Pseudobulbar affect

Pseudobulbar affect
Classification and external resources
Specialty Neurology, psychiatry
ICD-10 ICD10GroupMajor.minor
ICD-9-CM xxx

Pseudobulbar affect (PBA), emotional lability, labile affect, or emotional incontinence refers to a neurologic disorder characterized by involuntary crying or uncontrollable episodes of crying and/or laughing, or other emotional displays.[1] PBA occurs secondary to a neurologic disease or brain injury. Patients may find themselves crying uncontrollably at something that is only moderately sad, being unable to stop themselves for several minutes. Episodes may also be mood-incongruent: a patient might laugh uncontrollably when angry or frustrated, for example.

Terminology

Historically, there have been a variety of terms used for the disorder, including pseudobulbar affect, pathological laughter and crying, emotional lability, emotionalism, emotional dysregulation, or more recently, involuntary emotional expression disorder.[2]

Terms such as forced crying, involuntary crying, pathological emotionality, and emotional incontinence have also been used, although less frequently.[3]

Signs and symptoms

The cardinal feature of the disorder is a pathologically lowered threshold for exhibiting the behavioral response of laughter, crying, or both. An affected individual exhibits episodes of laughter and/or crying without an apparent motivating stimulus or in response to stimuli that would not have elicited such an emotional response before the onset of their underlying neurologic disorder. In some patients, the emotional response is exaggerated in intensity but is provoked by a stimulus with an emotional valence congruent with the character of the emotional display. For example, a sad stimulus provokes a pathologically exaggerated weeping response instead of a sigh, which the patient normally would have exhibited in that particular.

However, in some other patients, the character of the emotional display can be incongruent with, and even contradictory to, the emotional valence of the provoking stimulus or may be incited by a stimulus with no clear valence. For example, a patient may laugh in response to sad news or cry in response to stimuli with no emotional undertone, or, once provoked, the episodes may switch from laughing to crying or vice versa.[4]

The symptoms of PBA can be severe, with persistent and unremitting episodes.[3] Characteristics include:

Many people with neurologic disorders exhibit uncontrollable episodes of laughing, crying, or both that are either exaggerated or contradictory to the context in which they occur. Where patients have significant cognitive deficits (e.g., Alzheimer's) it can be unclear whether it is true PBA as opposed to a grosser form of emotional dysregulation, but patients with intact cognition often report the symptom as disturbing. Patients report that their episodes are at best only partially amenable to voluntary control, and unless they experience a severe change of mental status, they often have insight into their problem and judge their emotional display as inappropriate and out of character. The clinical impact of PBA can be severe, with unremitting and persistent symptoms that can be disabling to patients, and may significantly impact quality of life for caregivers.

Social impact

While not as profoundly disabling as the physical symptoms of these diseases, PBA can have a significant impact on individuals' social functioning and their relationships with others. Such sudden, frequent, extreme, uncontrollable emotional outbursts may lead to social withdrawal and interfere with activities of daily living, social and professional pursuits, and have a negative impact on overall healthcare. For example, patients with ALS and MS are often cognitively normal. However, the appearance of uncontrollable emotions is commonly associated with many additional neurological disorders such as attention deficit/hyperactivity disorder,[5] Parkinson's disease,[6] cerebral palsy,[7] autism,[8] epilepsy,[9] and migraines.[10] This may lead to severe embarrassment and avoidance of social interactions for the patient, which in turn has an impact on their coping mechanisms and their careers.[3][11][12][13][14]

Several criteria exist to differentiate between PBA and depression

Depression

PBA may often be misdiagnosed as clinical depression; however, many clear distinctions exist.

In depression and grief syndromes, crying is typically a sign of sadness, whereas the pathological displays of crying which occur in PBA are often in contrast to the underlying mood, or greatly in excess of the mood or eliciting stimulus. In addition, a key to differentiating depression from PBA is duration: PBA episodes are sudden, occurring in a brief episodic manner, while crying in depression is a more sustained presentation and closely relates to the underlying mood state. The level of control that one has over the crying episodes in PBA is minimal or nonexistent, whereas for those suffering from depression, the emotional expression (typically crying) can be modulated by the situation. Similarly, the trigger for episodes of crying in patients with PBA may be nonspecific, minimal or inappropriate to the situation, but in depression the stimulus is specific to the mood-related condition. These differences are outlined in the adjacent Table.

In some cases, depressed mood and PBA may co-exist. In fact, depression is one of the most common emotional changes in patients with neurodegenerative disease or post-stroke sequelae. As a result, it is often comorbid with PBA. Comorbidity implies that depression is distinct from PBA and is not necessary for, nor does it exclude, a diagnosis of PBA.[2]

Causes

The specific pathophysiology involved in this frequently debilitating condition is still under investigation; the primary pathogenic mechanisms of PBA remain controversial.[1] One hypothesis, established by early researchers such as Wilson and Oppenheim, placed emphasis on the role of the corticobulbar pathways in modulating emotional expression in a top-down model, and theorized that PBA occurs when bilateral lesions in the descending corticobulbar tract cause failure of voluntary control of emotion, which leads to the disinhibition, or release, of laughing/crying centers in the brainstem.[15] Other theories implicate the prefrontal cortex.[16]

Secondary condition

Pseudobulbar affect is a condition that occurs secondary to neurological disease or brain injury, and is thought to result from disruptions of neural networks that control the generation and regulation of motor output of emotions. PBA is most commonly observed in people with neurologic injuries such as traumatic brain injury (TBI) and stroke,[15][17] and neurologic diseases such as dementias including Alzheimer's disease, attention deficit/hyperactivity disorder (ADHD),[5][18] multiple sclerosis (MS), amyotrophic lateral sclerosis (ALS), Lyme disease, PANDAS in children and adults, and Parkinson's disease (PD). It has been reported as a symptom of hyperthyrodism, Graves' Disease, or hypothyroidism in combination with depression.[19]

PBA has also been observed in association with a variety of other brain disorders, including brain tumors, Wilson's disease, syphilitic pseudobulbar palsy, and various encephalitides. Rarer conditions associated with PBA include gelastic epilepsy, dacrystic epilepsy, central pontine myelinolysis, olivopontinocerebellar atrophy, lipid storage diseases, chemical exposure (e.g., nitrous oxide and insecticides), fou rire prodromique, and Angelman syndrome.

It is hypothesized that these primary neurologic injuries and diseases impact chemical signaling in the brain, which in turn disrupts the neurologic pathways that control emotional expression.[20][21][22]

Stroke

PBA is one of the most frequently reported post-stroke behavioral syndromes, with a range of reported prevalence rates from 28% to 52%.[23][24][25] The higher prevalence rates tend to be reported in stroke patients who are older and/or who have a history of prior stroke.[26][27] The relationship between post-stroke depression and PBA is complicated, because the depressive syndrome also occurs with high frequency in stroke survivors. Post-stroke patients with PBA are more depressed than poststroke patients without PBA, and the presence of a depressive syndrome may exacerbate the weeping side of PBA symptoms.[23][28]

Multiple sclerosis

Recent studies suggest that approximately 10% of patients with multiple sclerosis (MS) will experience at least one episode of emotional lability.[29][30] PBA is generally associated with later stages of the disease (chronic progressive phase).[25] PBA in MS patients is associated with more severe intellectual deterioration, physical disability, and neurological disability.[31]

Amyotrophic lateral sclerosis

A study designed specifically to survey for prevalence found that 49% of patients with amyotrophic lateral sclerosis (ALS) also had PBA.[11] PBA does not appear to be associated with duration of amyotrophic lateral sclerosis.[32][33] It is a symptom of ALS that many patients are unaware of and do not get information about by their physician.[34]

Traumatic brain injury

One study of 301 consecutive cases in a clinic setting reported a 5% prevalence. PBA occurred in patients with more severe head injury, and coincided with other neurological features suggestive of pseudobulbar palsy.[35]

The Brain Injury Association of America (BIAA) indicates that approximately 80% of survey respondents experience symptoms of PBA.[36] Results from a recent investigation estimate the prevalence of PBA associated with traumatic brain injury to exceed more than 55% of survivors.[37]

Treatment

Education of patients, families, and caregivers is an important component of the appropriate treatment of PBA. Crying associated with PBA may be incorrectly interpreted as depression; laughter may be embarrassing. It is therefore critical for families and caregivers to recognize the pathological nature of PBA and the reassurance that this is an involuntary syndrome that is manageable. Traditionally, antidepressants such as sertraline,[38] fluoxetine,[39]citalopram,[40] nortriptyline[41] and amitriptyline[42] have been prescribed with some efficacy.

Dextromethorphan/quinidine

Dextromethorphan hydrobromide is a generic drug that affects the signals in the brain that trigger the cough reflex. It is generally used as a cough suppressant, although it can sometimes be used, medicinally, as a pain reliever, and is also used as a recreational drug.[43] "Dextromethorphan (DM) is a sigma-1 receptor agonist and an uncompetitive NMDA receptor antagonist."[44]

Quinidine sulfate affects the way the heart beats, and is generally used in people with certain heart rhythm disorders. It is also used to treat malaria.[45] Quinidine sulfate, as a metabolic inhibitor, "increases plasma levels of dextromethorphan by competitively inhibiting cytochrome P450 2D6, which catalyzes a major biotransformation pathway for dextromethorphan," enabling therapeutic dextromethorphan concentrations.[44][46]

Nuedexta is a patented combination of these two generic drugs, and is the first FDA-approved drug for the treatment of PBA, approved on October 29, 2010.[47] In December 2007, clinical study information for Nuedexta was first submitted to ClinicalTrials.gov, (a Web-based resource maintained by the National Library of Medicine (NLM) at the National Institutes of Health (NIH)). Sponsored by Avanir Pharmaceuticals, (with brief title, Safety and Efficacy of AVP-923 in PBA Patients With ALS or MS), the study was assigned NCT Number NCT00573443. Final updates and verifications occurred in June 2013 on the ClinicalTrials.gov site.[48]

For this multicenter study, the "Objectives...[were] to evaluate the safety, tolerability, and efficacy of two different doses of AVP-923 [Dextromethorphan/quinidine combination]...when compared to placebo."[48] The conditions and results of that study are as follows:

At one study site, a total of 326 participants received one of three dose options. "METHODS: In a 12-week randomized, double-blind trial, ALS and MS patients with clinically significant PBA" were given a twice-daily dose of one of the following:
  • placebo (N=109)
  • dextromethorphan hydrobromide 30 mg/quinidine sulfate 10 mg (N=110)
  • Nuedexta – dextromethorphan hydrobromide 20 mg/quinidine sulfate 10 mg (N=107)

283 patients (86.8%) completed the study. The number of PBA episodes (laughing and crying) were 47% and 49% lower (based on the trial's outcome measures), respectively, for the drug-combination options than for the placebo. The "mean CNS-LS scores" decreased by 8.2 points for both drug-combination options, vs a decrease of 5.7 points for the placebo. Overall, the trial showed a statistically significant benefit from taking a combination of Dextromethorphan and quinidine, with both dosages being safe and well tolerated. For a secondary objective measuring a participant's "perceived health status...measuring eight health concepts: vitality, physical functioning, bodily pain, general health perceptions, physical role-, emotional role-, social role functioning, and mental health," the higher dosage showed improvement, especially on measures of social functioning and mental health.[48][49]

Other studies have confirmed the results of NCT00573443, but, "The mechanism by which dextromethorphan exerts therapeutic effects in patients with pseudobulbar affect is unknown."[44]

Avanir Pharmaceuticals

Nuedexta is marketed by Avanir Pharmaceuticals. Founded in 1988, "Avanir Pharmaceuticals is a biopharmaceutical company engaged in acquiring, developing and commercializing novel therapeutic products for the treatment of central nervous system disorders."[50] In December 2014, Avanir announced a definitive deal with Japanese pharmaceutical giant, Otsuka Holdings, in which Otsuka would acquire Avanir for $3.54 billion.[51][52]

While AVP-923 (Nuedexta) was tested and approved for treatment of PBA, "Avanir is also studying Nuedexta as a treatment for diabetic nerve pain, agitation in patients with Alzheimer's disease, central nerve pain in multiple sclerosis, and levodopa-induced dyskinesia in Parkinson's disease."[53]

Avanir, and some of its collaborative partners, utilizes a drug development path whereby drug manufacturers begin with "known drug compound[s]," (an "approved drug, advanced clinical candidate or previously studied compound"), which are "improved with deuterium substitution," creating "deuterated analogs of approved drugs" which should result in "faster advancement into clinical development" with the "potential for [an] expedited clinical pathway."[54]

AVP-786 is another developmental drug for Avanir, and is similar to AVP-923, but "contains quinidine at a lower dosage than that used in Nuedexta."[55] The "fast-track" development program was successful for this drug:

"Following interactions with the FDA, an agreement was reached for a faster development path for Avanir's AVP-786...which contains deuterium-modified dextromethorphan and quinidine, [and] is being developed for the treatment of neurologic and psychiatric disorders. Under the agreement with the FDA, Avanir will be allowed to use the data generated on Nuedexta (AVP-923) to support the IND application as well as regulatory filings for AVP-786 in the US. This will not only help fasten [sic] the development process for AVP-786, it will also lower development-related costs."[55]

Avanir sometimes collaborates with Concert Pharmaceuticals, Inc., and AVP-786 is a current "partnered drug," which Concert describes as "a combination of deuterium-substituted dextromethorphan and an ultra-low dose of quinidine...for the treatment of agitation in Alzheimer’s patients, schizophrenia, and as an adjunctive treatment of major depressive disorder (MDD)."[54]

In addition, Avanir believes its drugs can be used to treat neuropathic pain, treatment-resistant depression, migraines, dyskinesia in patients suffering from Parkinson's disease, and adult autism. AVP-923 and AVP-786 are in clinical trials for "the treatment of neurologic and psychiatric disorders, including pain, behavioral disorders, mood disorders, and movement disorders."[56]

Clinical Trials for AVP-786 and AVP-923




Epidemiology

Prevalence estimates place the number of people with PBA between 1.5 and 2 million in the United States alone, which would be less than 1% of the U.S. population even at the high end of the estimate. Some argue that the number is probably higher and that clinicians underdiagnose PBA.[57] However, the prevalence estimate of 2 million is based on an online survey. Self-selected computer-savvy patients in at-risk groups evaluated their own symptoms and submitted their self-diagnoses. No doctor or clinic confirmed the data. Motivation to participate could have been influenced by the presence of symptoms, which would have skewed the results. The actual prevalence could very well be quite a bit lower than estimated.[58]

History

The Expression of the Emotions in Man and Animals by Charles Darwin was published in 1872.[59] In Chapter VI, "Special Expressions of Man: Suffering and Weeping", Darwin discusses cultural variations in the acceptability of weeping and the wide differences in individual responses to suffering. The chapter contains the following sentence:

We must not, however, lay too much stress on the copious shedding of tears by the insane, as being due to the lack of all restraint; for certain brain-diseases, as hemiplegia, brain-wasting, and senile decay, have a special tendency to induce weeping.[60]

See also

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