blood pressure; HC, healthy control; HRV, heart rate variability; RR, respiratory rate; SaO2, oxygen saturation; SBP, systolic blood pressure; SSR, sympathetic skin response.
Event number.
FMRI studies of psychogenic nonepileptic seizures
| Study | Imaging | No. | PNES | ES | HC | Findings |
|---|---|---|---|---|---|---|
| van der Kruijs et al. [ |
rsfMRI, event-related fMRI | 23 | 11 | 0 | 12 | PNES increased FC between areas involved in emotion (insula), executive control (inferior frontal gyrus and parietal cortex) and movement (precentral sulcus) in resting state, which were significantly associated with dissociation scores.; no significant difference for activation pattern to fMRI tasks |
| Ding et al. [ |
rsfMRI, DTI | 37 | 17 | 0 | 20 | PNES patients lost optimal topological organization in FC and SC networks; PNES decreased coupling strength between FC and SC |
| Ding et al. [ |
rsfMRI | 38 | 18 | 0 | 20 | PNES showed abnormal functional connectivity density regions mainly associated with attention (frontal cortex), sensorimotor (sensorimotor cortex), and emotion (cingulate gyrus and insular); FC was disrupted between these regions. |
| van der Kruijs et al. [ |
rsfMRI | 48 | 21 | 0 | 27 | PNES increased coactivation of fronto-parietal network (OFC, insular and subcallosal cortex), executive control network (cingulate and insular cortex), sensorimotor network (cingulate gyrus, SPL, pre- and postcentral gyri and SMA, and default mode network; The connectivity strength within these regions significantly correlated with dissociation scores in PNES |
| Li et al. [ |
rsfMRI | 38 | 18 | 0 | 20 | Insular subregions (vAI, dAI, PI) have a significantly higher connectivity within motor (postcentral gyrus/SMA and putamen), visual memory (lingual gyrus) and sensory process (parietal lobe) region in PNES; the correlation between the altered FC values and the frequency of PNES episodes |
| Li et al. [ |
rsfMRI | 38 | 18 | 0 | 20 | PNES exhibited widespread intra-regional neural network deficits, including increasing (DLPFC, sensorimotor, and limbic system) and decreased (ventrolateral prefrontal cortex) connectivity; PNES frequency is correlated with connectivity between SMA and anterior cingulate cortex |
| Szaflarski et al. [ |
rsfMRI, emotional face task fMRI | 48 | 12 | 12 (TLE) | 24 | Compared with TLE, PNES exhibited increased fMRI response to happy, neutral, and fearful faces in visual, temporal, and/or parietal regions and decreased fMRI response to sad faces in the putamen bilaterally; RSFC of the left and right amygdala to brain regions including emotion regulation and motor control circuits was increased in PNES |
| Dienstag et al. [ |
rsfMRI | 22 | 9 | 0 | 13 | PNES exhibited disturbances of functional disturbances between the MTL and the sensorimotor cortex and between the MTL and ventral attention networks. |
| Allendorfer et al. [ |
rsfMRI, stress task fMRI | 24 | 12 | 0 | 12 | PNES exhibited hyporeactivity to psychological stress (hypo reactivity in left/right amygdala and left hippocampus), along with greater emotion-motor-executive control network (increased connectivity between right amygdala to left precentral and inferior/middle frontal gyri) in RSFC. |
fMRI, functional magnetic resonance imaging; PNES, psychogenic nonepileptic seizures; refMRI, resting-state functional magnetic resonance image; ES, epileptic seizures; HC, healthy control; FC, functional connectivity; DTI, diffusion tensor imaging; SC, structural connectivity; OFC, orbitofrontal cortex; SPL, superior parietal lobe; SMA, supplementary motor area; vAI, ventral anterior insula; dAI, dorsal anterior insula; PI, posterior insula; DLPFC, dorsolateral prefrontal cortex; TLE, temporal lobe epilepsy; RSFC, resting state functional connectivity; MTL, medial temporal lobe.